Neutronics R&D Needs and Testing In Fusion Test Facility M. Youssef UCLA APEX/TBM Meeting, November 3-5, 2003, UCLA.

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Neutronics R&D Needs and Testing In Fusion Test Facility M. Youssef UCLA APEX/TBM Meeting, November 3-5, 2003, UCLA

Important Nuclear Parameters of Interest To be Tested in TBM and Related Performance Issues Tritium production rate and profile (TBR and Tritium self-sufficiency) Volumetric nuclear heating rate and profile (Thermo-mechanics, stresses, temperature windows, thermal efficiency, etc) Induced Radioactivity and transmutation (Low activation and waste disposal rating, recycling, safety, scheduled maintenance, availability) Decay Heat (Safety, emergency cooling system design, etc) Radiation damage profiles (dpa, He, H) (Components’ lifetime, maintenance, availability, etc)

Neutronics Issues to be Resolved in ITER TBM Unlike the neutronics integral experiments in progress at 14 MeV fusion point source facilities (FNS, FNG, SNEG-13, etc), ITER will offer a volumetric D-T neutron source (plasma) representative of the one found in a realistic fusion environment. Key neutronics issues to be resolved in ITER are generic in nature and are important to each TBM type to be located in test ports, regardless of the party involved. Main Issues to be resolved: Demonstration of tritium self-sufficiency for a particular FW/B/S concept Verification of the adequacy of current transport codes and nuclear data bases in predicting key parameters such as local and (zonal) tritium production rate (TPR), heating rates (kerma factors verification), induced activation (transmutation cross-sections), decay heat (decay data) and dose rates after shutdown, gas production rates (component life time issue) Verification of adequate radiation protection of machine components (SC magnet) and personnel (accessibility for maintenance). Sharing experience among parties should be planned

Testing Tritium Self-sufficiency in ITER Direct demonstration of tritium self-sufficiency requires a fully integrated reactor system, including the plasma and all reactor prototypic nuclear components. This does not appear to be possible in ITER (e.g. basic shielding blanket does not produce tritium, no interface with tritium processing system in the TBM’, partial coverage vs.. full coverage in DEMO, etc. ) It may be necessary to rely on indirect demonstration by utilizing the information obtained from local and zonal tritium production rate in the TBM and the associated uncertainties in their prediction, in addition to information on tritium extraction and flow in TBM, and extrapolate this information to DEMO and power-producing reactor conditions. This seems to be a difficult task

Impact of Partial Coverage of TBM on Local Tritium Production Rate, TPR ( compared to full coverage) Ratio Ratio of local TBR from 6 Li (T 6 ) and 7 Li (T 7 ) in the poloidal direction at front breeding surface to corresponding values in full coverage case

Higher Li-6 enrichment could increase heating rates to values in act-alike module Two TBM of the EU Li 4 SiO 4 helium –cooled design are placed in the test port A lattice consists of FS layer (0.8 cm), Be bed layer (4.5 cm) and SB bed layer (1.1 cm) Buffer zone between modules (10 cm) Upper module has 75% Li-6 (19 lattices), lower module 25% Li-6 (16 lattices) Lower attenuation (higher flux) behind beryllium layers Heating Rate (w/cc) SB (upper TBM) SB (lower TBM) Be (upper) Be (lower) Be SB Streaming Effect Upper TBM Lower TBM

Classification of Neutronics Tests (A) Dedicated Neutronics Test Aim at examining the present state-of-the-art neutron cross-section data, various methodologies implemented in transport codes, and system geometrical modeling as to the accuracy in predicting key neutronics parameters. Comparison to measured data and performing cross- section sensitivity/uncertainty analysis, as needed, to reveal which particular cross-section requires improvements and in what energy range.

Dedicated Neutronics Test (con’d) Measurements to be performed in TBM Neutron yield and external DD or DT source characterization (basically from plasma diagnostics) Neutron and gamma heating rates and profiles Local (and if possible zonal) tritium production rates and profile Neutron and gamma-rays spectra at various locations Multi foil activation measurements (e.g. 27 Al(n,2n), 27 Al(n,a), 197 Au(n,g), 58 Ni(n,p), etc). These MFA measurements is used for neutron spectrum quantification. Out-of-Pile measurements include dose measurements behind the test module, at the port plug, the cryostat, etc. and can be performed concurrently with in- pile measurements

Dedicated Neutronics Tests and Fluence Requirements Operation ScenarioSteady-state or pulsed operation A dedicated material test facility other than ITER (IFMIF) may be necessary since the accumulated fluence test in ITER is ~0.09 MWa/m2 in 10 years

