diff --git a/DESCRIPTION b/DESCRIPTION
index 94f0a25..ec5af9e 100755
--- a/DESCRIPTION
+++ b/DESCRIPTION
@@ -1,8 +1,8 @@
 Package: RLumCarlo
 Type: Package
 Title: Monte-Carlo Methods for Simulating Luminescence Phenomena
-Version: 0.1.4
-Date: 2020-06-06
+Version: 0.1.5
+Date: 2020-06-12
 Author: Johannes Friedrich [aut, trl] (<https://orcid.org/0000-0002-0805-9547>),
     Sebastian Kreutzer [aut, trl, cre] (<https://orcid.org/0000-0002-0734-2199>),
     Vasilis Pagonis [aut] (<https://orcid.org/0000-0002-4852-9312>),
diff --git a/NEWS.Rmd b/NEWS.Rmd
index 85c4f72..d1f8b23 100644
--- a/NEWS.Rmd
+++ b/NEWS.Rmd
@@ -8,8 +8,7 @@ header-includes:
 
 ## RLumCarlo `r RLumBuild::.get_pkg_version()` (`r Sys.Date()`)
 
-* Add automated spell correction and remove odd DOIs and not yet 
-valid links to ease the CRAN inspection
+* Fix problem on CRAN Solaris
 
 ## RLumCarlo 0.1.3 (2020-06-05) (never published on CRAN)
 
diff --git a/NEWS.html b/NEWS.html
index afb314f..ea6a308 100644
--- a/NEWS.html
+++ b/NEWS.html
@@ -602,9 +602,9 @@
 
 <!-- NEWS.md was auto-generated by NEWS.Rmd. Please DO NOT edit by hand!-->
 
-<h2 id="rlumcarlo-014-2020-06-06">RLumCarlo 0.1.4 (2020-06-06)</h2>
+<h2 id="rlumcarlo-015-2020-06-12">RLumCarlo 0.1.5 (2020-06-12)</h2>
 <ul>
-<li>Add automated spell correction and remove odd DOIs and not yet valid links to ease the CRAN inspection</li>
+<li>Fix problem on CRAN Solaris</li>
 </ul>
 <h2 id="rlumcarlo-013-2020-06-05-never-published-on-cran">RLumCarlo 0.1.3 (2020-06-05) (never published on CRAN)</h2>
 <ul>
diff --git a/NEWS.md b/NEWS.md
index 60cee59..a454910 100644
--- a/NEWS.md
+++ b/NEWS.md
@@ -5,10 +5,9 @@
 
 <!-- NEWS.md was auto-generated by NEWS.Rmd. Please DO NOT edit by hand!-->
 
-## RLumCarlo 0.1.4 (2020-06-06)
+## RLumCarlo 0.1.5 (2020-06-12)
 
-  - Add automated spell correction and remove odd DOIs and not yet valid
-    links to ease the CRAN inspection
+  - Fix problem on CRAN Solaris
 
 ## RLumCarlo 0.1.3 (2020-06-05) (never published on CRAN)
 
diff --git a/README.html b/README.html
index 51b3a59..654cba7 100644
--- a/README.html
+++ b/README.html
@@ -604,7 +604,7 @@
 
 <h1 id="rlumcarlo-">RLumCarlo <img width="120px" src="data:image/png;base64,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" align="right" /></h1>
 <p>The <strong>R</strong> package RLumCarlo provides a collection of R functions modelling luminescence production in isolators and semiconductors for various stimulation modes using Monte Carlo methods.</p>
-<p><a href="https://www.repostatus.org/#active"><img src="data:image/svg+xml;base64,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" alt="Project Status: Concept" /></a> <a href="https://travis-ci.org/R-Lum/RLumCarlo"><img src="data:image/svg+xml;base64,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" alt="Build Status" /></a> <a href="https://ci.appveyor.com/project/RLumSK/rlumcarlo"><img src="data:image/svg+xml;base64,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" alt="Build status" /></a> <a href="https://codecov.io/gh/R-Lum/RLumCarlo"><img src="data:image/svg+xml;base64,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" alt="codecov" /></a></p>
+<p><a href="https://www.repostatus.org/#active"><img src="data:image/svg+xml;base64,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" alt="Project Status: Concept" /></a> <a href="https://CRAN.R-project.org/package=RLumCarlo"><img src="data:image/svg+xml; charset=utf-8;base64,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" alt="CRAN" /></a> <a href="https://www.r-pkg.org/pkg/RLumCarlo"><img src="data:image/svg+xml; charset=utf-8;base64,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" alt="Downloads" /></a> <a href="https://travis-ci.org/R-Lum/RLumCarlo"><img src="data:image/svg+xml;base64,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" alt="Build Status" /></a> <a href="https://ci.appveyor.com/project/RLumSK/rlumcarlo"><img src="data:image/svg+xml;base64,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" alt="Build status" /></a> <a href="https://codecov.io/gh/R-Lum/RLumCarlo"><img src="data:image/svg+xml;base64,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" alt="codecov" /></a></p>
 <h2 id="installation">Installation</h2>
 <h4 id="i-requirements">i. Requirements</h4>
 <p>Depending on your OS please download and install one of the following:</p>
@@ -620,7 +620,7 @@ <h4 id="ii-install-the-package-from-github">ii. Install the package from GitHub<
 <h2 id="examples">Examples</h2>
 <div class="sourceCode" id="cb2"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb2-1"><a href="#cb2-1"></a><span class="kw">run_MC_CW_IRSL_TUN</span>(<span class="dt">A =</span> <span class="fl">0.12</span>, <span class="dt">rho =</span> <span class="fl">0.003</span>, <span class="dt">times =</span> <span class="dv">0</span><span class="op">:</span><span class="dv">1000</span>) <span class="op">%&gt;%</span></span>
 <span id="cb2-2"><a href="#cb2-2"></a><span class="st">     </span><span class="kw">plot_RLumCarlo</span>(<span class="dt">norm =</span> <span class="ot">TRUE</span>, <span class="dt">legend =</span> <span class="ot">TRUE</span>)</span></code></pre></div>
-<img src="data:image/png;base64,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" 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" style="display: block; margin: auto;" />
 
