This release of SCALE is unsupported. Please click here for the current production release.
SCALE 6.1.1 Updates
CENTRM (Updated in SCALE 6.1.1, May 23, 2012)
CENTRM was updated to correct an issue that can lead to non-conservative keff values when using the 44-group ENDF/B-V data with CENTRM for high-leakage models with trace-element number densities below ~10‑9 atoms/barn-cm when running SCALE 5.1–SCALE 6.1. The effect on the 238-group ENDF/B-V, VI, and VII libraries is minimal. There is no effect on continuous-energy Monte Carlo calculations.
In the dozens of test cases examined thus far, the discrepancy appears only in cases that meet ALL of the following conditions.
- Calculations are performed with SCALE 5.1, 6.0 or 6.1.
- The number density of at least one nuclide has a small fractional concentration of 10-8 or less relative to the total mixture number density. Typically this corresponds to an absolute concentration less than ~10-9 to 10-10 atoms/barn-cm, but greater than zero.
- The SCALE 44-group ENDF/B-V library or a user-generated broad group library with few groups in the U-238 resolved resonance range (1 eV-4 KeV) is used.
- CENTRM is used for resonance self-shielding. This is the default behavior in SCALE 6.1, but NITAWL processing is the default behavior for SCALE 5.1 and 6.0 for the ENDF/B-V cross-section data, so the user must explicitly request CENTRM processing to observe the discrepancy with SCALE 5.1 or 6.0.
- The system is sensitive to the high-energy portion of the resolved range, which most commonly occurs for high-leakage systems. Low-leakage criticality and depletion models examined realized only a minimal impact.
Impact of CENTRM error on computed results:
- Continuous-energy KENO calculations do not use CENTRM and are not affected.
- The impact for all 238-group calculations examined thus far is small, on the order of a few pcm.
- Eigenvalues and isotopic concentrations computed for the 44-group ENDF/B-V depletion cases examined are not significantly affected, because these are low-leakage systems [reflected lattice geometries]. For most cases that meet all of the above criteria, including burned fuel criticality safety calculations that include small concentrations of fission products, the discrepancy introduces an error on the order of 100 pcm.
In a contrived case that artificially introduces a trace material into a plutonium nitrate system, a discrepancy of ~3% delta-k between the SCALE 6.1 and corrected SCALE 6.1.1 result has been observed. However, the SCALE development team has not observed an experimental benchmark or operational safety-related problem that exhibits an error on the order of this contrived numerical case.
After applying the patch, users should repeat any calculations where this discrepancy could affect results.
Lattice Physics Enhancements (Updated in SCALE 6.1.1, May 23, 2012)
Several minor updates for lattice physics calculations have been included for TRITON and NEWT. Users will realize improved performance where these specific features are utilized. The following issues have been resolved.
- Homogenization of kinetic parameters in NEWT: The delayed neutron fraction, beta, is currently homogenized by forward fission weighting. In this formulation, beta should be weighted by the nu-fission reaction rate. The current coding uses the fission reaction rate (i.e., without the nu). Users should expect differences in the homogenized values of kinetic parameters, which will impact subsequent transient analysis.
- TRITON TRACE Block: An issue was identified using the TRACE block in TRITON. The TRACE block now supports any nuclide in the ORIGEN light-element library. Previously in SCALE 6.1, only trace amounts of nuclides from the AMPX cross-section library could be added to depletion materials. The ORIGEN light-element library contains more nuclides than are available in the AMPX cross-section library.
- Depletion File ft71f001 Index Listing: TRITON provides an output edit for a table of contents of the data in the ORIGEN nuclide inventory file (i.e., ft71f001). This file can be used in follow-on ORIGEN-ARP and OPUS analyses. It was identified that the record numbers were not properly displayed for the two cumulative datasets (system-sum of materials and selected-sum of materials). This edit was corrected.
- KENO Depletion Message: TRITON increases the user-defined KENO parameters NSK and GEN for depletion analysis. A message was added to the TRITON output to notify users of the modified values.
- NEWT ARRAY block: Two issues were addressed for the NEWT ARRAY block. An error message was added in the case where an array is used in the model geometry without being defined in the ARRAY block. Second, a code bug was removed so that the model geometry may include multiple placements of the same array definition.
- CENTRM Cross-section processing defaults: TRITON supports several sets of CENTRM cross-section processing defaults: parm=2region, parm=centrm, and parm=(xslevel=1/2/3/or 4). An error was identified in depletion calculations if the user supplied parm=centrm. In this case, TRITON continued to use the depletion default set, which has been slightly modified to decrease run-time without significantly impacting depletion analysis. This error was resolved in this patch. For depletion calculations (i.e. =t-depl, =³Ù-»å±ð±è±ô‑1»å, =t5-depl, =t6-depl) that use parm=centrm, users can expect a small deviation (~50 pcm change in multiplication factor as a function of burnup) and slightly longer run-times for depletion models that utilize the parm=centrm option when using the SCALE 6.1.1 update.
MAVRIC/Monaco Enhancements (Updated in SCALE 6.1.1, May 23, 2012)
A few minor issues were identified with the SCALE fixed-source Monte Carlo code Monaco and an associated utility, especially related to seldom-used optional features. Users should review any results produced with these features using SCALE 6.1.
- When specifying the special distribution pwrNeutronAxialProfileReverse or pwrGammaAxialProfileReverse for a spatial source distribution, the un-reversed profile was erroneously returned.
- The sum of the point detector group-wise results may be higher than the point detector energy-integrated (total) results. The reported total is correct. The group-wise values are high due to rejecting negative contributions (which happen a small fraction of the time due to the multigroup energy/angle physics).
- If a source specification utilizes different Watt spectra distributions in multiple sources, the energies sampled for one source may include energies from the wrong distribution.