Fluence Requirements for Some Measuring Techniques a: For counter methods, the measuring time is assumed to be 10 to 100 sec

ITER Operational Plan and Co-odinated Schedule of Blanket Testing EM: Electro-magnetic. NT: Neutronics and Tritium Production. TM: Thermo mechanics. PI: Integral Performance Dedicated neutronics test: during DD operation (year 4) and low duty DT operation (year 5&6) Supplementary neutronics test to provide heat source to thermo- mechanics test and tritium control tests

Supplementary Neutronics Tests Intended to be performed in TBM (or sub modules) used for non- neutronics tests Objectives: Provide additional supporting information to the dedicated tests in examining the prediction capabilities Provide the source term (e.g. heat generation and tritium production rate) for other non-neutronics tests devoted to predictive behavior and engineering performance verification (e.g. tritium permeation and recovery tests, thermo-mechanics tests, afterheat removal tests, etc) These tests can be scheduled during the high duty D-T operation (year 7-10) devoted to the integrated tests.

Needs for a Timely Neutronics R&D Program An aggressive neutronics R&D program is needed prior to the construction of ITER basic machine and TBM’s For more than two decades, serious worldwide efforts were put to execute such a program utilizing both available 14 MeV point (and line ) sources as well as fission reactors Examples: The US/JAERI Collaborative program on Fusion neutronics (10-years effort) ( ) ITER basic shielding blanket integral experiments (EU, JA, RF, US)- ( ) –US pulled out 1998 IEA Collaborative Program on the Technology of Fusion Reactors, Sub-task “Fusion Neutronics (1995-present)

IEA Collaborative Program on Fusion Neutronics Participants: EU, JA, US, RF Pre-agreement Meetings: ENEA (Italy) on September 22, Garching (Germany) on March 26, 1993 UCLA on October 22, UCLA on June 1, Officially started on 13 June 1994 for five-year period Official Meetings: ENEA (Italy) on March 3, an informal meeting at FZK (Germany) on October 20, Prague (Czech Republic) in September, Trieste (Italy) in May 22, Marseille (France) on September 8, Rome, September 21, The collaboration was renewed for another 5 years Madrid (Spain), September 2000 Dresden, (Germany) September 2002 Kyoto (Japan), December 2003

Main Elements of the Neutronics R&D Program Basic nuclear data measurements and evaluation Both double differential and integrated data are needed along with range of uncertainties. Evaluated data are needed for cross sections that are not measured Nuclear data processing and generation of transport and response working data libraries in various formats suitable for transport codes. Point wise and multi-group data libraries Transport and response codes development Monte Carlo and discrete ordinates codes, kerma factors and activation codes Integral experiments and analysis Experimental measuring techniques development

Inter-relationship Between Fusion Design Analysis and Blanket/Shield Neutronics R&D BLANKET/SHIELD NEUTRONICS R&D PROGRAM Integral Fusion Neutronics Experiments & Analysis (Using 14 MeV Neutron Sources) Integral Fusion Neutronics Experiments & Analysis (Using 14 MeV Neutron Sources) Codes Development Transport Codes Nuclear Heating Activation Codes Development Transport Codes Nuclear Heating Activation Nuclear Data Evaluation Cross-Sections Measurements Nuclear Data Bases ENDV/B-VI BROND JENDL-3 CENDL FENDL Data Base Data Processing Working Libraries Safety Factors C/E NUCLEAR DESIGN ANALYSIS ITER, CTR, etc. NUCLEAR DESIGN ANALYSIS ITER, CTR, etc. Improving Codes and Data

Areas for Long-term Neutronics R&D (A)Experiments /Measuring Techniques (1) Integral Experiments Testing of innovative blanket and shielding concepts for DEMO and power-producing fusion reactors - High tritium production rate - Low activation breeding materials/structural materials (e.g. SiC/Li2ZrO3/Be) - High performance shielding characteristics (2) Experimental Technique Development Advancing techniques and methods for neutronics testing - tritium production rates, - Neutron and gamma-spectrum - Volumetric Heating rates - Post-shutdown decay heating rates - Plasma diagnostics techniques, in situ-measurements, and dosimetry. Areas for Long-term Neutronics R&D (A) Experiments /Measuring Techniques (1) Integral Experiments Testing of innovative blanket and shielding concepts for DEMO and power-producing fusion reactors - High tritium production rate - Low activation breeding materials/structural materials (e.g. SiC/Li2ZrO3/Be) - High performance shielding characteristics (2) Experimental Technique Development Advancing techniques and methods for neutronics testing - tritium production rates, - Neutron and gamma-spectrum - Volumetric heating rates - Activation/Post-shutdown decay heat rates - Plasma diagnostics techniques, in situ-measurements, and dosimetry.