 <h2 id="supported-models">Supported models</h2>
 <table>
diff --git a/RLumCarlo.BuildResults/RLumCarlo-Ex.timings.0.1.4.WARNING b/RLumCarlo.BuildResults/RLumCarlo-Ex.timings.0.1.5.WARNING
similarity index 100%
rename from RLumCarlo.BuildResults/RLumCarlo-Ex.timings.0.1.4.WARNING
rename to RLumCarlo.BuildResults/RLumCarlo-Ex.timings.0.1.5.WARNING
diff --git a/RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.4.pdf b/RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.5.pdf
similarity index 80%
rename from RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.4.pdf
rename to RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.5.pdf
index c50dc60..c6cc62d 100644
Binary files a/RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.4.pdf and b/RLumCarlo.BuildResults/RLumCarlo-TimingExamples.0.1.5.pdf differ
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4.tar.gz b/RLumCarlo.BuildResults/RLumCarlo_0.1.4.tar.gz
deleted file mode 100644
index 0a5d246..0000000
Binary files a/RLumCarlo.BuildResults/RLumCarlo_0.1.4.tar.gz and /dev/null differ
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.csv b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.csv
similarity index 91%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.csv
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.csv
index 05f44dd..45feda2 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.csv
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.csv
@@ -1,45 +1,45 @@
 "Name","Title","Description","Version","m.Date","m.Time","Author","Citation"
 "create_ClusterSystem","Create dosimetric cluster system","In order to allow interaction of an spatial a correlation clusters in RLumCarlo, first a dosimetric system needs to be created in a three-dimensional space, which is the purpose of this function.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
-"methods_RLumCarlo","methods_RLumCarlo","Methods for S3-generics implemented for the package 'RLumCarlo'.",NA,NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom),<br /> Johannes Friedrich, University of Bayreuth (Germany),<br />","Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+"methods_RLumCarlo","methods_RLumCarlo","Methods for S3-generics implemented for the package 'RLumCarlo'.",NA,NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom),<br /> Johannes Friedrich, University of Bayreuth (Germany),<br />","Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "plot_RLumCarlo","Plot RLumCarlo Monte-Carlo Simulation Results","Visualise 'RLumCarlo' modelling results without extracting the values manually. Typically visualised are the averaged signal or the number of remaining electrons, with a polygon indicating modelling uncertainties.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) <br /> Johannes Friedrich, University of Bayreuth (Germany)<br />","Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) <br /> Johannes Friedrich, University of Bayreuth (Germany)<br />","Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_CW_IRSL_LOC","Monte-Carlo Simulation for CW-IRSL (localized transitions)","Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_CW_IRSL_TUN","Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions)","Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the model for tunnelling transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap, into a recombination centre.","0.2.0
-",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_CW_OSL_DELOC","Run Monte-Carlo Simulation for CW-OSL (delocalized transitions)","Runs a Monte-Carlo (MC) simulation of continuous wave optically stimulated luminescence (CW-OSL) using the one trap one recombination centre (OTOR) model. The term delocalized here refers to the involvement of the conduction band.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_ISO_DELOC","Run Monte-Carlo Simulation for ISO-TL (delocalized transitions)","Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_ISO_LOC","Run Monte-Carlo simulation for ISO-TL (localized transitions)","Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do no involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_ISO_TUN","Monte-Carlo Simulation for ISO-TL (tunnelling transitions)","Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into the recombination centre.","0.1.0
-",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_LM_OSL_DELOC","Run Monte-Carlo Simulation for LM-OSL (delocalized transitions)","Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_LM_OSL_LOC","Run Monte-Carlo Simulation for LM-OSL (localized transitions)","Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trap, and also involve a an energy state of the recombination centre.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_LM_OSL_TUN","Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions)","Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into a recombination centre.","0.1.0
-",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_TL_DELOC","Run Monte-Carlo Simulation for TL (delocalized transitions)","Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. The heating rate in this function is assumed to be 1 K/s.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_TL_LOC","Run Monte-Carlo Simulation for TL (localized transitions)","Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. The heating rate in this function is assumed to be 1 K/s.","0.1.0
-",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
 "run_MC_TL_TUN","Run Monte-Carlo Simulation for TL (tunnelling transitions)","Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) caused by tunnelling (TUN) transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap into a recombination centre. The heating rate in this function is assumed to be 1 K/s.","0.1.0
-",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,<br /> Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+",NA,NA,"Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,<br /> Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />","Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 "
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.html b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.html
similarity index 91%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.html
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.html
index d2a6bfb..7f4013a 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.html
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.html
@@ -1,6 +1,6 @@
 
 <p class='character'><h2 align="center">Major functions in the R package 'Luminescence'</h2>
-           <h4 align="center"> [version: 0.1.4 ]</h4>
+           <h4 align="center"> [version: 0.1.5 ]</h4>
            <style type="text/css">
            <!--
 
