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LBNFTargetL150cmFinsOff2.inp
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TITLE
LBNF RAL 1.5m cantilevered target simulation
* Set the defaults for precision simulations
DEFAULTS PRECISIO
* Beam parameters: 120 GeV/c protons, sigma = 2.667 mm, FWHM = 2*sqrt(2*ln2)*sigma = 2.355*sigma = 6.281 mm
BEAM 120. 0.0 0.0 -0.628 -0.628 PROTON
* Beam position: 1cm z offset from the start of the upstream baffle; 2 sigma = 5.334 mm horizontal offset
BEAMPOS 0.5334 0.0 -42. 0.0 0.0
MGNFIELD 30. 0.05 0.05 0.0 0.0 0.0
GEOBEGIN COMBNAME
0 0
* Black body
SPH blkbody 0.0 0.0 0.0 100000.
* Large void sphere
SPH void 0.0 0.0 0.0 10000.
* Outer volume
RCC outvol 0.0 0.0 -50. 0.0 0.0 290. 30.
ZCC r2p9 0.0 0.0 2.9
ZCC r3p3 0.0 0.0 3.3
ZCC r5 0.0 0.0 5.
ZCC r6p9 0.0 0.0 6.9
ZCC r7p4 0.0 0.0 7.4
ZCC r9p5 0.0 0.0 9.5
ZCC r12p2 0.0 0.0 12.2
ZCC r12p7 0.0 0.0 12.7
ZCC r13p73 0.0 0.0 13.73
ZCC r14p5 0.0 0.0 14.5
ZCC r19 0.0 0.0 19.
ZCC r19p5 0.0 0.0 19.5
ZCC r20 0.0 0.0 20.
XYP z0 0.0
XYP zm40 -40.
XYP zm30 -30.
XYP zm29p5 -29.5
XYP zm20 -20.
XYP zm16p54 -16.54
XYP zm15p5 -15.5
XYP zm14p09 -14.09
XYP zm14p04 -14.04
XYP zm12p49 -12.49
XYP zm11p15 -11.15
XYP zm10p76 -10.76
XYP zm6p52 -6.52
XYP zm5 -5.
XYP zm4 -4.
XYP zm2p5 -2.5
XYP z8p0855 8.0855
XYP z40 40.
XYP z76 76.
XYP z112 112.
XYP z116p3 116.3
XYP z145 145.
XYP z148 148.
XYP z149p4 149.4
XYP z150 150.
XYP z150p6 150.6
XYP z157 157.
XYP z212 212.
XYP z215 215.
XYP z216 216.
XYP z219p5 219.5
XYP z222p5 222.5
XYP z224 224.
XYP z225 225.
XYP z240 240.
* Fin boundary 1 at +46 deg, z = 40 cm, top, pointing NW; 0.5 mm to 1 mm thick radially; direction = (-sinPhi, cosPhi, 0)
PLA xy1 -0.71934 0.69466 0.0 0.0 0.0 40.
* Fin boundary 2 at +44 deg, z = 40 cm, bottom, pointing SE
PLA xy2 0.69466 -0.71934 0.0 0.0 0.0 40.
* Fin boundary 3 at -46 deg, z = 40 cm, top, pointing NE
PLA xy3 0.71934 0.69466 0.0 0.0 0.0 40.
* Fin boundary 4 at -44 deg, z = 40 cm, bottom, pointing SW
PLA xy4 -0.69466 -0.71934 0.0 0.0 0.0 40.
YZP yzplane 0.0
XZP xzplane 0.0
* Horn1 outer conductor outer radius
ZCC h1cyl1 0.0 0.0 23.65
* Horn1 outer conductor inner radius
ZCC h1cyl2 0.0 0.0 22.
* Horn1 start of upstream curved section
ZCC h1cyl3 0.0 0.0 8.