Areas for Long-term Neutronics R&D (Cont’d) (B) Codes Development (1) Transport and Response Codes Compare neutron/gamma transport and response codes and calibrate against experimental benchmarks. Recommend a set of reference codes for design. Suggest any required improvements in codes Transport Codes: Deterministic codes: 1-,2-,3-DANT, DORT, TORT, ANISN (US), PERMUDA (J), BISTRO (EU) Monte Carlo Codes: MCNP (US), TRIPOLI (EU), MORSE-DD, GMVP (J) Response Codes: Activation Codes: ALARA, DKR-PULSAR, REAC (US), FISPACT, ANITA (EU), THIDA (J) Nuclear Heating Codes: Mack, KAOS (US) Data Processing codes: NJOY, TRANSX, AMPX (US) Pre- and Post-Analysis sensitivity/uncertainty Codes: Deterministic: FORSS, UNCER, DENSIT (US), BISTRO (EU) Monte Carlo: Coupled Monte Carlo Sensitivity/uncertainty treatment (FZK, EU)

Areas for Long-term Neutronics R&D (Cont’d) (B) Codes Development (Cont’d) (2) Examples of Ongoing/needed developments in Codes: MC sensitivity/uncertainty computational techniques (FZK) Coupled MC/SN radiation field analysis for large systems (e.g. ITER Building*) (FZK) CAD - Interface for MCNP Input (FZK, UW) Radiation damage simulation (FZK) _____________________________________________________ * Coupled 2-D and 3-D Calculations using Deterministic method (DORT and TORT codes) for neutron and gamma flux calculations and DKR-Pulsar code were done in the US for earlier ITER building to assess dose rates (  S/h) in ITER Building During Operation and After Shut Down

Configurations of the Experiments in US-JAERI Collaboration ( Phase I&II: ‘84-’89, Phase III: ‘89-’93 Phase I: open geometry, SS FW, Be Sandwiched Expts Phase IIA and IIB: Be linear and Sandwiched Expts Phase III: Line source exprts. Armor effect, large opening effects. Phase IIC: Coolant channels expts

Prediction Uncertainty in the Line-integrated TPR from Li-6 (Li-glass Measurements) Line-integrated TPR for calculated and measured data were obtained using the least squares fitting method. Fitting coefficients and their covariance were obtained. The prediction uncertainty is quantified in terms of the quantity u=(C/E-1)X 100 with the relative variance,

Normalized Density Function (NDF) and Safety Factors For the Prediction Uncertainty in T 6 (Li-glass Measurements ) The Gaussian distributions approximate well the normalized density function (NDF)- Both US and JAERI codes and data from previous viewgraph are considered for Li-glass measurements (all phases) Confidence level for calculations not to exceed measurements as a function of design safety factors for T6 (all phases)

Findings regarding the prediction uncertainties in the Line- integrated Tritium Production from Li-6 (T6) Li2O breeder Tritium Production from Li-6: Prediction uncertainty in T6 ~ 5% (US) and ~2% (JAERI) with standard deviation ~8-9% based on all calculation methods and measuring techniques. To achieve the highest confidence level that calculated T6 does not exceed the actual value, the safety factor to be used by designer is ~1.35 Tritium Production from Li-7 Prediction uncertainty in T7 ~ 5% (US) and ~-0.4% (JAERI) with standard deviation ~11% (US) and ~9% (JAERI) based on all calculations methods and measuring techniques To achieve the highest confidence level that calculated T7 does not exceed the actual value, the safety factor to be used by designer is ~1.35 (US) and 1.3 (JAERI)

Recent Experiments on Other Breeder Materials Single and Three Bed Layers TPR Experiment on Li 2 TiO 3 at FNS* * From T. Nishitani,et al., “Initial Results of Neutronics Experiments for Evaluation of Tritium Production Rate in Solid Breeding Blanket” 20th IEEE/NPSS (SOFE) October , 2003, San Diego, CA USA Concept of the Solid Breeding Blanket designed by JAERI First Wall Reduced Activation Ferritic Steel (F82H) Neutron Multiplier bed layer Breeder bed layer (Li 2 TiO 3 or Li 2 O) Cooling Water