- The utility program mim2wwinp does not format MCNP *.wwinp files correctly for photon-only problems. MCNP interprets a *.wwinp with only one particle listed as neutrons, even in a "mode p" problem. The *.wwinp file produced by SCALE needs to specifically identify that there are 0 neutron groups for photon-only problems.
ORIGEN Data Enhancements (Updated in SCALE 6.1.1, May 23, 2012)
Three issues are corrected within the ORIGEN depletion and decay libraries.
- origen.rev03.jeff200g – The energy group boundaries of the 200-group JEFF-based ORIGEN library were inadvertently generated using constant lethargy boundaries instead of the boundaries of the SCALE 200-neutron and 47-gamma group cross section libraries. The library was regenerated to include the corrected boundaries. No other changes were made. All calculations performed with the previous version of the jeff200g library should be discarded and repeated with the current library.
- The fission product yield library used by COUPLE was modified to include ternary yields of H-3, He-3, and He-4 based on data from the JEF-2.2 fission yield library. In the previous library these fission products are only generated as by-products of neutron reactions other than fission, and not directly from fission. Cumulative yields are applied for H-3 and He-4, and direct yields are used for He-3 since it is a decay product of H-3. Direct yields for He-3 are zero for all fission nuclides.
- The ORIGEN decay libraries were updated to provide correct natural abundances of several elements. Previously, the use of natural isotopic abundances (NEX1=4) for input element concentrations entered in gram units may have resulted in incorrect isotopic concentrations for Mg, Ge, Kr, Sr, and Te. If atom units (gram atoms) were used, incorrect isotopic concentrations may have occurred for F, Na, Mg, Al, P, Sc, Mn, Co, Ge, As, Kr, Sr, Y, Nb, Rh, Te, I, Cs, Pr, Tb, Ho, Tm, and Au. The libraries origen.rev02.decay.data and origen.rev02.end7dec were updated.
KENO-VI Hexagonally-Pitched Arrays (Updated in SCALE 6.1.1, May 23, 2012)
KENO-VI was updated to correct an issue that occasionally caused a calculation to fail when tracking in a hexagonally-pitched array. Previous calculations that encountered this error failed, and the results of other calculations are not affected.
Other Enhancements (Updated in SCALE 6.1.1, May 23, 2012)
The SCALE 6.1 distribution included some sample problem output data that were generated with a prerelease version of SCALE and were not consistent with those produced by the final release of SCALE 6.1. Additionally, some of the sample problems were verified using output that included timing information, such as Figure of Merit data from Monte Carlo calculations. This update provides revised .out and .table files for all sample problems, updates in the XML files that drive the sample problems, corrections in platform-specific information in three Windows sample problem inputs, and provides an updated differencing tool that is used for comparing sample problem outputs.
Additionally, KENO3D and OrigenArp example files that are referenced in some publications but were not included in SCALE 6.1 are also installed with this update, and an updated version of GeeWiz is provided to correct minor issues.
Files
The following files will be installed, regardless of platform
./scale6.1:
CMakeTPL.txt Windows_x86
CopyBack.xml cmake
Darwin cmds
GeeWiz data
Keno3d output
Linux_i686 samples-windows_x86.xml
Linux_x86_64 samples.xml
OrigenArp script
ScaleRunResources.xml smplprbs
Windows_amd64 src
./scale6.1/Darwin:
bin data
./scale6.1/Darwin/bin:
bonamist mavric origen triton
cajun mim2wwinp reorg triton6
centrm monaco sams5
couple newt sams6
kenovi newt-omp scale
./scale6.1/Darwin/data:
qatable
./scale6.1/GeeWiz:
GeeWiz.exe GeeWizHelp.chm
./scale6.1/Keno3d:
Examples keno3d.exe
./scale6.1/Keno3d/Examples:
Asmile.inp cross.inp
Cube0.inp cruciform_cyls.inp
Ga4-TruckCask.inp cube_ecyl.inp
HOLE4.INP cubecyl1.inp
HOLE5.INP grotesque2.inp
HopperWithChords.inp hemicyls_nested.inp
KENO10.INP saxton792.inp
KENO12.INP sheba-detail-k6.inp
KENO2.INP sheba-detail-k6.kmt
Sphere8Cut.inp sheba.inp
annular_hex_array.inp sheba.kmt
array7.inp sheba.out
container2.inp y_30degree.inp
container2_6x6.inp
./scale6.1/Linux_i686:
bin data
./scale6.1/Linux_i686/bin:
bonamist mavric origen triton
cajun mim2wwinp reorg triton6
centrm monaco sams5
couple newt sams6
kenovi newt-omp scale
./scale6.1/Linux_i686/data:
qatable