* Horn1 inner conductor outer radius
ZCC h1cyl4o 0.0 0.0 4.55
* Horn1 inner conductor inner radius
ZCC h1cyl4i 0.0 0.0 4.30
* Horn1 radius at start of downstream curved flare section
ZCC h1cyl5 0.0 0.0 3.35
* Horn1 water channel along first inner conductor section
ZCC w1cyl1 0.0 0.0 4.70
* Flange of upstream support cone to the left of the horn A conic conductor; outer part
TRC tcone1o 0.0 0.0 -12.49 0.0 0.0 5.97 14.35 12.96
* Flange of upstream support cone to the left of the horn A conic conductor; inner part
TRC tcone1i 0.0 0.0 -12.49 0.0 0.0 5.97 13.73 12.34
* Upper edge of upstream support cone just below the horn A conic conductor; 1 mm thick at apex; theta = 10.85 + 0.27 = 11.12 deg
TRC tcone2o 0.0 0.0 -6.52 0.0 0.0 46.52 12.96 3.80
* Lower edge of upstream support cone just below the horn A conic conductor
TRC tcone2i 0.0 0.0 -6.52 0.0 0.0 46.52 12.73 3.70
* Upstream cone connecting to inner target 1 Ti container: outer radius
TRC tcone3o 0.0 0.0 -15.5 0.0 0.0 23.5855 12.7 1.75
* Upstream cone connecting to inner target 1 Ti container: inner radius
TRC tcone3i 0.0 0.0 -15.5 0.0 0.0 23.5855 12.2 1.70
* Upstream target support cone, inner shell, outer part: Hz = 8.49 - 1.34 = 7.15 cm
TRC tcone4o 0.0 0.0 -11.75 0.0 0.0 7.75 6.6 2.9
* Upstream target support cone, inner shell, inner part, 0.8 cm thick (guesstimate)
TRC tcone4i 0.0 0.0 -11.75 0.0 0.0 7.75 5.8 2.1
* Connecting outer cone section linking upstream target support sections
TRC tcone5o 0.0 0.0 -6.52 0.0 0.0 -7.52 12.7 3.3
* Connecting inner cone section linking upstream target support sections: assume 4 mm thick
TRC tcone5i 0.0 0.0 -6.52 0.0 0.0 -7.52 12.3 2.9
* Upstream horn A inner conductor cone, outer section; same incline as target support cone with 5 mm gap; Rbase = tan(11.12 deg)*42.5 + 4.55
TRC h1cone1o 0.0 0.0 -2.5 0.0 0.0 42.5 12.90 4.55
* Upstream horn A inner conductor cone, inner section; 5 mm gap with target support cone; Rbase = tan(11.12 deg)*45 + 4.30
TRC h1cone1i 0.0 0.0 -5. 0.0 0.0 45. 13.15 4.30
* Hz = 212 - 117.5
TRC h1cone2o 0.0 0.0 116.3 0.0 0.0 95.7 4.55 3.60
* Hz = 212 - 117.5
TRC h1cone2i 0.0 0.0 116.3 0.0 0.0 95.7 4.30 3.35
* Horn1 water channel along tilted upstream conic inner conductor; Rbase = tan(11.12 deg)*42.5 + 4.7
TRC w1cone1 0.0 0.0 -2.5 0.0 0.0 42.5 13.05 4.70
* Horn1 water channel along tilted inner conductor
TRC w1cone2 0.0 0.0 116.3 0.0 0.0 95.7 4.70 3.75
* Start of Horn1 downstream (DS) curved (C) section: base must have larger radius than apex, so need negative Hz length for apex to be before base
TRC h1dsc1 0.0 0.0 216. 0.0 0.0 -4. 4.2 3.6
* Horn1 water channel along first DS curved section
TRC w1dsc1 0.0 0.0 216. 0.0 0.0 -4. 4.35 3.75
* Approximate Horn1 DS 1st 3 polygons using intersection of two cones
TRC h1dsc2o 0.0 0.0 219.5 0.0 0.0 -3.5 5. 4.2
* Approximate Horn1 DS 1st 3 polygons using intersection of two cones: z = 216.0 to 219.5
TRC h1dsc2i 0.0 0.0 219.5 0.0 0.0 -3.5 4. 3.35
* Approximate Horn1 DS 2nd 3 polygons using intersection of two cones: z = 219.5 to 222.5
TRC h1dsc3o 0.0 0.0 222.5 0.0 0.0 -3. 7.5 5.
* Approximate Horn1 DS 2nd 3 polygons using intersection of two cones: z = 219.5 to 222.5
TRC h1dsc3i 0.0 0.0 222.5 0.0 0.0 -3. 6.5 4.