A blanket assembly Shielding (Li 2 CO 3 ) Be F82H 1.6mm×10 F82H 1.0mm× Li 2 CO 3 (  13)1.23x Li/cm 3 40-% 6 Li 2 TiO 3 (  12)1.23x Li/cm 3 The assembly was enclosed in a cylindrical SS-316 reflector to shield the neutrons reflected by the experimental room walls and to simulate the incident neutron spectrum at the DEMO blanket. Three 12-mm thick 40% enriched 6 Li 2 TiO 3 layers with a thin F82H layer are set up between 50- and 100-mm thick layers of beryllium Detectors (NE213) T target 1372mm SS316 source reflector Be  1200mm 350mm  630mm Single and Three Bed Layers TPR Experiment on Li2TiO3 at FNS* (Cont’d) A blanket assembly Shielding (Li 2 CO 3 ) Be F82H 1.6mm×10 F82H 1.0mm× Li 2 CO 3 (  13)1.23x Li/cm 3 40-% 6 Li 2 TiO 3 (  12)1.23x Li/cm 3 The assembly was enclosed in a cylindrical SS-316 reflector to shield the neutrons reflected by the experimental room walls and to simulate the incident neutron spectrum at the DEMO blanket. Three 12-mm thick 40% enriched 6 Li 2 TiO 3 layers with a thin F82H layer are set up between 50- and 100-mm thick layers of beryllium Detectors (NE213) T target 1372mm SS316 source reflector Be  1200mm 350mm  630mm The experimental results were analyzed with the three-dimensional Monte Carlo transport codes MCNP-4B with JENDL-3.2, JENDL-FF, ENDF/B-VI and FENDL-2.0 nuclear data libraries.

Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance. Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance.

Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance. Bulk Shielding Experiment at FNG (Frascati, Italy) for ITER

Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance. Bulk Shielding Experiment at FNG (Frascati, Italy) for ITER Calculations based on MCNP/FENDL-1 (and also FENDL-2 and EFF-3) correctly predict n/gamma flux attenuation in a steel/water shield up to 1 m depth within ± 30% uncertainty, in bulk shield and in presence of streaming paths

Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance. US/JAERI Bulk Shielding Experiment of SS316/Water with and without a Simulated SC Magnet for ITER Assembly without SC magnet Zone Assembly with SC magnet Zone Seven layers of simulated water. 1 st water layer at 1.2 cm from front. SS316 layer that follows have thickness 2.4, 7.78, 7.48, 7.48, 12.56, Analysis: US: 175n-42G FENDL1/MG-1, 175n-42G ENDF/B-VI, DORT (R-Z). Shielded and unshielded data JAERI: JENDL-3.1 (J3DF) –MORSE-DD

Monte Carlo Analysis Distance from the assembly surface (mm) 1st breeding layer 2nd 3rd TPR The calculation of TPR is overestimation by 10% to 25% in this experiment. Average1.21 Average1. 09 Average1.12 C/E of the integrated TPR for three layers was about 1.15, which is a little bit larger than the design margin for the tritium breeding performance. US/JAERI Bulk Shielding Experiment of SS316/Water with and without a Simulated SC Magnet for ITER (Con’d) Large under estimation of the integrated spectrum at deep locations of 25% and 10–15%, respectively. The shielded MG data give better agreement with the experiment than the unshielded one, particularly at deep locations. The C/E values of gamma-ray heating obtained by the MG and MC data are similar and within ~20% of the experiment.

Experimental Validation of Shutdown Dose Rates inside ITER Cryostat* * From P. Batistoni,et al., “Experimental validation of shutdown dose rates calculations inside ITER cryostat”, Fusion Eng.& Design, (2001)

Experimental Validation of Shutdown Dose Rates inside ITER Cryostat* (Con’d) The shut down dose rate calculated by FENDL-2 nuclear data libraries is within ± 15% from a few days up to about 4 months of decay time

Streaming Experiments at FNG (Frascati, Italy) for ITER Shielding

Recommendation for Performing Neutronics R&D for ITER TBM Since neutronics R&D for ITER TBM are generic in nature, it is highly recommended to form two groups of experts in analysis and experimentation from all parties involved to: Identify and carefully scrutinize requirements for TBM neutronics R&D for all blanket concepts on the table for testing in ITER. This includes examining the state-of-the art measuring techniques and transport codes in each parties for any shortcomings, limitations, and possible improvements. Set a reference analytical and measuring technique tools against which each party can compare their own computational tools/measuring techniques.

Recommendation for Performing Neutronics R&D for ITER TBM (Cont'd) Examine the availability and schedule of all well-equipped and suited 14 MeV facilities located in each party’s homeland (e.g. FNS, FNG, etc) Draw a well-defined task assignment among neutronics experts from each party to undertake the identified R&D tasks with equitable burden-sharing. Define an effective mechanism to communicate with each test port “leader” and ITER central team It is highly recommended to redirect and redefine the IEA Collaboration on Fusion Neutronics to undertake the above responsibilities, since this collaboration already exists