@@ -71,7 +71,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -92,7 +92,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom),<br /> Johannes Friedrich, University of Bayreuth (Germany),<br />
 </td>
-<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -114,7 +114,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) <br /> Johannes Friedrich, University of Bayreuth (Germany)<br />
 </td>
-<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -136,7 +136,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -158,7 +158,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -180,7 +180,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -202,7 +202,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -224,7 +224,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -246,7 +246,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -268,7 +268,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -290,7 +290,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -312,7 +312,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -334,7 +334,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -356,7 +356,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -378,7 +378,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,<br /> Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -388,7 +388,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
  <br>
 
 <p class='character'><h2 align="center">Major functions in the R package 'Luminescence'</h2>
-           <h4 align="center"> [version: 0.1.4 ]</h4>
+           <h4 align="center"> [version: 0.1.5 ]</h4>
            <style type="text/css">
            <!--
 
@@ -459,7 +459,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -480,7 +480,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom),<br /> Johannes Friedrich, University of Bayreuth (Germany),<br />
 </td>
-<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -502,7 +502,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) <br /> Johannes Friedrich, University of Bayreuth (Germany)<br />
 </td>
-<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -524,7 +524,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -546,7 +546,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -568,7 +568,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -590,7 +590,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -612,7 +612,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -634,7 +634,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -656,7 +656,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -678,7 +678,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -700,7 +700,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany),<br /> Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -722,7 +722,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -744,7 +744,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
@@ -766,7 +766,7 @@ <h4 align="center"> [version: 0.1.4 ]</h4>
 </td>
 <td class=cellinside>Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,<br /> Geography & Earth Sciences, Aberystwyth University (United Kingdom)<br />
 </td>
-<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+<td class=cellinside>Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 
 </td></tr>
  
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.tex b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.tex
similarity index 92%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.tex
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.tex
index 0cfc5ea..33a2bef 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions.tex
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions.tex
@@ -5,48 +5,48 @@
  & Name & Title & Description & Version & m.Date & m.Time & Author & Citation \\ 
   \hline
 1 & create\_ClusterSystem & Create dosimetric cluster system & In order to allow interaction of an spatial a correlation clusters in RLumCarlo, first a dosimetric system needs to be created in a three-dimensional space, which is the purpose of this function. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. create\_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. create\_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
-  2 & methods\_RLumCarlo & methods\_RLumCarlo & Methods for S3-generics implemented for the package 'RLumCarlo'. &  &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom),$<$br /$>$ Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ & Kreutzer, S., Friedrich, J., 2020. methods\_RLumCarlo(): methods\_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+  2 & methods\_RLumCarlo & methods\_RLumCarlo & Methods for S3-generics implemented for the package 'RLumCarlo'. &  &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom),$<$br /$>$ Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ & Kreutzer, S., Friedrich, J., 2020. methods\_RLumCarlo(): methods\_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   3 & plot\_RLumCarlo & Plot RLumCarlo Monte-Carlo Simulation Results & Visualise 'RLumCarlo' modelling results without extracting the values manually. Typically visualised are the averaged signal or the number of remaining electrons, with a polygon indicating modelling uncertainties. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom) $<$br /$>$ Johannes Friedrich, University of Bayreuth (Germany)$<$br /$>$ & Kreutzer, S., Friedrich, J., 2020. plot\_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom) $<$br /$>$ Johannes Friedrich, University of Bayreuth (Germany)$<$br /$>$ & Kreutzer, S., Friedrich, J., 2020. plot\_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   4 & run\_MC\_CW\_IRSL\_LOC & Monte-Carlo Simulation for CW-IRSL (localized transitions) & Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_CW\_IRSL\_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_CW\_IRSL\_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   5 & run\_MC\_CW\_IRSL\_TUN & Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions) & Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the model for tunnelling transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap, into a recombination centre. & 0.2.0
- &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_CW\_IRSL\_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_CW\_IRSL\_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   6 & run\_MC\_CW\_OSL\_DELOC & Run Monte-Carlo Simulation for CW-OSL (delocalized transitions) & Runs a Monte-Carlo (MC) simulation of continuous wave optically stimulated luminescence (CW-OSL) using the one trap one recombination centre (OTOR) model. The term delocalized here refers to the involvement of the conduction band. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_CW\_OSL\_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_CW\_OSL\_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   7 & run\_MC\_ISO\_DELOC & Run Monte-Carlo Simulation for ISO-TL (delocalized transitions) & Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_ISO\_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_ISO\_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   8 & run\_MC\_ISO\_LOC & Run Monte-Carlo simulation for ISO-TL (localized transitions) & Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do no involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_ISO\_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_ISO\_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   9 & run\_MC\_ISO\_TUN & Monte-Carlo Simulation for ISO-TL (tunnelling transitions) & Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into the recombination centre. & 0.1.0
- &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_ISO\_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_ISO\_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   10 & run\_MC\_LM\_OSL\_DELOC & Run Monte-Carlo Simulation for LM-OSL (delocalized transitions) & Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_LM\_OSL\_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_LM\_OSL\_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   11 & run\_MC\_LM\_OSL\_LOC & Run Monte-Carlo Simulation for LM-OSL (localized transitions) & Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trap, and also involve a an energy state of the recombination centre. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_LM\_OSL\_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_LM\_OSL\_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   12 & run\_MC\_LM\_OSL\_TUN & Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions) & Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into a recombination centre. & 0.1.0
- &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_LM\_OSL\_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Johannes Friedrich, University of Bayreuth (Germany),$<$br /$>$ Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_LM\_OSL\_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   13 & run\_MC\_TL\_DELOC & Run Monte-Carlo Simulation for TL (delocalized transitions) & Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. The heating rate in this function is assumed to be 1 K/s. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_TL\_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_TL\_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   14 & run\_MC\_TL\_LOC & Run Monte-Carlo Simulation for TL (localized transitions) & Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. The heating rate in this function is assumed to be 1 K/s. & 0.1.0
- &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_TL\_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Sebastian Kreutzer, Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Kreutzer, S., 2020. run\_MC\_TL\_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
   15 & run\_MC\_TL\_TUN & Run Monte-Carlo Simulation for TL (tunnelling transitions) & Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) caused by tunnelling (TUN) transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap into a recombination centre. The heating rate in this function is assumed to be 1 K/s. & 0.1.0
- &  &  & Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,$<$br /$>$ Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_TL\_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+ &  &  & Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer,$<$br /$>$ Geography \& Earth Sciences, Aberystwyth University (United Kingdom)$<$br /$>$ & Friedrich, J., Kreutzer, S., 2020. run\_MC\_TL\_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
  \\ 
    \hline
 \end{tabular}
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions_Markdown.md b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions_Markdown.md
similarity index 90%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions_Markdown.md
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions_Markdown.md
index 3021189..d59010a 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-Functions_Markdown.md
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-Functions_Markdown.md
@@ -1,20 +1,20 @@
 