* Approximate Horn1 DS 3rd polygons using intersection of two cones: z = 222.5 to 224.0
TRC h1dsc4o 0.0 0.0 224. 0.0 0.0 -1.5 9.5 7.5
* Approximate Horn1 DS 3rd polygons using intersection of two cones: z = 222.5 to 225. Bottom section is longer to better match vertical polygon
TRC h1dsc4i 0.0 0.0 225. 0.0 0.0 -2.5 9.5 6.5
* Approximate Horn1 DS 4th polygons using intersection of two cones: z = 222.5 to 225.0
TRC h1dsc5o 0.0 0.0 222.5 0.0 0.0 2.5 17.5 14.5
* Approximate Horn1 DS 4th polygons using intersection of two cones: z = 222.5 to 224.0
TRC h1dsc5i 0.0 0.0 222.5 0.0 0.0 1.5 16.5 14.5
* Approximate Horn1 DS 5th polygons using intersection of two cones: z = 219.5 to 222.5
TRC h1dsc6o 0.0 0.0 219.5 0.0 0.0 3. 20. 17.5
* Approximate Horn1 DS 5th polygons using intersection of two cones: z = 219.5 to 222.5
TRC h1dsc6i 0.0 0.0 219.5 0.0 0.0 3. 19. 16.5
* Approximate Horn1 DS 6th polygons using intersection of two cones: z = 216.0 to 219.5
TRC h1dsc7o 0.0 0.0 216. 0.0 0.0 3.5 20.5 20.
* Approximate Horn1 DS 6th polygons using intersection of two cones: z = 216.0 to 219.5
TRC h1dsc7i 0.0 0.0 216. 0.0 0.0 3.5 19.5 19.
* Target main outer container, outer section
TRC tout1o 0.0 0.0 40. 0.0 0.0 109.4 3.8 2.77
* Target main outer container, inner section; 1.0 (0.7) mm thick upstream (downstream)
TRC tout1i 0.0 0.0 40. 0.0 0.0 109.4 3.7 2.70
* Target 1 outer Ti container spherical end outer radius
SPH tsph1o 0.0 0.0 149.5 2.77
* Target 1 outer Ti container spherical end inner radius
SPH tsph1i 0.0 0.0 149.5 2.70
* Target 1 inner Ti containter tube outer radius: 0.5 mm thick
ZCC tcyl2o 0.0 0.0 1.75
* Target 1 inner Ti containter tube inner radius
ZCC tcyl2i 0.0 0.0 1.70
* Target main cylinder core
ZCC target 0.0 0.0 0.8
* Target upstream core outer cone
TRC tupendo 0.0 0.0 -4. 0.0 0.0 8. 2.9 0.8
* Target upstream core inner cone
TRC tupendi 0.0 0.0 -4. 0.0 0.0 4. 2.1 0.8
* Bafflette cone piece
TRC bafcone 0.0 0.0 -14.04 0.0 0.0 -2.5 2.9 0.8
END
* Black hole
BLKBODY 5 +blkbody -void
* Void
VOID 5 +void -outvol
* Outer volume containing the horn and target geometry
OUTVOL 15 +outvol +zm40
| +outvol -r3p3 +zm30 -zm40
| +r6p9 -r3p3 -tcone5o -zm30 +zm6p52
| +h1cyl1 +zm20 -zm30 -r12p7
| +outvol -h1cyl1 +z216 -zm30
| +h1cyl1 -zm15p5 +zm5 -r20
| +r20 -tcone1o -tcone2o -zm12p49 +zm5
| +r13p73 -r12p7 -zm20 +zm12p49
| +r12p7 -tcone3o +zm12p49 -zm15p5
| +tcone1i -tcone3o -tcone5o
| +outvol -h1cyl1 +z240 -z216
* Horn 1 Al outer conductor
H1OUT 5 +h1cyl2 -h1cone1i -zm5 +zm2p5
