Merge pull request idaholab#300 from idaholab/PR_tag3

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licharlot · Oct 2, 2023 · 548f0a5 · 548f0a5
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diff --git a/.github/ISSUE_TEMPLATE/feature-request.md b/.github/ISSUE_TEMPLATE/feature-request.md
@@ -0,0 +1,17 @@
+---
+name: Test Bed Feature Request
+about: Ask for a new feature in the Virtual Test Bed. NOT for reactor model improvements!
+title: ''
+labels: ''
+assignees: ''
+
+---
+
+## Feature Description
+<!--A clear and concise description of the feature you would like -->
+
+## Design
+<!-- How do you think this feature should be implemented? Is this requiring some website development? Some MOOSEDocs development? -->
+
+## Impact
+<!-- How does this feature help you? How does it help the wider community? -->
diff --git a/doc/content/htgr/assembly/index.md b/doc/content/htgr/assembly/index.md
@@ -6,9 +6,10 @@
 
 !tag name=Multiphysics Coupling of OpenMC, MOOSE, and THM for a HTGR pairs=reactor:HTGR
                        geometry:assembly
-                       simulation_type:assembly_multiphysics
+                       simulation_type:multiphysics
                        code_used:cardinal
                        open_source:true
+                       transient:steady_state
                        input_features:multiapps
                        computing_needs:HPC
                        fiscal_year:2022

diff --git a/doc/content/htgr/generic-pbr/generic-pbr_model.md b/doc/content/htgr/generic-pbr/generic-pbr_model.md
@@ -4,9 +4,11 @@
 
 *Model link: [Generic PBR SAM Model](https://github.com/idaholab/virtual_test_bed/tree/devel/htgr/generic-pbr)*
 
-!tag name=SAM Generic PBR Model pairs=reactor:HTGR
+!tag name=SAM Generic PBR Model pairs=reactor_type:HTGR
+                       reactor:generic_PBR
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
+                       transient:load_follow
                        code_used:SAM
                        computing_needs:Workstation
                        fiscal_year:2021

diff --git a/doc/content/htgr/htr10/griffin_htr10_model.md b/doc/content/htgr/htr10/griffin_htr10_model.md
@@ -7,7 +7,8 @@
 !tag name=HTR-10 Griffin Neutronics Model pairs=reactor_type:HTGR
                        reactor:HTR-10
                        geometry:core
-                       simulation_type:core_neutronics
+                       simulation_type:neutronics
+                       transient:steady_state
                        code_used:Griffin
                        computing_needs:Workstation
                        fiscal_year:2021

diff --git a/doc/content/htgr/httf/httf_multiapp_model.md b/doc/content/htgr/httf/httf_multiapp_model.md
@@ -7,7 +7,7 @@
 !tag name=HTTF Core Model pairs=reactor_type:HTGR
                        reactor:HTTF
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
                        code_used:RELAP-7
                        input_features:multiapps
                        computing_needs:HPC

diff --git a/doc/content/htgr/httf/lower_plenum_cfd.md b/doc/content/htgr/httf/lower_plenum_cfd.md
@@ -7,7 +7,8 @@
 !tag name=Nek5000 CFD Modeling of HTTF Lower Plenum Flow Mixing Phenomenon pairs=reactor_type:HTGR
                        reactor:HTTF
                        geometry:plenum
-                       simulation_type:component_CFD
+                       simulation_type:CFD
+                       transient:steady_state
                        code_used:Nek5000
                        computing_needs:HPC
                        open_source:true

diff --git a/doc/content/htgr/httr/httr_null_transient_model_description.md b/doc/content/htgr/httr/httr_null_transient_model_description.md
@@ -7,7 +7,7 @@
 !tag name=High Temperature Engineering Test Reactor (HTTR) Null Transient Model pairs=reactor_type:HTGR
                        reactor:HTTR
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
                        input_features:multiapps
                        transient:null
                        code_used:Sabertooth

