Transmutation of Long-Lived Nuclear Wastes
June 1-6, 2014 ARIS2014 Transmutation of Long-lived Nuclear Wastes Hiroyuki Oigawa Office of Strategic Planning (Nuclear Science and Engineering Directorate, and J-PARC Center) Japan Atomic Energy Agency 1 Background Concern to radioactive waste management has been increasing in Japan. Transmutation technology for long-lived nuclides is drawing the attention from public, media and politicians. JAEA (former JAERI and PNC/JNC) has been studying this technology for more than 20 years. The Ministry of Education, Culture, Sports Science and Technology (MEXT) in Japan has launched a Working Party to review Partitioning and Transmutation Technology in August, 2013, and issued an interim report in November, 2013. 2 Major Long-lived Nuclides in Spent Nuclear Fuel 0.7B 47 10kg U-238 4.5B 45 930kg Minor actinides (MA) Trans-uranic elements (TRU) Dose Actinides (per 1tHM) U-235 Half-life coefficient Nuclide (year) (μSv/kBq) Mass (per 1tHM) Pu-238 87.7 230 0.3kg Pu-239 24k 250 6kg Pu-240 6.6k 250 3kg Pu-241 14.3 4.8 1kg Dose Half-life coefficient Nuclide (year) (μSv/kBq) Dose Mass Fission products (FP) Dose Half-life coefficient Nuclide (year) (μSv/kBq) Half-life coefficient Nuclide (year) (μSv/kBq) Mass (per 1tHM) Se-79 0.3M 2.9 6g Sr-90 28.8 28 0.6kg Zr-93 1.53M 1.1 1kg Tc-99 0.21M 0.64 1kg Pd-107 6.5M 0.037 0.3kg Sn-126 0.23M 4.7 30g I-129 15.7M 110 0.2kg Cs-135 2.3M 2.0 0.5kg Cs-137 30.1 13 1.5kg Mass (per 1tHM) Np-237 2.14M 110 0.6kg Am-241 432 200 0.4kg Am-243 7.4k 200 0.2kg Cm-244 18.1 120 60g Dose Coefficient: Committed dose (Sv) per unit intake (Bq), indicating the magnitude of influence of radioactivity to human body. α-activity is more influential than β,γ-activity. 3 Partitioning and Transmutation (P&T) Spent fuel Reprocessing FP、MA Partitioning Recycle U、Pu Geological disposal (Glass waste form) Conventional scheme MA (Np, Am, Cm) P&T technology Transmutation by ADS and/or FR PGM (Ru, Rh, Pd) Utilization and/or disposal (Example) Heat generator (Sr, Cs) Remaining elements MA: FP: PGM: FR: ADS: Minor Actinides Fission Products Platinum Group Metal Fast Reactor Accelerator Driven System Geological disposal after cooling and/or utilization (Calcined waste form) Geological disposal (high-density glass waste form) 4 Reduction of Radiological Toxicity by P&T Radiological Toxicity: Amount of radioactivity weighted by dose coefficient of each nuclide. 1.E+09 使用済燃料 Spent fuel (1t) 高レベル廃棄物 High-level waste 分離変換導入 MA transmutation 天然ウラン9トン Natural uranium (9t) toxicity (Sv) Radiological 潜在的有害度(Sv) 1.E+08 1.E+07 1.E+06 • 9t of natural uranium (NU) is raw material of 1t of low-enriched uranium including daughter nuclides. Time period to decay below the NU level: 1.E+05 • Spent fuel 1.E+04 100,000y ↓ • High-level waste 5,000y ↓ • MA transmutation 300y Reduction 1.E+03 1.E+02 1.E+01 • Normalized by 1t of spent fuel. Reduction 1.E+02 1.E+03 1.E+04 1.E+05 Time after reprocessing (Year) 処理後経過時間(年) 1.E+06 1.E+07 5 How to Transmute MA and LLFP Example of fission reaction of MA Np-237 Neutron Mo-102 Tc-102 (T1/2=11min.) β-ray (T1/2=5s) Ru-102 β -ray (stable) (T1/2=2.14M yr.) Fission reaction (n, f) Note: 10% or less of FPs are Long-lived ones. Fast neutrons (> 1MeV) Neutron β -ray I-133 (T1/2=21hr.) Xe-133 β -ray (T1/2=5d) Cs-133 (stable) Example of capture reaction of LLFP Xe-130 I-130 Capture reaction (T1/2=12hr.) (T1/2=15.7M yr.) (n, γ) I-129 Neutron (stable) T1/2: Half life Β-ray Thermal neutrons Example of (n, 2n) reaction of LLFP Sn-126 Neutron (T1/2=230k yr.) High energy neutrons (> 10MeV) (n, 2n) reaction