./scale6.1/Linux_x86_64:
bin data
./scale6.1/Linux_x86_64/bin:
bonamist mavric origen scale
cajun mim2wwinp reorg triton
centrm monaco runner triton6
couple newt sams5
kenovi newt-omp sams6
./scale6.1/Linux_x86_64/data:
qatable
./scale6.1/OrigenArp:
Examples
./scale6.1/OrigenArp/Examples:
Balakova2-15.arp bm1.arp
Demonstration.arp bm1.mox
Magnox-a.arp oecd-ivb.arp
UO2ExpressDemo1.arp oecd-ivb.mox
UO2ExpressDemo1.uo2 vv440.arp
agr-20.arp
./scale6.1/Windows_amd64:
bin data
./scale6.1/Windows_amd64/bin:
bonamist.exe mavric.exe o rigen.exe triton.exe
cajun.exe mim2wwinp.exe reorg.exe triton6.exe
centrm.exe monaco.exe sams5.exe
couple.exe newt-omp.exe sams6.exe
kenovi.exe newt.exe scale.exe
./scale6.1/Windows_amd64/data:
qatable
./scale6.1/Windows_x86:
bin data
./scale6.1/Windows_x86/bin:
bonamist.exe mavric.exe o rigen.exe triton.exe
cajun.exe mim2wwinp.exe reorg.exe triton6.exe
centrm.exe monaco.exe sams5.exe
couple.exe newt-omp.exe sams6.exe
kenovi.exe newt.exe scale.exe
./scale6.1/Windows_x86/data:
qatable
./scale6.1/cmake:
IntelCXXFlags.cmake IntelFortranFlags.cmake
./scale6.1/cmds:
cpexec lib
./scale6.1/cmds/lib:
JavaDiff.jar
./scale6.1/data:
aliases origen.rev04.maphnobr
origen.rev03.end7dec origen.rev04.maphuo2b
origen.rev03.jeff200g origen_data
origen.rev04.maphh2ob scale.messages
./scale6.1/data/origen_data:
origen.rev03.decay.data origen.rev04.mpdkxgam.data
origen.rev03.yields.data
./scale6.1/output:
Nix k6smp07.out
Windows k6smp08.out
arp.out k6smp09.out
arplib-reorg.out k6smp10.out
bonami.out k6smp11.out
c5toc6.out k6smp12.out
caas.kenovi.out k6smp13.out
caas.mavricA.out k6smp14.out
caas.mavricB.out k6smp15.out
cecsas5_1.out k6smp16.out
cecsas5_2.out k6smp17.out
cecsas5_4.out k6smp18.out
cecsas5_5.out k6smp19.out
cecsas5_6.out k6smp20.out
cecsas6_1.out k6smp21.out
cecsas6_2.out k6smp22.out
cecsas6_3.out k6smp23.out
cecsas6_4.out k6smp24.out
cecsas6_5.out k6smp25.out
cecsas6_6.out k6smp26.out
cecsas6_7.out k6smp27.out
cecsas6_8.out kenova.out
cek5smp01.out kenovi.out
cek5smp02.out kmart5.out
cek5smp03.out kmart6.out
cek5smp04.out mavric.caskAnalogn.out
cek5smp06.out mavric.caskAnalogp.out
cek5smp07.out mavric.caskCADISn.out
cek5smp08.out mavric.caskCADISp.out
cek5smp09.out mavric.graphiteCADIS.out
cek5smp10.out mavric.isfsi.out
cek5smp11.out mavric.lithoFW.out
cek5smp12.out mavric.tn24p.out
cek5smp13.out mavricUtilities1.out
cek5smp14.out mavricUtilities2.out
cek5smp15.out mavricUtilities3.out
cek5smp16.out mcdancoff.out
cek5smp18.out monaco.d2oSphereA.out
cek5smp19.out monaco.d2oSphereB.out
cek5smp20.out monaco.graphite.out
cek5smp21.out monaco.howitzer.out
cek5smp22.out monaco.ironSphere.out
cek5smp23.out newt1.out
cek5smp24.out newt2.out
cek5smp25.out newt3.out
cek5smp26.out newt4.out
cek5smp27.out newt5.out
cek5smp28.out nitawl.out
cek5smp29.out opus.out
cek5smp30.out origen.out
cek5smp31.out picture.out
cek5smp32.out prism.out
cek5smp33.out qadcggp.out
cek6smp01.out qads.out
cek6smp02.out sas1a.out
cek6smp03.out sas1b.out
cek6smp04.out sas1c.out
cek6smp06.out sas1d.out
cek6smp07.out sas1e.out
cek6smp08.out sas1f.out
cek6smp09.out sas1g.out
cek6smp10.out sas1h.out
cek6smp11.out smores_evref.out
cek6smp12.out smores_maxk.out
cek6smp13.out smores_minmas.out
cek6smp14.out starbucs1.out
cek6smp15.out starbucs2.out
cek6smp16.out starbucs3.out
cek6smp18.out starbucs4.out
cek6smp19.out starbucs5.out
cek6smp20.out starbucs6.out
cek6smp21.out toc.out
cek6smp22.out triton1.out
cek6smp23.out triton10.out
cek6smp24.out triton11.out
cek6smp25.out triton12.out
cek6smp26.out triton12.sdf
cek6smp27.out triton2.out
cekenova.out triton3.out
cekenovi.out triton4.out
centrm-activity.out triton5.out
centrm-boundary.out triton6-1.out
centrm-dancoff.out triton6.out
centrm-double_het.out triton7.out
centrm-libraries.out triton8.out
centrm-options.out triton9.out
centrm-pwr.out triton9.sdf
centrm-thermal.out triton9.u235-abs.sdf
centrm-transport.out triton9.u235-fis.sdf
couple.out triton9.u238-abs.sdf
csas5_1.out triton9.u238-fis.sdf
csas5_2.out tsar-1.0002.react.sdf
csas5_3.out tsar-1.kstate1.sdf
csas5_4.out tsar-1.kstate2.sdf
csas5_5.out tsar-1.out
csas5_6.out tsar-1.react.sdf
csas5_7.out tsar-1d_1.sdf
csas5_8.out tsar-1d_2.sdf
csas6_1.out tsar-2.0002.react.sdf
csas6_2.out tsar-2.kstate1.sdf
csas6_3.out tsar-2.kstate2.sdf
csas6_4.out tsar-2.out
csas6_5.out tsar-2.react.sdf
csas6_6.out tsunami-1d1.out
csas6_7.out tsunami-1d1.sdf
csas6_8.out tsunami-1d2.out
ice.out tsunami-1d2.sdf
k5smp01.out tsunami-1d3.out
k5smp02.out tsunami-1d3.sdf