diff --git a/doc/content/htgr/httr/httr_steady_state_model_description.md b/doc/content/htgr/httr/httr_steady_state_model_description.md
@@ -7,8 +7,9 @@
 !tag name=High Temperature Engineering Test Reactor Steady State Model pairs=reactor_type:HTGR
                        reactor:HTTR
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
                        input_features:multiapps
+                       transient:null
                        code_used:Sabertooth
                        computing_needs:Workstation
                        fiscal_year:2023

diff --git a/doc/content/htgr/leu_pulse/treat_leu_model.md b/doc/content/htgr/leu_pulse/treat_leu_model.md
@@ -6,7 +6,7 @@
 
 !tag name=LEU Fuel Pulse pairs=reactor_type:HTGR
                        geometry:mini-core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
                        transient:RIA
                        code_used:Griffin
                        computing_needs:Workstation

diff --git a/doc/content/htgr/mhtgr_griffin/mhtgr350_model.md b/doc/content/htgr/mhtgr_griffin/mhtgr350_model.md
@@ -7,7 +7,9 @@
 !tag name=MHTGR Griffin Benchmark pairs=reactor_type:HTGR
                        reactor:MHTGR
                        geometry:core
-                       simulation_type:core_neutronics
+                       simulation_type:neutronics
+                       transient:steady_state
+                       V&V:benchmark
                        code_used:Griffin
                        computing_needs:Workstation
                        fiscal_year:2023

diff --git a/doc/content/htgr/mhtgr_sam/sam_mhtgr_model.md b/doc/content/htgr/mhtgr_sam/sam_mhtgr_model.md
@@ -2,10 +2,11 @@
 
 *Contact: Thanh Hua, hua.at.anl.gov*
 
-*Model link: [MHTGR SAM Model](https://github.com/idaholab/virtual_test_bed/tree/devel/htgr/mhtgr/mhtgr_sam)*
+*Model link: [MHTGR SAM Model](https://github.com/idaholab/virtual_test_bed/tree/main/htgr/mhtgr/mhtgr_sam)*
 
 !tag name=MHTGR SAM Model pairs=reactor_type:HTGR
                        reactor:MHTGR
+                       geometry:primary
                        simulation_type:balance_of_plant
                        code_used:SAM
                        computing_needs:Workstation

diff --git a/doc/content/htgr/pb67_cardinal/index.md b/doc/content/htgr/pb67_cardinal/index.md
@@ -8,6 +8,7 @@
                        geometry:pebble_bed
                        simulation_type:CFD
                        code_used:NekRS
+                       input_features:multiapps
                        computing_needs:Workstation
                        gpu_enabled:true
                        open_source:true

diff --git a/doc/content/htgr/pbmr/model_description.md b/doc/content/htgr/pbmr/model_description.md
@@ -7,10 +7,12 @@
 !tag name=Pebble Bed Modular Reactor Core Multiphysics pairs=reactor_type:HTGR
                        reactor:PBMR-400
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
+                       input_features:multiapps
+                       transient:PLOFC
                        code_used:BlueCrab
                        computing_needs:Workstation
-                       fiscal_year:2022
+                       fiscal_year:2021
 
 The VTB PBMR case is based on the PBMR400 coupled benchmark specifications described in [!citep](PBMR400). The benchmark design has been derived from the 400 MWth Pebble Bed Modular Reactor (PBMR) demonstration plant. The PBMR-400 is a modular thermal reactor with helium coolant and graphite moderator. It utilizes 9.6% enriched uranium dioxide fuel encapsulated with four shells of pyrolitic graphite and ceramic layers, known as TriStructural Isotropic (TRISO) particles. These particles are then embedded into larger graphite pebbles. There are roughly 15,000 of these TRISO particles in each of the 452,000 graphite pebbles in the system. These pebbles are contained in an annular region where they enter the core from the top and leave through the defueling chute at the bottom. Pebbles then are either recirculated or discarded based on their burnup; a pebble makes an average of six passes through the core. During normal operation, 192.7 kg/s of helium at an inlet temperature of 773K flows through the pebbles from the top to the bottom of the core, reaching roughly 1173K at the outlet.
 