 
-| Name                 | Title                                                           | Description                                                                                                                                                                                                                                                                                                                                                                                                                         | Version | m.Date | m.Time | Author                                                                                                                                                     | Citation                                                                                                                                                                                                                                                                                                          |
-|:---------------------|:----------------------------------------------------------------|:------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|:--------|:-------|:-------|:-----------------------------------------------------------------------------------------------------------------------------------------------------------|:------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|
-| create_ClusterSystem | Create dosimetric cluster system                                | In order to allow interaction of an spatial a correlation clusters in RLumCarlo, first a dosimetric system needs to be created in a three-dimensional space, which is the purpose of this function.                                                                                                                                                                                                                                 | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                                             |
-| methods_RLumCarlo    | methods_RLumCarlo                                               | Methods for S3-generics implemented for the package 'RLumCarlo'.                                                                                                                                                                                                                                                                                                                                                                    | NA      | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom), -  Johannes Friedrich, University of Bayreuth (Germany), -  | Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                                                                        |
-| plot_RLumCarlo       | Plot RLumCarlo Monte-Carlo Simulation Results                   | Visualise 'RLumCarlo' modelling results without extracting the values manually. Typically visualised are the averaged signal or the number of remaining electrons, with a polygon indicating modelling uncertainties.                                                                                                                                                                                                               | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)  -  Johannes Friedrich, University of Bayreuth (Germany) -   | Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                       |
-| run_MC_CW_IRSL_LOC   | Monte-Carlo Simulation for CW-IRSL (localized transitions)      | Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.                        | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                     |
-| run_MC_CW_IRSL_TUN   | Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions) | Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the model for tunnelling transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap, into a recombination centre.                                                                                                                                                          | 0.2.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. |
-| run_MC_CW_OSL_DELOC  | Run Monte-Carlo Simulation for CW-OSL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of continuous wave optically stimulated luminescence (CW-OSL) using the one trap one recombination centre (OTOR) model. The term delocalized here refers to the involvement of the conduction band.                                                                                                                                                                                              | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.               |
-| run_MC_ISO_DELOC     | Run Monte-Carlo Simulation for ISO-TL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.                                                                                                                                                                                                                      | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                  |
-| run_MC_ISO_LOC       | Run Monte-Carlo simulation for ISO-TL (localized transitions)   | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do no involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.                               | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                      |
-| run_MC_ISO_TUN       | Monte-Carlo Simulation for ISO-TL (tunnelling transitions)      | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into the recombination centre.                                                                                                                                                              | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.          |
-| run_MC_LM_OSL_DELOC  | Run Monte-Carlo Simulation for LM-OSL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.                                                                                                                                                                                                             | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.               |
-| run_MC_LM_OSL_LOC    | Run Monte-Carlo Simulation for LM-OSL (localized transitions)   | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trap, and also involve a an energy state of the recombination centre.                             | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                   |
-| run_MC_LM_OSL_TUN    | Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions)  | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into a recombination centre.                                                                                                                                                       | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.   |
-| run_MC_TL_DELOC      | Run Monte-Carlo Simulation for TL (delocalized transitions)     | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. The heating rate in this function is assumed to be 1 K/s.                                                                                                                                                                                         | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                       |
-| run_MC_TL_LOC        | Run Monte-Carlo Simulation for TL (localized transitions)       | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. The heating rate in this function is assumed to be 1 K/s. | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.                           |
-| run_MC_TL_TUN        | Run Monte-Carlo Simulation for TL (tunnelling transitions)      | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) caused by tunnelling (TUN) transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap into a recombination centre. The heating rate in this function is assumed to be 1 K/s.                                                                                                                                        | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer, -  Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4.           |
+| Name                 | Title                                                           | Description                                                                                                                                                                                                                                                                                                                                                                                                                         | Version | m.Date | m.Time | Author                                                                                                                                                     | Citation                                                                                                                                                                                                                                                                                                                                                       |
+|:---------------------|:----------------------------------------------------------------|:------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|:--------|:-------|:-------|:-----------------------------------------------------------------------------------------------------------------------------------------------------------|:---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|
+| create_ClusterSystem | Create dosimetric cluster system                                | In order to allow interaction of an spatial a correlation clusters in RLumCarlo, first a dosimetric system needs to be created in a three-dimensional space, which is the purpose of this function.                                                                                                                                                                                                                                 | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                                             |
+| methods_RLumCarlo    | methods_RLumCarlo                                               | Methods for S3-generics implemented for the package 'RLumCarlo'.                                                                                                                                                                                                                                                                                                                                                                    | NA      | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom), -  Johannes Friedrich, University of Bayreuth (Germany), -  | Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                                                                        |
+| plot_RLumCarlo       | Plot RLumCarlo Monte-Carlo Simulation Results                   | Visualise 'RLumCarlo' modelling results without extracting the values manually. Typically visualised are the averaged signal or the number of remaining electrons, with a polygon indicating modelling uncertainties.                                                                                                                                                                                                               | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom)  -  Johannes Friedrich, University of Bayreuth (Germany) -   | Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                       |
+| run_MC_CW_IRSL_LOC   | Monte-Carlo Simulation for CW-IRSL (localized transitions)      | Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.                        | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                     |
+| run_MC_CW_IRSL_TUN   | Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions) | Runs a Monte-Carlo (MC) simulation of continuous wave infrared stimulated luminescence (CW-IRSL) using the model for tunnelling transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap, into a recombination centre.                                                                                                                                                          | 0.2.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo |
+| run_MC_CW_OSL_DELOC  | Run Monte-Carlo Simulation for CW-OSL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of continuous wave optically stimulated luminescence (CW-OSL) using the one trap one recombination centre (OTOR) model. The term delocalized here refers to the involvement of the conduction band.                                                                                                                                                                                              | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo               |
+| run_MC_ISO_DELOC     | Run Monte-Carlo Simulation for ISO-TL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.                                                                                                                                                                                                                      | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                  |
+| run_MC_ISO_LOC       | Run Monte-Carlo simulation for ISO-TL (localized transitions)   | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do no involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre.                               | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                      |
+| run_MC_ISO_TUN       | Monte-Carlo Simulation for ISO-TL (tunnelling transitions)      | Runs a Monte-Carlo (MC) simulation of isothermally stimulated luminescence (ISO-TL or ITL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into the recombination centre.                                                                                                                                                              | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo          |
+| run_MC_LM_OSL_DELOC  | Run Monte-Carlo Simulation for LM-OSL (delocalized transitions) | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band.                                                                                                                                                                                                             | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo               |
+| run_MC_LM_OSL_LOC    | Run Monte-Carlo Simulation for LM-OSL (localized transitions)   | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trap, and also involve a an energy state of the recombination centre.                             | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                   |
+| run_MC_LM_OSL_TUN    | Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions)  | Runs a Monte-Carlo (MC) simulation of linearly modulated optically stimulated luminescence (LM-OSL) using the tunnelling (TUN) model. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trapped charge, into a recombination centre.                                                                                                                                                       | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), -  Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo   |
+| run_MC_TL_DELOC      | Run Monte-Carlo Simulation for TL (delocalized transitions)     | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the one trap one recombination centre (OTOR) model. Delocalised refers to involvement of the conduction band. The heating rate in this function is assumed to be 1 K/s.                                                                                                                                                                                         | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                       |
+| run_MC_TL_LOC        | Run Monte-Carlo Simulation for TL (localized transitions)       | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) using the generalized one trap (GOT) model. Localized transitions refer to transitions which do not involve the conduction or valence band. These transitions take place between the ground state and an excited state of the trapped charge, and also involve an energy state of the recombination centre. The heating rate in this function is assumed to be 1 K/s. | 0.1.0   | NA     | NA     | Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United Kingdom) -                                                               | Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo                           |
+| run_MC_TL_TUN        | Run Monte-Carlo Simulation for TL (tunnelling transitions)      | Runs a Monte-Carlo (MC) simulation of thermoluminescence (TL) caused by tunnelling (TUN) transitions. Tunnelling refers to quantum mechanical tunnelling processes from the excited state of the trap into a recombination centre. The heating rate in this function is assumed to be 1 K/s.                                                                                                                                        | 0.1.0   | NA     | NA     | Johannes Friedrich, University of Bayreuth (Germany), Sebastian Kreutzer, -  Geography & Earth Sciences, Aberystwyth University (United Kingdom) -   | Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo           |
 