k5smp03.out tsunami-1d4.out
k5smp04.out tsunami-1d4.sdf
k5smp05.out tsunami-1d5.out
k5smp06.out tsunami-1d5.sdf
k5smp07.out tsunami-1d6.out
k5smp08.out tsunami-1d6.sdf
k5smp09.out tsunami-1d7.out
k5smp10.out tsunami-1d7.sdf
k5smp11.out tsunami-1d8.out
k5smp12.out tsunami-1d9.U234-abs.sdf
k5smp13.out tsunami-1d9.U234-fis.sdf
k5smp14.out tsunami-1d9.U235-abs.sdf
k5smp15.out tsunami-1d9.U235-fis.sdf
k5smp16.out tsunami-1d9.U238-abs.sdf
k5smp17.out tsunami-1d9.U238-fis.sdf
k5smp18.out tsunami-1d9.out
k5smp19.out tsunami-1d9.sdf
k5smp20.out tsunami-3d-summary.out
k5smp21.out tsunami-3d_k5-1.out
k5smp22.out tsunami-3d_k5-1.sdf
k5smp23.out tsunami-3d_k5-2.out
k5smp24.out tsunami-3d_k5-2.sdf
k5smp25.out tsunami-3d_k5-3.out
k5smp26.out tsunami-3d_k5-3.sdf
k5smp27.out tsunami-3d_k5-4.out
k5smp28.out tsunami-3d_k5-4.sdf
k5smp29.out tsunami-3d_k6-1.out
k5smp30.out tsunami-3d_k6-1.sdf
k5smp31.out tsunami-3d_k6-2.out
k5smp32.out tsunami-3d_k6-2.sdf
k5smp33.out tsunami-ip.out
k6smp01.out tsunami-ip.sdf
k6smp02.out tsurfer.out
k6smp03.out util.out
k6smp04.out xsdose.out
k6smp05.out xsdrn.out
k6smp06.out xseclist.out
./scale6.1/output/Nix:
arp.table k5smp22.table
arplib-reorg.table k5smp23.table
bonami.table k5smp24.table
c5toc6.table k5smp25.table
caas.kenovi.table k5smp26.table
caas.mavricA.table k5smp27.table
caas.mavricB.table k5smp28.table
cecsas5_1.table k5smp29.table
cecsas5_2.table k5smp30.table
cecsas5_4.table k5smp31.table
cecsas5_5.table k5smp32.table
cecsas5_6.table k5smp33.table
cecsas6_1.table k6smp01.table
cecsas6_2.table k6smp02.table
cecsas6_3.table k6smp03.table
cecsas6_4.table k6smp04.table
cecsas6_5.table k6smp05.table
cecsas6_6.table k6smp06.table
cecsas6_7.table k6smp07.table
cecsas6_8.table k6smp08.table
cek5smp01.table k6smp09.table
cek5smp02.table k6smp10.table
cek5smp03.table k6smp11.table
cek5smp04.table k6smp12.table
cek5smp06.table k6smp13.table
cek5smp07.table k6smp14.table
cek5smp08.table k6smp15.table
cek5smp09.table k6smp16.table
cek5smp10.table k6smp17.table
cek5smp11.table k6smp18.table
cek5smp12.table k6smp19.table
cek5smp13.table k6smp20.table
cek5smp14.table k6smp21.table
cek5smp15.table k6smp22.table
cek5smp16.table k6smp23.table
cek5smp18.table k6smp24.table
cek5smp19.table k6smp25.table
cek5smp20.table k6smp26.table
cek5smp21.table k6smp27.table
cek5smp22.table kenova.table
cek5smp23.table kenovi.table
cek5smp24.table kmart5.table
cek5smp25.table kmart6.table
cek5smp26.table mavric.caskAnalogn.table
cek5smp27.table mavric.caskAnalogp.table
cek5smp28.table mavric.caskCADISn.table
cek5smp29.table mavric.caskCADISp.table
cek5smp30.table mavric.graphiteCADIS.table
cek5smp31.table mavric.isfsi.table
cek5smp32.table mavric.lithoFW.table
cek5smp33.table mavric.tn24p.table
cek6smp01.table mavricUtilities1.table
cek6smp02.table mavricUtilities2.table
cek6smp03.table mavricUtilities3.table
cek6smp04.table mcdancoff.table
cek6smp06.table monaco.d2oSphereA.table
cek6smp07.table monaco.d2oSphereB.table
cek6smp08.table monaco.graphite.table
cek6smp09.table monaco.howitzer.table
cek6smp10.table monaco.ironSphere.table
cek6smp11.table newt1.table
cek6smp12.table newt2.table
cek6smp13.table newt3.table
cek6smp14.table newt4.table
cek6smp15.table newt5.table
cek6smp16.table nitawl.table
cek6smp18.table opus.table
cek6smp19.table origen.table
cek6smp20.table picture.table
cek6smp21.table qadcggp.table
cek6smp22.table qads.table
cek6smp23.table sas1a.table
cek6smp24.table sas1b.table
cek6smp25.table sas1c.table
cek6smp26.table sas1d.table
cek6smp27.table sas1e.table
cekenova.table sas1f.table
cekenovi.table sas1g.table
centrm-activity.table sas1h.table
centrm-boundary.table smores_evref.table
centrm-dancoff.table smores_maxk.table
centrm-double_het.table smores_minmas.table
centrm-libraries.table starbucs1.table
centrm-options.table starbucs2.table
centrm-pwr.table starbucs3.table
centrm-thermal.table starbucs4.table
centrm-transport.table starbucs5.table
couple.table starbucs6.table
csas5_1.table toc.table
csas5_2.table triton1.table
csas5_3.table triton10.table
csas5_4.table triton11.table
csas5_5.table triton12.table
csas5_6.table triton2.table
csas5_7.table triton3.table
csas5_8.table triton4.table
csas6_1.table triton5.table
csas6_2.table triton6-1.table
csas6_3.table triton6.table
csas6_4.table triton7.table
csas6_5.table triton8.table
csas6_6.table triton9.table
csas6_7.table tsar-1.table
csas6_8.table tsar-2.table
ice.table tsunami-1d1.table
k5smp01.table tsunami-1d2.table
k5smp02.table tsunami-1d3.table