|+h1cyl1 -h1cyl2 +z216 -zm5
| +h1cyl2 -r19p5 +z216 -z215
* Horn 1 Al inner conductor, central cylindrical conductor volume and start of downstream curved region
H1IN 5 +h1cone1o -h1cone1i
| +h1cyl4o -h1cyl4i +z116p3 -z40
| +h1cone2o -h1cone2i
| +h1dsc1 -h1cyl5
* Horn1 Al curved downstream section
H1END 10 +h1dsc2o -h1dsc2i
| +h1dsc3o -h1dsc3i
| +h1dsc4o -h1dsc4i
| +r9p5 -h1dsc4i +z225 -z224
| +r14p5 -r9p5 +z225 -z224
| +h1dsc5o -h1dsc5i -r14p5
| +h1dsc6o -h1dsc6i
| +h1dsc7o -h1dsc7i
* Horn 1 upstream end plate
H1PLATE 5 +h1cyl1 -zm20 +zm15p5 -r13p73
* Horn1 ceramic
H1CERAM 5 +r20 -zm15p5 +zm14p09 -r13p73
* Horn1 Ar gas region: upstream and central regions
H1GAS1 5 +h1cyl2 -zm2p5 +z40 -w1cone1
| +h1cyl2 -w1cyl1 +z116p3 -z40
| +h1cyl2 -w1cone2 -z116p3 +z212
| +r19p5 -w1dsc1 +z216 -z212
| +h1cyl2 -r19p5 +z215 -z212
* Horn1 Ar gas region: downstream, outer sections
H1GAS2 5 +r5 -h1dsc2o +z219p5 -z216
| +r19 -r5 +z219p5 -z216
| +h1dsc7i -r19
| +h1dsc6i -h1dsc3o
| +h1dsc5i -h1dsc4o
* Nitrogen gas between horn inner conductor and target container (filled with He)
BEAMGAS 10 +h1cone1i -tcone2o
| +h1cyl4i -tout1o +z116p3 -z40
| +h1cone2i -tout1o +z149p4 -z116p3
| +h1cone2i -tsph1o +z157 -z149p4
| +h1cone2i -z157 +z212
| +h1cyl5 +z216 -z212
* N gas surrounding DS end of Horn 1
H1GAS3 10 +h1dsc2i
| +h1dsc3i
| +h1dsc4i
| +h1cyl1 - z225 + z240
| +h1cyl1 -h1dsc7o +z219p5 -z216
| +h1cyl1 -h1dsc6o +z222p5 -z219p5
| +h1cyl1 -h1dsc5o +z225 -z222p5
* Horn1 water cooling channels along inner conductor surface
H1COOL 5 +w1cone1 -h1cone1o
| +w1cyl1 -h1cyl4o +z116p3 -z40
| +w1cone2 -h1cone2o -z116p3 +z212
| +w1dsc1 -h1dsc1 +z216 -z212
* Target Ti flow tube between target core and its outer container
TFLOW 10 +r7p4 -r6p9 -zm30 +zm6p52 -tcone5o
| +r12p2 -r7p4 -zm30 +zm29p5
| +r12p7 -r12p2 +zm15p5 -zm30
| +tcone3o -tcone3i -tcone5o +zm6p52
| +tcone3o -tcone3i +tcone5o
| +tcone3o -tcone3i -zm6p52
| +tcyl2o -tcyl2i -z8p0855 +z150p6
* Target outer Ti container
TCONT 5 +r20 -zm14p09 +zm12p49 -r13p73
| +tcone1o -tcone1i
| +tcone5o -tcone5i +tcone1i -tcone3o
| +tcone2o -tcone2i
| +tout1o -tout1i +z150p6 -z40
* Target outer container downstream Ti beam window
TDSWIN 5 +tsph1o -tsph1i -z149p4
* Bafflet Ti container, connecting to the upstream target manifold and the graphite target joins
BAFCONT 5 +tcone4o -tcone4i +zm4 -zm6p52
| +tcone4o -tcone4i +tcone5i
| +tcone5o -tcone5i +tcone1i +zm10p76
| +tcone5o -tcone5i -tcone1i +zm12p49
| +r3p3 -r2p9 -zm40 +zm14p04