Sn-125 Sb-125 Te-125 (T1/2=9.6d) (T1/2=2.8yr.) (stable) Β-ray Β-ray 6 Cross Sections of Neutron-induced Reaction : Am-241 Total Scattering Capture Fission inelastic Chain reactions of fission by fast neutrons are advantageous for transmutation of MA. 7 Examples of “Reduced Half-life” “Reduced Half-life” can be written as T1/2 = ln2 / (φ·σ ) , if there is no competitive reaction nor production reaction, where φ is neutron flux and σ is reaction cross section. Nuclide Half-life Reaction (year) Am-241 432 Tc-99 211k Sn-126 230k I-129 15.7M Cs-135 2.3M Cs-137 30.1 n,f n,γ n,2n n,γ n,2n n,γ n,2n n,γ n,2n n,γ n,2n Neutron energy Cross section σ (JENDL-4.0) (barn=10-24cm2) Fiss. Spec. Maxwell 14MeV Maxwell 14MeV Maxwell 14MeV Maxwell 14MeV Maxwell 14MeV 1.378 23.68 1.233 0.09 1.686 30.33 1.464 8.304 1.61 0.27 1.549 Neutron flux φ (/cm2/s) 1013 1014 1015 Reduced half-life (year) 1,600 160 16 93 9.3 0.93 1,800 180 18 24,000 2,400 240 1300 130 13 72 7.2 0.72 1,500 150 15 260 26 2.6 1,400 140 14 8,100 810 81 1,400 140 14 Condition of realistic transmutation: φ·σ >1015 (barn/cm2/s) 8 Accelerator Driven System (ADS) for MA Transmutation Proton beam Max.30MW Super-conducting LINAC 100MW To accelerator 800MW 170MW Fission energy To grid MA: Minor Actinides LBE: Lead-Bismuth Eutectic Spallation target (LBE) 270MWPower generation Transmutation by ADS Utilizing chain reactions in subcritical state Fission neutrons Short-lived or stable nuclides MA-fueled LBEcooled subcritical core Proton Spallation target Fast neutrons Characteristics of ADS: Long-lived nuclides (MA) • Chain reactions stop when the accelerator is turned off. • LBE is chemically stable. High safety can be expected. • High MA-bearing fuel can be used. MA from 10 LWRs can be transmuted. 9 ADS Proposed by JAEA Movable support • • • • • • • Proton beam : 1.5GeV Spallation target : Pb-Bi Coolant : Pb-Bi Max. keff = 0.97 Thermal output : 800MWt MA initial inventory : 2.5t Fuel composition : (MA +Pu)Nitride + ZrN • Transmutation rate : 10%MA / Year • 600EFPD, 1 batch Bending magnet Proton beam Fuel exchanger Beam duct Primary pump Steam generator Spallation target Reactor vessel Subcritical core Beam window Core support Conceptual view of 800 MWth LBE-cooled ADS 10 Components of Double-strata Fuel Cycle Concept U [752t/y] Pu [8t/y] [7t/y] Recovered actinides Spent fuel Reprocessing [8t/y] [1t/y] Fission products [4t/y] [5t/y] Remaining elements Accelerator Driven System (ADS) Sr-Cs Dedicated Fuel fabrication transmutation fuel process [1t/y] [8t/y] PGM Reprocessing [800t/y] Partitioning process Fission Products (FP) [39t/y] Minor Actinides (MA) [1t/y] Minor actinides (MA) Spent fuel Scope of P&T [30t/y] Optimization by utilization / Disposal after cooling Final disposal PGM: Platinum Group Metal 11 Technical Issues for ADS •Accelerator • R&D of SC-LINAC • Reliability Assessment Construction and operation of J-PARC accelerator •Structure •Design study on reactor vessel, beam duct, quakeproof structure, etc. •Fuel •Fabrication, irradiation and reprocessing tests J-PARC: Japan Proton Accelerator Research Complex TEF-P: Transmutation Physics Experimental Facility TEF-T: ADS Target Test Facility SC-LINAC: Superconducting LINAC •R&D of Pb-Bi technology Construction of TEF-T in J-PARC •Spallation Target, Material •Operation of Pb-Bi system •Experiments in existing facilities and analyses Construction of TEF-P in J-PARC • Reactor Physics • Control of Subcritical System 12 Reliability of Accelerator Number of beam trips per year (7,200 hours) Beam trip rate (times/year) Acceptable trip rate We are comparing