k5smp03.table tsunami-1d4.table
k5smp04.table tsunami-1d5.table
k5smp05.table tsunami-1d6.table
k5smp06.table tsunami-1d7.table
k5smp07.table tsunami-1d8.table
k5smp08.table tsunami-1d9.table
k5smp09.table tsunami-3d-summary.table
k5smp10.table tsunami-3d_k5-1.table
k5smp11.table tsunami-3d_k5-2.table
k5smp12.table tsunami-3d_k5-3.table
k5smp13.table tsunami-3d_k5-4.table
k5smp14.table tsunami-3d_k6-1.table
k5smp15.table tsunami-3d_k6-2.table
k5smp16.table tsunami-ip.table
k5smp17.table tsurfer.table
k5smp18.table util.table
k5smp19.table xsdose.table
k5smp20.table xsdrn.table
k5smp21.table xseclist.table
./scale6.1/output/Windows:
arp.table k5smp22.table
arplib-reorg.table k5smp23.table
bonami.table k5smp24.table
c5toc6.table k5smp25.table
caas.kenovi.table k5smp26.table
caas.mavricA.table k5smp27.table
caas.mavricB.table k5smp28.table
cecsas5_1.table k5smp29.table
cecsas5_2.table k5smp30.table
cecsas5_4.table k5smp31.table
cecsas5_5.table k5smp32.table
cecsas5_6.table k5smp33.table
cecsas6_1.table k6smp01.table
cecsas6_2.table k6smp02.table
cecsas6_3.table k6smp03.table
cecsas6_4.table k6smp04.table
cecsas6_5.table k6smp05.table
cecsas6_6.table k6smp06.table
cecsas6_7.table k6smp07.table
cecsas6_8.table k6smp08.table
cek5smp01.table k6smp09.table
cek5smp02.table k6smp10.table
cek5smp03.table k6smp11.table
cek5smp04.table k6smp12.table
cek5smp06.table k6smp13.table
cek5smp07.table k6smp14.table
cek5smp08.table k6smp15.table
cek5smp09.table k6smp16.table
cek5smp10.table k6smp17.table
cek5smp11.table k6smp18.table
cek5smp12.table k6smp19.table
cek5smp13.table k6smp20.table
cek5smp14.table k6smp21.table
cek5smp15.table k6smp22.table
cek5smp16.table k6smp23.table
cek5smp18.table k6smp24.table
cek5smp19.table k6smp25.table
cek5smp20.table k6smp26.table
cek5smp21.table k6smp27.table
cek5smp22.table kenova.table
cek5smp23.table kenovi.table
cek5smp24.table kmart5.table
cek5smp25.table kmart6.table
cek5smp26.table mavric.caskAnalogn.table
cek5smp27.table mavric.caskAnalogp.table
cek5smp28.table mavric.caskCADISn.table
cek5smp29.table mavric.caskCADISp.table
cek5smp30.table mavric.graphiteCADIS.table
cek5smp31.table mavric.isfsi.table
cek5smp32.table mavric.lithoFW.table
cek5smp33.table mavric.tn24p.table
cek6smp01.table mavricUtilities1.table
cek6smp02.table mavricUtilities2.table
cek6smp03.table mavricUtilities3.table
cek6smp04.table mcdancoff.table
cek6smp06.table monaco.d2oSphereA.table
cek6smp07.table monaco.d2oSphereB.table
cek6smp08.table monaco.graphite.table
cek6smp09.table monaco.howitzer.table
cek6smp10.table monaco.ironSphere.table
cek6smp11.table newt1.table
cek6smp12.table newt2.table
cek6smp13.table newt3.table
cek6smp14.table newt4.table
cek6smp15.table newt5.table
cek6smp16.table nitawl.table
cek6smp18.table opus.table
cek6smp19.table origen.table
cek6smp20.table picture.table
cek6smp21.table qadcggp.table
cek6smp22.table qads.table
cek6smp23.table sas1a.table
cek6smp24.table sas1b.table
cek6smp25.table sas1c.table
cek6smp26.table sas1d.table
cek6smp27.table sas1e.table
cekenova.table sas1f.table
cekenovi.table sas1g.table
centrm-activity.table sas1h.table
centrm-boundary.table smores_evref.table
centrm-dancoff.table smores_maxk.table
centrm-double_het.table smores_minmas.table
centrm-libraries.table starbucs1.table
centrm-options.table starbucs2.table
centrm-pwr.table starbucs3.table
centrm-thermal.table starbucs4.table
centrm-transport.table starbucs5.table
couple.table starbucs6.table
csas5_1.table toc.table
csas5_2.table triton1.table
csas5_3.table triton10.table
csas5_4.table triton11.table
csas5_5.table triton12.table
csas5_6.table triton2.table
csas5_7.table triton3.table
csas5_8.table triton4.table
csas6_1.table triton5.table
csas6_2.table triton6-1.table
csas6_3.table triton6.table
csas6_4.table triton7.table
csas6_5.table triton8.table
csas6_6.table triton9.table
csas6_7.table tsar-1.table
csas6_8.table tsar-2.table
ice.table tsunami-1d1.table
k5smp01.table tsunami-1d2.table
k5smp02.table tsunami-1d3.table
k5smp03.table tsunami-1d4.table
k5smp04.table tsunami-1d5.table
k5smp05.table tsunami-1d6.table
k5smp06.table tsunami-1d7.table
k5smp07.table tsunami-1d8.table
k5smp08.table tsunami-1d9.table
k5smp09.table tsunami-3d-summary.table
k5smp10.table tsunami-3d_k5-1.table
k5smp11.table tsunami-3d_k5-2.table
k5smp12.table tsunami-3d_k5-3.table
k5smp13.table tsunami-3d_k5-4.table
k5smp14.table tsunami-3d_k6-1.table
k5smp15.table tsunami-3d_k6-2.table
k5smp16.table tsunami-ip.table
k5smp17.table tsurfer.table
