further cleanup

database/data-nk/main/CdSe/Ninomiya-cubic.yml

@@ -3,8 +3,14 @@
 # copyright and related rights waived via CC0 1.0
 
 REFERENCES: |
-    "1) S. Ninomiya and S. Adachi. Optical properties of cubic and hexagonal CdSe, <a href="https://doi.org/10.1063/1.359815"><i>J. Appl. Phys.</i> <b>78</b>, 4681-4689 (1995)</a><br>2) Y. D. Kim, M. V. Klein, S. F. Ren, Y. C. Chang, H. Luo, N. Samarth, J. K. Furdyna.
-    Optical properties of zinc-blende CdSe and Zn<sub>x</sub>Cd<sub>1−x</sub>Se films grown on GaAs, <a href="https://doi.org/10.1103/PhysRevB.49.7262"><i>Phys. Rev. B</i> <b>49</b>, 7262-7270 (1994)</a><br>* Authors of Ref. 1 provide a simplified model of the interband transitions (MDF) based on the experimental data from Ref. 2.<br>[<a href="https://github.com/polyanskiy/refractiveindex.info-scripts/blob/master/scripts/Ninomiya%201995%20-%20cubic%20CdSe.py">Calculation script (Python)</a>]"
+    1) S. Ninomiya and S. Adachi.
+    Optical properties of cubic and hexagonal CdSe,
+    <a href="https://doi.org/10.1063/1.359815"><i>J. Appl. Phys.</i> <b>78</b>, 4681-4689 (1995)</a><br>
+    2) Y. D. Kim, M. V. Klein, S. F. Ren, Y. C. Chang, H. Luo, N. Samarth, J. K. Furdyna.
+    Optical properties of zinc-blende CdSe and Zn<sub>x</sub>Cd<sub>1−x</sub>Se films grown on GaAs,
+    <a href="https://doi.org/10.1103/PhysRevB.49.7262"><i>Phys. Rev. B</i> <b>49</b>, 7262-7270 (1994)</a><br>
+    * Authors of Ref. 1 provide a simplified model of the interband transitions (MDF) based on the experimental data from Ref. 2.<br>
+    [<a href="https://github.com/polyanskiy/refractiveindex.info-scripts/blob/master/scripts/Ninomiya%201995%20-%20cubic%20CdSe.py">Calculation script (Python)</a>]
 COMMENTS: |
     Cubic CdSe. Room temperature.
 DATA:

database/data-nk/main/InP/Pettit.yml

@@ -3,8 +3,14 @@
 # copyright and related rights waived via CC0 1.0
 
 REFERENCES: |
-    "1) G. D. Pettit and W. J. Turner. Refractive index of InP, <a href="https://doi.org/10.1063/1.1714410"><i>J. Appl. Phys.</i> <b>36</b>, 2081 (1965)</a><br>2) A. N. Pikhtin and A. D. Yas’kov. Disperson of the refractive index
-    of semiconductors with diamond and zinc-blende structures, <i>Sov. Phys. Semicond.</i> <b>12</b>, 622-626 (1978) (as cited in Handbook of Optics, 2nd edition, Vol. 2. McGraw-Hill 1994)<br>3) Handbook of Optics, 2nd edition, Vol. 2. McGraw-Hill 1994<br> * Ref. 3 provides a Sellmeier equation based on data from Ref. 1 and Ref. 2."
+    1) G. D. Pettit and W. J. Turner.
+    Refractive index of InP,
+    <a href="https://doi.org/10.1063/1.1714410"><i>J. Appl. Phys.</i> <b>36</b>, 2081 (1965)</a><br>
+    2) A. N. Pikhtin and A. D. Yas’kov.
+    Disperson of the refractive index of semiconductors with diamond and zinc-blende structures,
+    <i>Sov. Phys. Semicond.</i> <b>12</b>, 622-626 (1978) (as cited in Handbook of Optics, 2nd edition, Vol. 2. McGraw-Hill 1994)<br>
+    3) Handbook of Optics, 2nd edition, Vol. 2. McGraw-Hill 1994<br>
+    * Ref. 3 provides a Sellmeier equation based on data from Ref. 1 and Ref. 2.
 COMMENTS: |
     Room temperature
 DATA:

database/data-nk/main/Si/Schinke.yml

@@ -3,8 +3,11 @@
 # copyright and related rights waived via CC0 1.0
 
 REFERENCES: |
-    "1) C. Schinke, P. C. Peest, J. Schmidt, R. Brendel,  K. Bothe, M. R. Vogt, I. Kröger, S. Winter, A. Schirmacher, S. Lim, H. T. Nguyen, D. MacDonald. Uncertainty analysis for the coefficient of band-to-band absorption of crystalline silicon.
-    <a href="https://doi.org/10.1063%2F1.4923379"><i>AIP Advances</i> <b>5</b>, 67168 (2015)</a><br>2) M. R. Vogt. <i>Development of physical models for the simulation of optical properties of solar cell modules</i>, <a href="https://www.tib.eu/en/search/id/TIBKAT%3A852464657">PhD. Thesis (2015)</a>"
+    1) C. Schinke, P. C. Peest, J. Schmidt, R. Brendel,  K. Bothe, M. R. Vogt, I. Kröger, S. Winter, A. Schirmacher, S. Lim, H. T. Nguyen, D. MacDonald.
+    Uncertainty analysis for the coefficient of band-to-band absorption of crystalline silicon.
+    <a href="https://doi.org/10.1063%2F1.4923379"><i>AIP Advances</i> <b>5</b>, 67168 (2015)</a><br>
+    2) M. R. Vogt. <i>Development of physical models for the simulation of optical properties of solar cell modules</i>,
+    <a href="https://www.tib.eu/en/search/id/TIBKAT%3A852464657">PhD. Thesis (2015)</a>
 COMMENTS: |
     Relative uncertainties of the absorption coefficient: 0.4% at 0.250 µm, 11% at 0.6 µm, 1.4% at 1 µm, 12% at 1.2 µm and 180% at 1.45 µm. Temperature: 295 K.
 DATA:

database/data-nk/main/SiO2/Malitson.yml

@@ -3,15 +3,18 @@
 # copyright and related rights waived via CC0 1.0
 
 REFERENCES: |
-    "1) I. H. Malitson. Interspecimen comparison of the refractive index of fused silica, <a href="https://doi.org/10.1364/JOSA.55.001205"><i>J. Opt. Soc. Am.</i> <b>55</b>, 1205-1208 (1965)</a><br>2) C. Z. Tan. Determination of refractive index of silica glass for infrared wavelengths by IR spectroscopy, <a href="https://doi.org/10.1016/S0022-3093(97)00438-9"><i>J. Non-Cryst. Solids</i> <b>223</b>, 158-163 (1998)</a><br>
-    <sup>*</sup> Sellmeier formula is reported in Ref. 1 for the 0.21-3.71 μm wavelength range. Ref. 2 verifies the validity of the formula up to 6.7 μm."
+    1) I. H. Malitson.
+    Interspecimen comparison of the refractive index of fused silica,
+    <a href="https://doi.org/10.1364/JOSA.55.001205"><i>J. Opt. Soc. Am.</i> <b>55</b>, 1205-1208 (1965)</a><br>
+    2) C. Z. Tan.
+    Determination of refractive index of silica glass for infrared wavelengths by IR spectroscopy,
+    <a href="https://doi.org/10.1016/S0022-3093(97)00438-9"><i>J. Non-Cryst. Solids</i> <b>223</b>, 158-163 (1998)</a><br>
+    * Sellmeier formula is reported in Ref. 1 for the 0.21–3.71 μm wavelength range. Ref. 2 verifies the validity of the formula up to 6.7 μm.
 COMMENTS: |
     Fused silica, 20 °C
 DATA:
   - type: formula 1
     wavelength_range: 0.21 6.7
     coefficients: 0 0.6961663 0.0684043 0.4079426 0.1162414 0.8974794 9.896161
 SPECS:
-    n_is_absolute: false
-    wavelength_is_vacuum: false
     temperature: 20 °C