* Ti support fins connecting flow guide to outer container; ~0.5 to 1 mm thick; +-45 deg and +- 135 deg, each arc spans 2 deg (45+-1 deg)
TFINS 5 +tout1i -tcyl2o +xy1 +xy2 -z40 +z148 -xzplane
| +tout1i -tcyl2o +xy3 +xy4 -z40 +z148 -xzplane
| +tout1i -tcyl2o -xy4 -xy3 -z40 +z148 +xzplane
| +tout1i -tcyl2o -xy1 -xy2 -z40 +z148 +xzplane
* He gas inside bafflet
BAFGAS 5 +target -zm40 +zm16p54
| +bafcone
* Target He cooling gas regions
TGAS1 5 +r12p2 -r7p4 +zm15p5 -zm29p5
| +tcone3i +z0 -zm15p5 -tcone4o -r7p4 -tcone5o +zm6p52
| +tcone5o -tcone5i -zm10p76 +tcone3i
TGAS2 10 +tcone5i +tcone3i -tcone4o
| +tcone3i -tcone4o -zm6p52 +zm4
| +tcone3i -zm4 +z0 -tupendo
| +tcone4i +tcone5i
| +tcone4i -zm6p52 +zm4
| +tupendi
| +tcone3i -z0 +z8p0855 -target -tupendo
| +tcyl2i -target -z8p0855 +z150p6
| +target -z150 +z150p6
| +tcyl2o -z150p6 +tsph1i
TGAS3 10 +tcone5i +zm6p52 -tcone3o
| +tcone2i -tcone3o +z8p0855
| +tcone2i -tcyl2o -z8p0855 +z40
| +tout1i -tcyl2o -xy1 -xy3 -z40 +z148 -xzplane
| +tout1i -tcyl2o -xy2 +xy4 -z40 +z148 -yzplane
| +tout1i -tcyl2o +xy3 +xy1 -z40 +z148 +xzplane
| +tout1i -tcyl2o +xy2 -xy4 -z40 +z148 +yzplane
| +tout1i -tcyl2o -z148 +z149p4
| +tsph1i -tcyl2o -z149p4
* Target 1 core cylinder and upstream cone connection to support manifold
TARGET 5 +target +z150 -z0
| +tupendo -tupendi -target
* Upstream graphite bafflet
BAFFLE 5 +r2p9 -target -zm40 +zm16p54
| +r2p9 -bafcone -zm16p54 +zm14p04
END
GEOEND
MATERIAL 1.78 Graphite
COMPOUND -.99 CARBON -.007 NITROGEN -.003 OXYGENGraphite
MAT-PROP 31. Graphite DPA-ENER
MATERIAL 3.99 Alumina
COMPOUND 0.4 ALUMINUM 0.6 OXYGEN Alumina
MAT-PROP 31. Alumina DPA-ENER
* ..+....1....+....2....+....3....+....4....+....5....+....6....+....7..
ASSIGNMA BLCKHOLE BLKBODY
ASSIGNMA VACUUM VOID
ASSIGNMA NITROGEN OUTVOL
ASSIGNMA ALUMINUM H1OUT H1END 1.
ASSIGNMA ALUMINUM H1PLATE
ASSIGNMA Alumina H1CERAM
ASSIGNMA ARGON H1GAS1 H1GAS2 1.
ASSIGNMA NITROGEN BEAMGAS H1GAS3
ASSIGNMA WATER H1COOL 1.
ASSIGNMA TITANIUM TFLOW TFINS
ASSIGNMA HELIUM BAFGAS TGAS3
ASSIGNMA Graphite TARGET BAFFLE
* Enable the PEANUT model for hadronic interactions for all energies and main particles. Parameters set the maximum threshold KE to 1 TeV
PHYSICS 1000. 1000. 1000. 1000. 1000. 1000.PEATHRES
* Nuclei evaporation for activation studies
PHYSICS 3. EVAPORAT
* Score energy deposition (GeV) in all regions for each event separately. This is unaffected by userweig weighting
SCORE ENERGY
* Dump the regional scoring info per event to output file: can then be used to find total deposited power in each region etc.