diff --git a/doc/content/htgr/triso/triso_model.md b/doc/content/htgr/triso/triso_model.md
@@ -5,9 +5,10 @@
 *Model link: [TRISO Bison Model](https://github.com/idaholab/virtual_test_bed/tree/devel/htgr/triso_fuel)*
 
 !tag name=TRISO Bison Model pairs=reactor_type:HTGR
-                       geometry:triso
-                       simulation_type:fuel
+                       geometry:TRISO
+                       simulation_type:fuel_performance
                        code_used:Bison
+                       transient:depletion
                        computing_needs:Workstation
                        fiscal_year:2022
 
@@ -19,7 +20,7 @@ The fuel parameters are given in [table:fuel_parameters]. The irradiation condit
 !table id=table:fuel_parameters caption=Fuel parameters used in this input file
 | Parameter                           | Values |
 |-------------------------------------|--------|
-| $^{235}$U enrichment (wt %)           | 15.5   |
+| $^{235}$U enrichment (wt %)         | 15.5   |
 | Carbon/uranium (atomic ratio)       | 0.4    |
 | Oxygen/uranium (atomic ratio)       | 1.5    |
 | Kernel diameter ($/mu$ m)             | 425    |

diff --git a/doc/content/lfr/heterogeneous_single_assembly_3D/Griffin_standalone_LFR.md b/doc/content/lfr/heterogeneous_single_assembly_3D/Griffin_standalone_LFR.md
@@ -9,11 +9,13 @@
                        simulation_type:assembly_neutronics
                        code_used:Griffin
                        computing_needs:HPC
+                       input_features:reactor_meshing
+                       cross_sections:MC2
                        fiscal_year:2023
 
 This VTB model provides a high fidelity neutronics model for a representative example of a lead-cooled fast reactor with an annular MOX (UPuO) fuel. Its design is based on an early iteration of an LFR-prototype assembly provided by Westinghouse Electric Company, LLC [!citep](WECLFR). The original purpose of this model is to characterize the impact of various sources of uncertainties, such as theoretical and experimental uncertainties, instrumentation uncertainties, manufacturing tolerances, correlation uncertainties, and the method and simulation uncertainties, on peak cladding, fuel and coolant temperatures in the system. For this purpose, high fidelity neutronics (fine mesh heterogeneous transport - Griffin) and thermalhydraulics (computational fluid dynamics - NekRS) calculations were performed to compute hot channel factors (HCFs) [!citep](HCFReport). A 3D heterogeneous single assembly steady-state problem was used since a full core model is seldom used for the HCF evaluation. In this VTB model, only the neutronics standlone model is explained.
 
-First, the LFR model is described, followed by the cross section generation procedure using MC2-3 [!citep](MCC3manual). Then, the Griffin standalone calculation setting with the discontinuous fininte element method (`DFEM`) discrete ordinate (`SN`) scheme with the Coarse Mesh Finite Difference (`CMFD`) acceleration is explained and the results are discussed.
+First, the LFR model is described, followed by the cross section generation procedure using MC2-3 [!citep](MCC3manual). Then, the Griffin standalone calculation setting with the discontinuous finite element method (`DFEM`) discrete ordinate (`SN`) scheme with the Coarse Mesh Finite Difference (`CMFD`) acceleration is explained and the results are discussed.
 