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-bibliography.bib b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-bibliography.bib
similarity index 88%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-bibliography.bib
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-bibliography.bib
index c2ba266..643e770 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-bibliography.bib
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-bibliography.bib
@@ -2,6 +2,6 @@ @Manual{
   title = {RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena},
   author = {Johannes Friedrich and Sebastian Kreutzer and Vasilis Pagonis and Christoph Schmidt},
   year = {2020},
-  note = {R package version 0.1.4},
+  note = {R package version 0.1.5},
   url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-fun_bibliography.bib b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-fun_bibliography.bib
similarity index 77%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4-fun_bibliography.bib
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5-fun_bibliography.bib
index dc48b75..e694da8 100644
--- a/RLumCarlo.BuildResults/RLumCarlo_0.1.4-fun_bibliography.bib
+++ b/RLumCarlo.BuildResults/RLumCarlo_0.1.5-fun_bibliography.bib
@@ -3,119 +3,134 @@ @InCollection{
   title = {create_ClusterSystem(): Create dosimetric cluster system},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {methods_RLumCarlo(): methods_RLumCarlo},
   volume = {version: },
   author = {Kreutzer S and Friedrich J},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results},
   volume = {version: 0.1.0},
   author = {Kreutzer S and Friedrich J},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions)},
   volume = {version: 0.2.0},
   author = {Friedrich J and Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions)},
   volume = {version: 0.1.0},
   author = {Friedrich J and Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions)},
   volume = {version: 0.1.0},
   author = {Friedrich J and Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions)},
   volume = {version: 0.1.0},
   author = {Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
 @InCollection{,
   title = {run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions)},
   volume = {version: 0.1.0},
   author = {Friedrich J and Kreutzer S},
-  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. },
+  booktitle = {Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5.},
   publisher = {RLumCarlo},
   year = {2020},
+  url = {https://CRAN.R-project.org/package=RLumCarlo},
 }
diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.4.pdf b/RLumCarlo.BuildResults/RLumCarlo_0.1.5.pdf
similarity index 84%
rename from RLumCarlo.BuildResults/RLumCarlo_0.1.4.pdf
rename to RLumCarlo.BuildResults/RLumCarlo_0.1.5.pdf
index c197391..bc80357 100644
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diff --git a/RLumCarlo.BuildResults/RLumCarlo_0.1.5.tar.gz b/RLumCarlo.BuildResults/RLumCarlo_0.1.5.tar.gz
new file mode 100644
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diff --git a/codemeta.json b/codemeta.json
index 4ca2a3b..bbbdcf7 100644
--- a/codemeta.json
+++ b/codemeta.json
@@ -10,7 +10,7 @@
   "codeRepository": "https://CRAN.R-project.org/package=RLumCarlo",
   "issueTracker": "https://github.com/R-Lum/RLumCarlo/issues",
   "license": "https://spdx.org/licenses/GPL-3.0",
-  "version": "0.1.4",
+  "version": "0.1.5",
   "programmingLanguage": {
     "@type": "ComputerLanguage",
     "name": "R",
@@ -253,5 +253,12 @@
     "https://travis-ci.org/R-Lum/RLumCarlo",
     "https://ci.appveyor.com/project/RLumSK/rlumcarlo",
     "https://codecov.io/gh/R-Lum/RLumCarlo"
-  ]
+  ],
+  "provider": {
+    "@id": "https://cran.r-project.org",
+    "@type": "Organization",
+    "name": "Comprehensive R Archive Network (CRAN)",
+    "url": "https://cran.r-project.org"
+  },
+  "relatedLink": "https://CRAN.R-project.org/package=RLumCarlo"
 }
diff --git a/cran-comments.md b/cran-comments.md
index 35037ac..a1580fc 100644
--- a/cran-comments.md
+++ b/cran-comments.md
@@ -1,71 +1,13 @@
 Dear CRAN-Team, 
 