EVENTDAT 60. evt.txt
THRESHOL 0.0 0.0 0.0
* Energy density overall: dz = 1 cm, dr = 1 mm
USRBIN 11. ENERGY -21. 25. 0.0 230.EALL
USRBIN 0.0 0.0 -40. 250. 1. 270. &
* Energy density in baffle: dz = 4 mm, dr = 2 mm, dphi = 10 degrees
USRBIN 11. ENERGY -22. 3.4 0.0 -14.EBAF
USRBIN 0.0 0.0 -40. 17. 36. 65. &
* Energy density in upstream upper manifold, z = -30 to -4 cm, r = 6.5 to 14.5 cm, dz = 4 mm, dr = 2 mm, dphi = 30 degrees
USRBIN 11. ENERGY -23. 14.5 0.0 -4.EMAN1
USRBIN 6.5 0.0 -30. 40. 12. 65. &
* Energy density in upstream lower manifold, z = -16 to -4 cm, r = 2 to 8 cm, dz = 4 mm, dr = 2 mm, dphi = 30 degrees
USRBIN 11. ENERGY -24. 8.0 0.0 -4.EMAN2
USRBIN 2.0 0.0 -16. 30. 12. 30. &
* Energy density in upper container & ceramic interface with horn plate, z = -20 to -12 cm, r = 13.6 to 24 cm, dz = 4 mm, dr = 4 mm, dphi = 30 degrees
USRBIN 11. ENERGY -25. 24. 0.0 -12.EMAN3
USRBIN 13.6 0.0 -20. 26. 12. 20. &
* Energy density in upstream target core, z = -4 to 4 cm, r = 0 to 3 cm: dz = 2 mm, dr = 1 mm, dphi = 10 degrees
USRBIN 11. ENERGY -26. 3. 0.0 4.ETARG1
USRBIN 0.0 0.0 -4. 30. 36. 40. &
* Energy density in main target core, z = 4 cm to 152 cm, r = 0 to 0.8 cm: dz = 4 cm, dr = 1 mm, dphi = 10 degrees
USRBIN 11. ENERGY -27. 0.8 0.0 152.ETARG2
USRBIN 0.0 0.0 4. 8. 36. 37. &
* Energy density in flow guide cone 1st part: z = -16 to -4 cm, r = 7.0 to 13 cm, dz = 2 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -28. 13. 0.0 -4.EFLOW1
USRBIN 7. 0.0 -16. 60. 12. 60. &
* Energy density in flow guide cone 2nd part: z = -4 to 8.6 cm, r = 1.5 to 7.5 cm, dz = 2 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -29. 7.5 0.0 8.6EFLOW2
USRBIN 1.5 0.0 -4. 60. 12. 63. &
* Energy density in flow guide long 3rd part: z = 8 to 152 cm, r = 1.70 to 1.75 cm, dz = 4 cm, dr = 0.1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -30. 1.75 0.0 152.EFLOW3
USRBIN 1.70 0.0 8. 5. 12. 36. &
* Energy density in container cone 1st part: z = -13.2 to 0 cm, r = 11 to 14.5 cm, dz = 4 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -31. 14.5 0.0 0.0ECONT1
USRBIN 11. 0.0 -13.2 35. 12. 33. &
* Energy density in container cone 2nd part: z = 0 to 20 cm, r = 7 to 12 cm, dz = 4 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -32. 12. 0.0 20.ECONT2
USRBIN 7. 0.0 0.0 50. 12. 50. &
* Energy density in container cone 3rd part: z = 20 to 40 cm, r = 3.5 to 8 cm, dz = 4 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -33. 8. 0.0 40.ECONT3
USRBIN 3.5 0.0 20. 45. 12. 50. &
* Energy density in container cone 4th part: z = 40 to 152 cm, r = 2.5 to 4.0 cm, dz = 4 cm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -34. 4. 0.0 152.ECONT4
USRBIN 2.5 0.0 40. 15. 12. 28. &
* Energy density in downstream target beam window, dz = 0.5 mm, dr = 0.5 mm, dphi = 30 degrees
USRBIN 11. ENERGY -35. 3. 0.0 152.5EDSWIN