k5smp18.table util.table
k5smp19.table xsdose.table
k5smp20.table xsdrn.table
k5smp21.table xseclist.table
./scale6.1/script:
linux_x86_64-cmake_MPI
./scale6.1/smplprbs:
Nix Windows
./scale6.1/smplprbs/Nix:
cooper_bwr.inp
./scale6.1/smplprbs/Windows:
cooper_bwr.inp origen.input triton6-1.input
opus.input toc.input
./scale6.1/src:
CMakeLists.txt couple mavricUtilities runner
DataComm dbcf miplib samslib
basicGeom defBlock monaco scalelib
bonamist driver newt triton
cajun jDebug origen tritonlib
centrm kenovi reorg
./scale6.1/src/DataComm:
AllocateArrays_M.f90 MPI_FC.f90
AllocatePointers.f90 PTimer.cpp
CMakeLists.txt PTimer.h
Constants.f90 Ppanalysis.cpp
DataBuffer_M.f90 Ppanalysis.h
DataCommIO_M.f90 TimerClass_M.f90
DataComm_config.h.in Tribits
DataPackUnpack_M.f90 getTimeofDay.cpp
Data_Types.f90 getTimeofDay.h
ETimer.cpp omp_M.f90
ETimer.h
./scale6.1/src/DataComm/Tribits:
CMakeLists.txt cmake tests
./scale6.1/src/DataComm/Tribits/cmake:
DataComm_config.h.in Dependencies.cmake
./scale6.1/src/DataComm/Tribits/tests:
CMakeLists.txt
TstAllocateArrays.f90
TstAllocatePointers.f90
TstDataBuffer_M.f90
TstDataBuffer_M_put_get_CHAR.f90
TstDataBuffer_M_put_get_INT4.f90
TstDataBuffer_M_put_get_INT8.f90
TstDataBuffer_M_put_get_LOGIC.f90
TstDataBuffer_M_put_get_REAL4.f90
TstDataBuffer_M_put_get_REAL8.f90
TstDataPackUnpack_CHAR.f90
TstDataPackUnpack_INT4.f90
TstDataPackUnpack_INT8.f90
TstDataPackUnpack_LOGIC.f90
TstDataPackUnpack_M.f90
TstDataPackUnpack_M_sendrecv-1.f90
TstDataPackUnpack_M_sendrecv-2.f90
TstDataPackUnpack_M_sendrecv-3.f90
TstDataPackUnpack_REAL4.f90
TstDataPackUnpack_REAL8.f90
TstTimerClass.f90
./scale6.1/src/basicGeom:
CMakeLists.txt
./scale6.1/src/bonamist:
arenko.f90 pxcalc.f90
./scale6.1/src/cajun:
cajun.f90 reader.f90
./scale6.1/src/centrm:
pxtsor_I.f90
./scale6.1/src/couple:
ampxl.f90 pool.f90
./scale6.1/src/dbcf:
CMakeLists.txt Tribits
DBCF.h dbcf_config.h.in
DBCF_M.f90
./scale6.1/src/dbcf/Tribits:
CMakeLists.txt cmake tests
./scale6.1/src/dbcf/Tribits/cmake:
Dependencies.cmake dbcf_config.h.in
./scale6.1/src/dbcf/Tribits/tests:
CMakeLists.txt dbcf_require_quoted_tester.f90
dbcf_assert_tester.f90 dbcf_require_tester.f90
dbcf_check_tester.f90 dbcf_tester.f90
dbcf_ensure_tester.f90 sample_dbc_subroutine.f90
./scale6.1/src/defBlock:
distribution.f90
./scale6.1/src/driver:
CMakeLists.txt modnam_util_M.f90.in
cntrlr_I.f90 process_time_I.f90
getmdl_I.f90 scale.f90
modnam_I.f90 scale_driver_config.h.in
./scale6.1/src/jDebug:
CMakeLists.txt Tribits jconfig.h.in jdebug.h
./scale6.1/src/jDebug/Tribits:
CMakeLists.txt cmake tests
./scale6.1/src/jDebug/Tribits/cmake:
Dependencies.cmake jconfig.h.in
./scale6.1/src/jDebug/Tribits/tests:
CMakeLists.txt jdebug_test.cpp
jdebug_fortran_test.f90
./scale6.1/src/kenovi:
track_I.f90
./scale6.1/src/mavricUtilities:
mim2wwinp.f90
./scale6.1/src/miplib:
mip_defaults_M.f90
./scale6.1/src/monaco:
extendedTally.f90 sourceGeomCuboid.f90
meshSourceHelper.f90 sourceGeomCylinder.f90
meshSourceSaver.f90 sourceGeomSphere.f90
source.f90 tally.f90
sourceGeom.f90
./scale6.1/src/newt:
cellwt2d.f90 read_array.f90
input.f90 readgeom.f90
module_xndata.f90 stopit.f90
./scale6.1/src/origen:
flxdi3.f90 matrex.f90 xterm.f90
./scale6.1/src/reorg:
ascii_to_binary.f90 binary_to_ascii.f90
./scale6.1/src/runner:
CMakeLists.txt RunnerGlobals_M.f90
Runner.f90 RunnerIO_M.f90
RunnerComm_M.f90 RunnerMessageRecord_M.f90
RunnerDataPackUnpack_M.f90 RunnerMessages_M.f90
RunnerDefaults_M.f90 RunnerTimer_M.f90
RunnerErrors_M.f90 RunnerUtils_M.f90
RunnerExecRecord_M.f90 Runner_config.h.in
RunnerFileRecord_M.f90 signal_M.f90
./scale6.1/src/samslib:
allocate_sensitivities.f90 implicit_sensitivities.f90
compute_sensitivities.f90 output_results.f90
get_input.f90
./scale6.1/src/scalelib:
CMakeLists.txt getnam.cpp
getnam.h getnam_I.f90
jobnum_I.f90 Vcdata_M.f90
./scale6.1/src/triton:
triton.f90
./scale6.1/src/tritonlib:
depletionsetup.f90 savexndata.f90
getvals.f90 scale_module.f90
handlparm.f90 sequencer.f90
init.f90 tparam_I.f90
librarian.f90 tritdirect.f90
pointer_module.f90 triton_module.f90
rdtrace.f90
SCALE 6.1.1 Known Issues
Minor Issues Identified with Fixed-Source Monte Carlo Capabilities
Corrected in SCALE 6.1.1
A few minor issues were identified with the SCALE fixed-source Monte Carlo code Monaco and an associated utility, especially related to seldom-used optional features. These features will be corrected in a pending patch for SCALE. These features should be used with caution until the patch is applied.