-This replaces RLumCarlo v0.1.3 currently under inspection by the CRAN Team. 
+This fixes the error message for the CRAN Solaris check ressource flagged
+thanks to Prof Ripley. 
 
-After my submission yesterday, I realised a couple of other problems with links and possibly misspelt words. This will likely lead to another rejection of my submission. 
-The following measures are now implemented, to avoid wasting more time of the CRAN Team: 
-
-* The package now uses a WORDLIST and unit test with the package 'spelling'
-* All flagged misspelt words were corrected
-* I removed all 'bad' DOIs from the manual, except for the DESCRIPTION file (where it was requested by the CRAN Team). 
-* The corresponding references are still correctly mentioned in the manual, but not anymore linked through a DOI. However, I notified the publisher, and I will add these DOIs again as soon as the underlying problem got solved.
-
-Thank you very much for your patience and support!
-
-On behalf of the RLumCarlo package developer team, best wishes, 
+Thank you for your support and on behalf of the RLumCarlo package developer team, 
+best wishes, 
 
 Sebastian Kreutzer
 
-## Responses to 3rd rejection
-
->  Possibly mis-spelled words in DESCRIPTION:
->  linerarly (32:5)
-
-Done and I am very sorry for the extra round and the trouble.
-
-## Responses to 2nd rejection
-
-> Please always use the canonical link for R packages.
-> Please fix and resubmit, and document what was changed in the submission comments.
-
-The flagged link was: `https://www.r-pkg.org/pkg/RLumCarlo`. 
-
-This is **not** a link, this is the URL to retrive the badge: 
-
-`[![CRAN](https://www.r-pkg.org/badges/version/RLumCarlo)](https://cran.r-project.org/package=RLumCarlo)`
-
-If you click on the badge the site link is: https://cran.r-project.org/package=RLumCarlo
-To be sure, I changed it now to `https://CRAN.R-project.org/package=RLumCarlo`. 
-Obviosuly it does not change the URL, but maybe this is what was meant. 
-
-
-## Responses to 1st rejection
-
-> If there are references describing the (theoretical background of) methods in your package, please add these in the Description field of your DESCRIPTION file in the form
-> authors (year) <doi:...>
-> authors (year) <arXiv:...>
-> authors (year, ISBN:...)
-> with no space after 'doi:', 'arXiv:' and angle brackets for auto-linking.
-
-Done.
-
-> Please replace \dontrun{} by \donttest{} or unwap the examples if they can be 
-executed in less than 5 sec per Rd-file.
-
-Nothing done. We have at least one running example per function (not wrapped
-in `\dontrun{}`) If we wrapped something in `\dontrun{}` it was because
-it exceeded this 5 s but we wanted to provide some longer examples 
-(obviously it depends a little bit on the computer, 
-but we did not want to push it too far and overcharge CRAN resources). 
-More examples can be found in the vignette. 
-
->You are changing the user's par() settings in your functions. Please ensure with an immediate call of on.exit() that the settings are reset. E.g.
->   opar <- par(no.readonly =TRUE)       # code line i
->   on.exit(par(opar))                   # code line i+1
-
-Added as requested in code-lines 120-121 in `plot_RLumCarlo()` (the only 
-function that produces a plot output).
-
 ## R CMD check --as-cran results
 