USRBIN 0.0 0.0 149. 60. 12. 70. &
* Energy density in horn 1 inner/outer conductor upstream vertical section: z = -5.1 to -2.5 cm, r = 12.4 to 24 cm, dz = 2 mm, dr = 4 mm, dphi = 30 degrees
USRBIN 11. ENERGY -40. 24. 0.0 -2.5EH1UPV
USRBIN 12.4 0.0 -5.1 29. 12. 13. &
* Energy density in horn 1 upstream inner conductor cone 1st part: z = -5.2 to 20 cm, r = 8 to 13.5 cm, dz = 4 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -41. 13.5 0.0 20.EH1CON1
USRBIN 8. 0.0 -5.2 55. 12. 63. &
* Energy density in horn 1 upstream inner conductor cone 2nd part: z = 20 to 40 cm, r = 4 to 9 cm, dz = 4 mm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -42. 9. 0.0 40.EH1CON2
USRBIN 4. 0.0 20. 50. 12. 50. &
* Energy density in horn 1 cylindrical and downstream inner conductor: z = 40 to 216 cm, r = 3.2 to 4.8 cm, dz = 4 cm, dr = 0.5 mm, dphi = 30 degrees
USRBIN 11. ENERGY -43. 4.8 0.0 216.EH1IN
USRBIN 3.2 0.0 40. 32. 12. 44. &
* Energy density in horn 1 downstream endcap: z = 210 to 226 cm, r = 2.9 to 20.5 cm, dz = 4 mm, dr = 4 mm, dphi = 30 degrees
USRBIN 11. ENERGY -44. 20.5 0.0 226.EH1END
USRBIN 2.9 0.0 210. 44. 12. 40. &
* Energy density in horn 1 outer conductor: z = -6 to 218 cm, r = 22 to 23 cm, dz = 4 cm, dr = 1 mm, dphi = 30 degrees
USRBIN 11. ENERGY -45. 23. 0.0 218.EH1OUT
USRBIN 22. 0.0 -6.0 10. 12. 56. &
* Energy density in solid support fins (flow guide to container); z = 40 cm to 76 cm, dz = 1 cm, dr = 0.5 mm, dPhi = 2 degrees
USRBIN 11. ENERGY -50. 3.8 0.0 76.EFINS1
USRBIN 1.7 0.0 40. 42. 180. 36. &
* Energy density in solid support fins (flow guide to container); z = 76 cm to 112 cm, dz = 1 cm, dr = 0.5 mm, dPhi = 2 degrees
USRBIN 11. ENERGY -51. 3.8 0.0 112.EFINS2
USRBIN 1.7 0.0 76. 42. 180. 36. &
* Energy density in solid support fins (flow guide to container); z = 112 cm to 148 cm, dz = 1 cm, dr = 0.5 mm, dPhi = 2 degrees
USRBIN 11. ENERGY -52. 3.8 0.0 148.EFINS3
USRBIN 1.7 0.0 112. 42. 180. 36. &
* Store radionuclides in all volume regions in binary format which can be processed with flutil/usrsuwev
RESNUCLE 3. -61. H1OUT RNH1OUT
RESNUCLE 3. -62. H1IN RNH1IN
RESNUCLE 3. -63. H1END RNH1END
RESNUCLE 3. -64. H1PLATE RNH1PL
RESNUCLE 3. -65. H1CERAM RNH1CER
RESNUCLE 3. -66. H1GAS1 RNH1GAS1
RESNUCLE 3. -67. H1GAS2 RNH1GAS2
RESNUCLE 3. -68. BEAMGAS RNBEAMG
RESNUCLE 3. -69. H1GAS3 RNH1GAS3
RESNUCLE 3. -70. H1COOL RNH1COOL
RESNUCLE 3. -71. TFLOW RNTFLOW
RESNUCLE 3. -72. TCONT RNTCONT
RESNUCLE 3. -73. TDSWIN RNTWIN
RESNUCLE 3. -74. BAFCONT RNBAFCON
RESNUCLE 3. -75. BAFGAS RNBAFGAS
RESNUCLE 3. -76. TGAS1 RNTGAS1
RESNUCLE 3. -77. TGAS2 RNTGAS2
RESNUCLE 3. -78. TGAS3 RNTGAS3
RESNUCLE 3. -79. TARGET RNTARGET
RESNUCLE 3. -80. BAFFLE RNBAFFLE
RESNUCLE 3. -81. TFINS RNTFINS
* Set the random number seed
RANDOMIZ 1. 1.
* Set the number of primary histories to be simulated in the run; 10,000
START 100.
STOP