- When specifying the special distribution pwrNeutronAxialProfileReverse or pwrGammaAxialProfileReverse for a spatial source distribution, the un-reversed profile is erroneously returned.
Impact: This is a seldom-used feature that was implemented for compatibility with previous MORSE calculations. Problems run using one of the special axial distributions containing the word reverse are in fact not reversed, and erroneous results could result due to an inaccurate source specification.
- The sum of the point detector group-wise results may be higher than the point detector energy-integrated (total) results. The reported total is correct. The group-wise values are high due to rejecting negative contributions (which happen a small fraction of the time due to the multi-group energy/angle physics).
Impact: The energy-integrated results are correct. Only energy-dependent results are in error for some calculations. If the use of energy-dependent results is desired, users should verify that they sum to the total value.If a source specification utilizes different Watt spectra distributions in multiple sources, the energies sampled for one source may include energies from the wrong distribution.
- If a source specification utilizes different Watt spectra distributions in multiple sources, the energies sampled for one source may include energies from the wrong distribution.
Impact: Only models that implement more than one Watt spectrum are impacted. Since Watt spectra from different isotopes are quite similar, the impact of this discrepancy may not be noticeable. For Watt spectra that are very different, results may differ.
- The utility program mim2wwinp does not format MCNP *.wwinp files correctly for photon-only problems. MCNP interprets a *.wwinp with only one particle listed as neutrons, even in a "mode p" problem. The *.wwinp file produced by SCALE needs to specifically identify that there are 0 neutron groups for photon-only problems.
Impact: Subsequent MCNP calculations that use the SCALE generated .wwinp files for photon-only problems will not run.
Date Identified: 3/22/2012
Discrepancy Observed with Small Number Densities with 44-Group ENDF/B-V Data and CENTRM
Corrected in SCALE 6.1.1
An issue has been identified that can lead to non-conservative keff values when using the 44-group ENDF/B-V data with CENTRM for high-leakage models with trace-element number densities below ~10-9 atoms/barn-cm when running SCALE 5.1 – SCALE 6.1. The effect on the 238-group ENDF/B-V,VI, and VII libraries is minimal. There is no effect on continuous-energy Monte Carlo calculations.
In the dozens of test cases examined thus far, the discrepancy is only realized in cases that meet ALL of the following conditions:
- The number density of at least one nuclide has a small fractional concentration of 10-8 or less relative to the total mixture number density. Typically this corresponds to an absolute concentration less than ~10-9 to 10-10 atoms/barn-cm, but greater than zero.
- The SCALE 44-group ENDF/B-V library or a user-generated broad group library with few groups in the U-238 resolved resonance range (1 eV-4 KeV) is used.
- CENTRM is used for resonance self-shielding. This is the default behavior in SCALE 6.1, but NITAWL processing is the default behavior for SCALE 5.1 and 6.0 for the ENDF/B-V cross-section data, so the user must explicitly request CENTRM processing to observe the discrepancy with SCALE 5.1 or 6.0.
- The system is sensitive to the high-energy portion of the resolved range, which most commonly occurs for high leakage systems. Low-leakage criticality and depletion models examined realized only a minimal impact.
- Calculations are performed with SCALE 5.1, 6.0 or 6.1.
Impact on calculations:
- Continuous-energy KENO calculations do not use CENTRM and are not affected.
- The impact for all 238-group calculations examined thus far is small, on the order of a few pcm.
- Eigenvalues and isotopic concentrations computed for the 44-group ENDF/B-V depletion cases examined are not significantly affected, as these are low-leakage systems [reflected lattice geometries]. For most cases that meet all of the above criteria, including burned fuel criticality safety calculations that include small concentrations of fission products, the discrepancy introduces an error on the order of 100 pcm.
- In a contrived case that artificially introduces a trace material into a plutonium nitrate system, a discrepancy of ~3% delta-k was observed. This is the maximum discrepancy observed for the real and hypothetical systems examined thus far, but it should not be considered a bounding value.
Corrective Action
- The SCALE Team is developing a patch that corrects this issue.
- Users should examine calculations to determine if they meet the criteria provided above.
- The eigenvalue for suspect systems should be examined using a different library, such as the 238-group ENDF/B-V to determine if a particular system is impacted.
- Users should install the SCALE 6.1 patch when it is available and repeat any suspect calculations.
Date Identified: 1/9/12
Acknowledgement: This issue was first identified by SCALE user Dale Lancaster
Optional Output Edit in STARBUCS
In STARBUCS burnup credit loading curve search calculations, an optional input prt=short may be used within the READ SEARCH input block to restrict the final output to contain only relevant information for a burnup loading curve calculation. In SCALE 6.1, this optional input causes the calculation to crash.
Users should only use the default parameter prt=long, which retains all SCALE output information for the last step of the iterative fuel enrichment search process. As prt=long is the default option in STARBUCS, there is no need for this input option to be specified in a STARBUCS input file.