 0 errors | 0 warnings | 1 note
diff --git a/man/create_ClusterSystem.Rd b/man/create_ClusterSystem.Rd
index d029cd3..8e64ba6 100644
--- a/man/create_ClusterSystem.Rd
+++ b/man/create_ClusterSystem.Rd
@@ -45,7 +45,7 @@ Sebastian Kreutzer, Geography & Earth Sciences, Aberystwyth University (United K
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. create_ClusterSystem(): Create dosimetric cluster system. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \keyword{data}
diff --git a/man/figures/README-unnamed-chunk-2-1.png b/man/figures/README-unnamed-chunk-2-1.png
index 5d556fc..1162f55 100644
Binary files a/man/figures/README-unnamed-chunk-2-1.png and b/man/figures/README-unnamed-chunk-2-1.png differ
diff --git a/man/methods_RLumCarlo.Rd b/man/methods_RLumCarlo.Rd
index e418b2a..95350ab 100644
--- a/man/methods_RLumCarlo.Rd
+++ b/man/methods_RLumCarlo.Rd
@@ -50,7 +50,7 @@ Johannes Friedrich, University of Bayreuth (Germany),
 } 
 
 \section{How to cite}{
-Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., Friedrich, J., 2020. methods_RLumCarlo(): methods_RLumCarlo. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \keyword{internal}
diff --git a/man/plot_RLumCarlo.Rd b/man/plot_RLumCarlo.Rd
index 6333d3b..803e89b 100644
--- a/man/plot_RLumCarlo.Rd
+++ b/man/plot_RLumCarlo.Rd
@@ -83,7 +83,7 @@ Johannes Friedrich, University of Bayreuth (Germany)
 } 
 
 \section{How to cite}{
-Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., Friedrich, J., 2020. plot_RLumCarlo(): Plot RLumCarlo Monte-Carlo Simulation Results. Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \keyword{hplot}
diff --git a/man/run_MC_CW_IRSL_LOC.Rd b/man/run_MC_CW_IRSL_LOC.Rd
index 73c354e..87cfb4e 100644
--- a/man/run_MC_CW_IRSL_LOC.Rd
+++ b/man/run_MC_CW_IRSL_LOC.Rd
@@ -80,7 +80,7 @@ plot_RLumCarlo(legend = TRUE)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_CW_IRSL_LOC(): Monte-Carlo Simulation for CW-IRSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_CW_IRSL_TUN.Rd b/man/run_MC_CW_IRSL_TUN.Rd
index 58590f0..fe18dad 100644
--- a/man/run_MC_CW_IRSL_TUN.Rd
+++ b/man/run_MC_CW_IRSL_TUN.Rd
@@ -91,7 +91,7 @@ run_MC_CW_IRSL_TUN(
 } 
 
 \section{How to cite}{
-Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Friedrich, J., Kreutzer, S., 2020. run_MC_CW_IRSL_TUN(): Run Monte-Carlo Simulation for CW-IRSL (tunnelling transitions). Function version 0.2.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_CW_OSL_DELOC.Rd b/man/run_MC_CW_OSL_DELOC.Rd
index f83cc68..3981253 100644
--- a/man/run_MC_CW_OSL_DELOC.Rd
+++ b/man/run_MC_CW_OSL_DELOC.Rd
@@ -130,7 +130,7 @@ legend("topright",
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_CW_OSL_DELOC(): Run Monte-Carlo Simulation for CW-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_ISO_DELOC.Rd b/man/run_MC_ISO_DELOC.Rd
index 8b4b73d..f350386 100644
--- a/man/run_MC_ISO_DELOC.Rd
+++ b/man/run_MC_ISO_DELOC.Rd
@@ -90,7 +90,7 @@ plot_RLumCarlo(legend = TRUE)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_ISO_DELOC(): Run Monte-Carlo Simulation for ISO-TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_ISO_LOC.Rd b/man/run_MC_ISO_LOC.Rd
index bc1271b..54dd602 100644
--- a/man/run_MC_ISO_LOC.Rd
+++ b/man/run_MC_ISO_LOC.Rd
@@ -89,7 +89,7 @@ plot_RLumCarlo(legend = TRUE)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_ISO_LOC(): Run Monte-Carlo simulation for ISO-TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_ISO_TUN.Rd b/man/run_MC_ISO_TUN.Rd
index b884c2b..aa75994 100644
--- a/man/run_MC_ISO_TUN.Rd
+++ b/man/run_MC_ISO_TUN.Rd
@@ -121,7 +121,7 @@ plot_RLumCarlo(results, legend = TRUE)
 } 
 
 \section{How to cite}{
-Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Friedrich, J., Kreutzer, S., 2020. run_MC_ISO_TUN(): Monte-Carlo Simulation for ISO-TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_LM_OSL_DELOC.Rd b/man/run_MC_LM_OSL_DELOC.Rd
index 5e88a44..a9e11b9 100644
--- a/man/run_MC_LM_OSL_DELOC.Rd
+++ b/man/run_MC_LM_OSL_DELOC.Rd
@@ -81,7 +81,7 @@ plot_RLumCarlo(legend = TRUE)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_LM_OSL_DELOC(): Run Monte-Carlo Simulation for LM-OSL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_LM_OSL_LOC.Rd b/man/run_MC_LM_OSL_LOC.Rd
index aa29b43..8f6278e 100644
--- a/man/run_MC_LM_OSL_LOC.Rd
+++ b/man/run_MC_LM_OSL_LOC.Rd
@@ -98,7 +98,7 @@ plot_RLumCarlo(results, legend = TRUE)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_LM_OSL_LOC(): Run Monte-Carlo Simulation for LM-OSL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_LM_OSL_TUN.Rd b/man/run_MC_LM_OSL_TUN.Rd
index b625031..5e4d988 100644
--- a/man/run_MC_LM_OSL_TUN.Rd
+++ b/man/run_MC_LM_OSL_TUN.Rd
@@ -108,7 +108,7 @@ plot_RLumCarlo(results, norm = TRUE)
 } 
 