 ## Description of LFR design
 

diff --git a/doc/content/microreactors/airjacket/index.md b/doc/content/microreactors/airjacket/index.md
@@ -7,7 +7,7 @@
 !tag name=Gas-Cooled Microreactor Air Jacket pairs=reactor_type:microreactor
                        reactor:GCMR
                        geometry:air_jacket
-                       simulation_type:component_CFD
+                       simulation_type:CFD
                        code_used:Nek5000
                        open_source:true
                        computing_needs:HPC

diff --git a/doc/content/microreactors/gcmr/BOP_model_description.md b/doc/content/microreactors/gcmr/BOP_model_description.md
@@ -1,5 +1,14 @@
 # Balance of Plant system
 
+!tag name=Gas-Cooled Microreactor Balance of Plant pairs=reactor_type:microreactor
+                       reactor:GCMR
+                       geometry:plant
+                       simulation_type:multiphysics
+                       code_used:BlueCrab
+                       transient:load_follow
+                       computing_needs:Workstation
+                       fiscal_year:2023
+
 The startup transient and load follow input file have the same structure and only differ by their initial condition and control system governing the transient. The components are the same.
 
 ## Fluid flow

diff --git a/doc/content/microreactors/gcmr/GCMR_Multiphysics_models.md b/doc/content/microreactors/gcmr/GCMR_Multiphysics_models.md
@@ -4,6 +4,16 @@
 
 *Model link: [GCMR Assembly Model](https://github.com/idaholab/virtual_test_bed/tree/devel/microreactors/gcmr/assembly)*
 
+!tag name=Gas-Cooled Microreactor Assembly pairs=reactor_type:microreactor
+                       reactor:GCMR
+                       geometry:assembly
+                       simulation_type:multiphysics
+                       code_used:BlueCrab
+                       input_features:multiapps
+                       transient:RIA
+                       computing_needs:HPC
+                       fiscal_year:2023
+
 ## Mesh files
 
 !alert note

diff --git a/doc/content/microreactors/gcmr/index.md b/doc/content/microreactors/gcmr/index.md
@@ -2,15 +2,6 @@
 
 *Contacts: Ahmed Abdelhameed (aabdelhameed.at.anl.gov), Yinbin Miao (ymiao.at.anl.gov), Nicolas Stauff (nstauff.at.anl.gov)*
 
-!tag name=Gas-Cooled Microreactor Assembly pairs=reactor_type:microreactor
-                       reactor:GCMR
-                       geometry:assembly
-                       simulation_type:assembly_multiphysics
-                       code_used:BlueCrab
-                       transient:RIA
-                       computing_needs:HPC
-                       fiscal_year:2023
-
 [Description of the assembly design](gcmr/GCMR_Assembly_Model_Description.md)
 
 [Multiphysics Models](gcmr/GCMR_Multiphysics_models.md)

diff --git a/doc/content/microreactors/mrad/mrad_model.md b/doc/content/microreactors/mrad/mrad_model.md
@@ -7,7 +7,8 @@
 !tag name=Micro-Reactor Multiphysics model pairs=reactor_type:microreactor
                        reactor:HPMR
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
+                       input_features:multiapps
                        transient:overpower
                        code_used:BlueCrab
                        computing_needs:HPC

diff --git a/doc/content/microreactors/s8er/s8er_multiphysics_model.md b/doc/content/microreactors/s8er/s8er_multiphysics_model.md
@@ -8,8 +8,8 @@
 !tag name=SNAP 8 Experimental Reactor Multiphysics model pairs=reactor_type:microreactor
                        reactor:SNAP-8
                        geometry:core
-                       features:multiapps
-                       simulation_type:core_multiphysics
+                       input_features:multiapps
+                       simulation_type:multiphysics
                        code_used:Griffin
                        computing_needs:Workstation
                        fiscal_year:2023

diff --git a/doc/content/msr/msfr/griffin_pgh_transient_model.md b/doc/content/msr/msfr/griffin_pgh_transient_model.md
@@ -7,7 +7,7 @@
 !tag name=MSFR Griffin-Pronghorn Transient Model pairs=reactor_type:MSR
                        reactor:MSFR
                        geometry:core
-                       simulation_type:core_multiphysics
+                       simulation_type:multiphysics
                        input_features:multiapps
                        transient:ULOF
                        code_used:BlueCrab

diff --git a/doc/content/msr/msfr/plant/SAM_model.md b/doc/content/msr/msfr/plant/SAM_model.md
@@ -2,7 +2,7 @@
 