Date Identified: 2/10/2011
MacOS System Requirements
The SCALE 6.1 Readme states that the system will operate on Mac OSX version 10.5 or newer, where Mac OSX 10.6 or newer is actually required to properly execute SCALE 6.1.
The symptoms are such that the SCALE runtime will execute and a job banner will be produced, but the executable modules will fail.
If messages are turned on (-m flag on the batch6.1 command) the following message will be reported:
'dyld: unknown required load command 0x80000022'
The solution is to upgrade to Mac OSX 10.6 or newer.
Date Identified: 2/23/2012
Windows ORIGEN and OPUS Sample Problems
Corrected in SCALE 6.1.1
There has been an issue identified when running the ORIGEN and OPUS sample problems on Windows.
Specifically, the sample problems' shell script uses an invalid path when attempting to copy needed resources into the working directory. Without these needed resources, both sample problems fail to produce the expected results.
The fix is simple. For the origen.input and opus.input files, located in
scale6.1\smplprbs\Windows, replace
=shell
copy z:\scale_staging\data\arplibs\w17_e40.arplib ft33f001
end
with
=shell
copy %DATA%\arplibs\w17_e40.arplib ft33f001
end
Date Identified: 8/30/2011
Unable to access jarfile ... ScaleDiff.jar
Corrected in SCALE 6.1.1
There has been an issue identified where when running the sample problems,
the ScaleDiff.jar file is not found producing an 'Unable to access jarfile ... ScaleDiff.jar' message.
The issue is due to not having the source code installed.
The ScaleDiff-Samples.xml zip file contains the following:
• samples.xml
• ScaleDiff.jar
Do the following to update your Scale6.1 install
1. Extract the contents into your Scale6.1 directory. You will be prompted to ‘copy and replace’ your samples.xml file.
2. Move the Scale6.1\ScaleDiff.jar file into your Scale6.1\cmds directory. You will be prompted ‘copy and replace’ your ScaleDiff.jar file.
The updated Scale6.1\samples.xml, and Scale6.1\cmds\ScaleDiff.jar files should be available to verify Scale as detailed in the readme file.
Updated: 11/15/2011
table_of_content_*.txt: no such file or directory
Corrected in SCALE 6.1.1
When running the sample problems an error may occur similar to the following,
C:\Scale6.1\Windows_amd64\bin\grep: table_of_content_*.txt: No such file or directory
This is due to a typo in the scale\samples.xml file.
'table_of_content_*' should be 'table_of_contents_*'. Notice the extra 's'.
Edit your Scale\samples.xml file, find 'table_of_content_*' and replace with 'table_of_contents_*'.
Date Identified: 10/6/2011
ORIGEN 200-group cross section library
Corrected in SCALE 6.1.1
A problem was identified in the energy-group boundaries of the ORIGEN 200-neutron-group cross-section library, origen.rev02.jeff200g. The boundaries were generated with constant lethargy instead of the boundaries of the SCALE 200-group transport library. Use of this library is currently not recommended, as it will produce erroneous results. An update to the library will be available soon.
Date Identified: 10/24/2011
ORIGEN natural isotopic abundances
Corrected in SCALE 6.1.1
The natural isotopic abundances for several elements in the ORIGEN library are incorrect. The abundances have been corrected and an updated library will be available soon. The use of natural isotopic abundances (NEX1=4) for input element concentrations enter in gram units may result in incorrect isotopic concentrations for Mg, Ge, Kr, Sr, and Te. If atom units (gram atoms) are used, incorrect isotopic concentration may occur for F, Na, Mg, Al, P, Sc, Mn, Co, Ge, As, Kr, Sr, Y, Nb, Rh, Te, I, Cs, Pr, Tb, Ho, Tm, and Au.
Date Identified: 10/24/2011
Problem with thermal energy cutoff in continuous-energy KENO calculations
Internal testing of continuous-energy calculations with KENO has revealed a considerable non-conservative change in keff, on the order of 20%, for cases involving BeO. Users who properly validate continuous-energy KENO calculations for these systems would notice a strong systematic bias for bound BeO cases prior to use in safety calculations. Nevertheless, users should not use be-beo in continuous-energy KENO calculations.
Note that multigroup calculations in KENO are not affected by this issue, and updates to the continuous-energy data for bound BeO will be available soon.
Further explanation:
Scale continuous energy neutron cross-section libraries are based on ENDF/B-VI Release 8 and ENDF/B-VII Release 0. While most of the neutron cross sections are for nuclides that are assumed to be free (not bound in a molecule), some nuclide cross sections are for bound nuclei that are commonly referred to as s(a,b) cross sections or thermal kernels. Hydrogen bound in water or Be in BeO are some example nuclei that have bound thermal cross sections. Scale continuous-energy neutron cross-section libraries were generated by processing the ENDF thermal kernel data for incident neutron energies of 5.05eV or below. To provide flexibility in analysis without the need to regenerate the cross section library, KENO was designed to implement a user-selectable value for the thermal cutoff for s(a,b) treatment, with default neutron cutoff energy of 3eV. Above this cutoff the effects of thermal motion of the molecule are assumed to be negligible.
As a result of a recent internal testing, it was discovered that KENO does not apply the thermal cutoff value to the use of s(a,b) treatment. If the evaluation does not have data up to 5.05eV, the short collision time method is used to extend the incoherent inelastic scattering data up to 5.05eV. Coherent elastic scattering is generated only for the energy range specified in the ENDF file. It was discovered that for Be in BeO, the coherent elastic and incoherent inelastic scattering cross sections extended beyond 3eV but did not have the same upper cut-off value. When KENO ignores the default thermal cut-off value of 3eV, it tries to sample from both coherent elastic and incoherent inelastic and obtains the wrong cross section between the cut-off values of these reactions.
Date Identified: 10/25/2011