 \section{How to cite}{
-Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Friedrich, J., Kreutzer, S., 2020. run_MC_LM_OSL_TUN(): Run Monte-Carlo Simulation for LM-OSL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_TL_DELOC.Rd b/man/run_MC_TL_DELOC.Rd
index b2edb62..b56d0f0 100644
--- a/man/run_MC_TL_DELOC.Rd
+++ b/man/run_MC_TL_DELOC.Rd
@@ -152,7 +152,7 @@ legend("topright",
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_TL_DELOC(): Run Monte-Carlo Simulation for TL (delocalized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_TL_LOC.Rd b/man/run_MC_TL_LOC.Rd
index b424e23..0e2f0a3 100644
--- a/man/run_MC_TL_LOC.Rd
+++ b/man/run_MC_TL_LOC.Rd
@@ -106,7 +106,7 @@ plot_RLumCarlo(results)
 } 
 
 \section{How to cite}{
-Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Kreutzer, S., 2020. run_MC_TL_LOC(): Run Monte-Carlo Simulation for TL (localized transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/man/run_MC_TL_TUN.Rd b/man/run_MC_TL_TUN.Rd
index 19ffa8a..7528684 100644
--- a/man/run_MC_TL_TUN.Rd
+++ b/man/run_MC_TL_TUN.Rd
@@ -117,7 +117,7 @@ plot_RLumCarlo(results)
 } 
 
 \section{How to cite}{
-Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.4. 
+Friedrich, J., Kreutzer, S., 2020. run_MC_TL_TUN(): Run Monte-Carlo Simulation for TL (tunnelling transitions). Function version 0.1.0. In: Friedrich, J., Kreutzer, S., Pagonis, V., Schmidt, C., 2020. RLumCarlo: Monte-Carlo Methods for Simulating Luminescence Phenomena. R package version 0.1.5. https://CRAN.R-project.org/package=RLumCarlo
 }
 
 \references{
diff --git a/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.Rmd b/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.Rmd
index 6fb2b20..3594277 100644
--- a/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.Rmd
+++ b/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.Rmd
@@ -128,7 +128,7 @@ iso-thermal (ITL) signal for a temperature (`T`) of 200 °C over
 depth and a frequency factor of $1\times10^{10}$ (1/s). The parameter `rho` ($\rho'$) defines the 
 recombination centre density. 
 
-```{r Fig 1, fig.align='center', cache=TRUE, fig.height=4, fig.width=5}
+```{r Fig 1, fig.align='center', cache=FALSE, fig.height=4, fig.width=5}
 results <- run_MC_ISO_TUN(
   E = 1.2,
   s = 1e10,
@@ -149,7 +149,7 @@ For example, one could assume that the number of initial electrons vary randomly
 between 190 and 210. Such a situation is created in the next example. Generally, 
 \`RLumCarlo' supports such an input for the parameters `N_e` and `n_filled`.
 
-```{r Fig 1b, fig.align='center', cache=TRUE, fig.height=4, fig.width=5}
+```{r Fig 1b, fig.align='center', cache=FALSE, fig.height=4, fig.width=5}
 results <- run_MC_ISO_TUN(
   E = 1.2,
   s = 1e10,
@@ -241,7 +241,7 @@ Contrary to the example above, here the results are stored in a `list` and `plot
 is called only one time and it will then iterate automatically over the results to 
 create a combined plot.
 
-```{r Fig 5, fig.align='center', cache = TRUE}
+```{r Fig 5, fig.align='center', cache = FALSE}
 s <- 3.5e12
 rho <- 0.015
 E <- 1.45
@@ -262,7 +262,7 @@ results <- lapply(r_c, function(x) {
 The plot output can be highly customised to provide a better visual experience, e.g., 
 the manual setting of the colours and the legend.
 
-```{r Fig 6,Plot average signal, fig.align='center', echo = TRUE, cache = TRUE, fig.height=4, fig.width=5}
+```{r Fig 6,Plot average signal, fig.align='center', echo = TRUE, cache = FALSE, fig.height=4, fig.width=5}
 ## plot curves, but without legend
 plot_RLumCarlo(
   object = results, 
@@ -294,7 +294,7 @@ clusters <- create_ClusterSystem(n = 100, plot = TRUE)
 ```
 The result is an arbitrary dosimetric system with randomly distributed clusters. The Euclidean distance is used to group the clusters (colour code). To use the system in the simulation, instead of providing a scalar as input to `clusters`, the output of `create_ClusterSystem()` can be injected in every `run_MC` function.
 
-```{r, echo = TRUE, fig.align='center', cache = TRUE, fig.height=4, fig.width=5}
+```{r, echo = TRUE, fig.align='center', cache = FALSE, fig.height=4, fig.width=5}
 run_MC_TL_LOC(
  s = 1e14,
  E = 0.9,
diff --git a/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.pdf b/vignettes/RLumCarlo_-_Getting_started_with_RLumCarlo.pdf
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