 *Contact: Jun Fang, fangj.at.anl.gov; Mauricio Tano, mauricio.tanoretamales.at.inl.gov*
 
-*Model link: [Standalone SAM Model](https://github.com/idaholab/virtual_test_bed/tree/devel/msr/msfr/plant/standalone_sam_model)*
+*Model link: [Standalone SAM Model](https://github.com/idaholab/virtual_test_bed/tree/main/msr/msfr/plant/standalone_sam_model)*
 
 !tag name=Molten Salt Fast Reactor SAM Model pairs=reactor_type:MSR
                        reactor:MSFR

diff --git a/doc/content/msr/msfr/plant/steady_state_coupling.md b/doc/content/msr/msfr/plant/steady_state_coupling.md
@@ -4,7 +4,8 @@
 
 !tag name=MSFR Steady-State Griffin-Pronghorn-SAM Coupling pairs=reactor_type:MSR
                        reactor:MSFR
-                       simulation_type:primary
+                       geometry:primary_loop
+                       simulation_type:multiphysics
                        code_used:BlueCrab
                        input_features:multiapps
                        computing_needs:HPC

diff --git a/doc/content/msr/msre/msre_sam_model.md b/doc/content/msr/msre/msre_sam_model.md
@@ -6,7 +6,7 @@
 
 !tag name=Molten Salt Reactor Experiment SAM Model pairs=reactor_type:MSR
                        reactor:MSRE
-                       simulation_type:primary
+                       geometry:primary_loop
                        code_used:SAM
                        computing_needs:Workstation
                        fiscal_year:2022

diff --git a/doc/content/pbfhr/balance_of_plant/plant.md b/doc/content/pbfhr/balance_of_plant/plant.md
@@ -9,7 +9,7 @@
                        simulation_type:balance_of_plant
                        code_used:BlueCrab
                        computing_needs:Workstation
-                       features:multiapps
+                       input_features:multiapps
                        fiscal_year:2022
 
 The [multiphysics core model](pbfhr/steady/griffin_pgh_model.md), which uses Griffin for neutronics and Pronghorn for

diff --git a/doc/content/sfr/abtr/abtr.md b/doc/content/sfr/abtr/abtr.md
@@ -13,7 +13,7 @@
 
 ## ABTR description
 
-A demonstrative system model based on the Advanced Burner Test Reactor (ABTR) conceptual design has been developed with the recent SAM capabitility enhancement in structure thermal expansion and reactivity feedback modeling. More details can be found in [!citep](Hu2019) regarding the implementation of Point Kinetics model and verifications of thermal expansion models.
+A demonstrative system model based on the Advanced Burner Test Reactor (ABTR) conceptual design has been developed with the recent SAM capability enhancement in structure thermal expansion and reactivity feedback modeling. More details can be found in [!citep](Hu2019) regarding the implementation of Point Kinetics model and verifications of thermal expansion models.
 
 The detailed design parameters of the 250 MW pool type design ABTR can be found in [!citep](Chang2008). The primary system is configured in a pool-type arrangement, with the reactor core, primary pumps, intermediate heat exchangers, and direct reactor auxiliary cooling system heat exchangers all immersed in a pool of sodium coolant within the reactor vessel. The reactor core consists of 24 assemblies in an inner enrichment zone and 30 assemblies in the outer zone. A total of nine test locations are provided for fuel (6 assemblies) and material (3 assemblies) tests. On the basis of the reactor physics calculations, a five-channel model was selected to model the reactor core. Channel 1 is used to represent the peak-power inner-core subassembly with fresh fuel. Channels 2 and 4 represent the average subassemblies in the inner and outer enrichment zones respectively, while channel 3 represents the average of the mid-core fuel test assemblies.  Channel 5 represents all of the non-fuel subassemblies, including the mid-core materials test assemblies. [assembly] shows the initial subassembly powers at the beginning of equilibrium cycle conditions, and the average axial power shape for all assemblies. The geometric data and input conditions employed in the multi-channel core model are shown in [channels].