the trip rate estimated from data of existing accelerators and the maximum acceptable trips to keep the integrity of the ADS components. Short beam trip (<10s) can meet the criteria. Longer beam trip should be decreased by: Reducing the frequency of trips and Reducing the beam trip duration Estimation from experiences LANSCE +KEKB J-PARC 0-10s 10s – 5min. >5min. Beam trip duration 13 9 1 φ4610 ビーム導入管 Cylinder r3,i Xi(=Xo) θt Transient part ・Suffix i: inner, o: outer 490oC ビーム窓 Temperature o 外表面温度 Of beam window 470 C t3 (2700) Partition wall Flow control nozzle 450oC t3 r2,o 3390 Temperatur 温度分布 e Outer surface 6450 r3,o 1030 High temperature Corrosion and erosion by LBE Pressure difference between vacuum and LBE (~0.8MPa) Irradiation by protons and neutrons 1390 1890 Beam duct support Proton beam Beam duct Beam window Core barrel Core region Reflector Target region 1000 Beam window is subjected to severe conditions: 5250 Design of Beam Window内 筒 θ θf t2 r1,o t2 Coolant flow Zi (Zo) zoff r2,i Constants θf = 60° r1,i = 200mm r3,i = 225mm r3,o = 235mm Support structure Transient part r1,i z Top part t1 x t1 (unit: Kelvin) Temperature at the outer surface of the window can be less than 500ºC. Buckling failure can be avoided by a factor of safety (FS)=3. The life time of the beam window should be evaluated from viewpoints of corrosion and irradiation. necessity of irradiation data base. 14 Accuracy of Neutronics Design JAEA J3.3 1.01 JAEA J3.2 1 JAEA J4.0 241Am 0.99 k-eff, JENDL J4.0 0.98 207Pb 206Pb 0.97 0.96 0.95 J3.2, J3.3 0.94 0.93 BOC EOC Benchmark calculation for 800MWt ADS for BOC and EOC. (Left: Comparison between JENDL-4.0 and JENDL-3.3, Right: Nuclide-wise contribution for differences in k-eff) There is 2% difference in k-eff between JENDL-4.0 and JENDL-3.2, which is too large to design ADS. necessity of integral validation of nuclear data 15 Japan Proton Accelerator Research Complex: J-PARC Jan. 28, 2008 Hadron Experimental Facility 50 GeV Synchrotron Materials and Life Science Experimental Facility To neutrino detector 3 GeV Synchrotron Site for Transmutation Experimental Facility LINAC 16 Transmutation Experimental Facility (TEF) of J-PARC Transmutation Physics Experimental Facility: TEF-P ADS Target Test Facility:TEF-T Purpose: To investigate physics properties of subcritical reactor with low power, and to accumulate operation experiences of ADS. Licensing: Nuclear reactor: (Critical assembly) Proton beam: 400MeV-10W Thermal power: <500W Purpose: To research and develop a spallation target and related materials with highpower proton beam. Licensing: Particle accelerator Proton beam: 400MeV-250kW Target: Lead-Bismuth Eutectic (LBE, Pb-Bi) Multi-purpose Irradiation Area Critical Assembly Pb-Bi Target Proton Beam 17 International Collaboration with MYRRHA ADS without MA fuel (LBE coolant, Accelerator, Operation of ADS) Power ADS Transmutation plant Experimental ADSMYRRHA 30MW-beam, 800MWth ・Transmute 250kg of MA annually ~2.4MW-beam, 50~100MWth ・Engineering feasibility of ADS and fuel irradiation Reactor physics of MA transmutation system and material development for spallation target material Advanced material for beam window KUCA Core FFAG Accelerator Ion Source Proton Beam Target Subcritical Reactor KUCA FFAG Acc. Magnets TEF in J-PARC 250kW-beam ・LBE target technology ・Reactor physics of transmutation system TEF in J-PARC MYRRHA Purpose R&D for elemental technology (LBE target, Reactor physics) Fuel irradiation, Accumulation of operation experience of ADS Power 250kW-beam TEF-P : 500W (max.) 2.4MW-beam Power : 50~100MWth MA Mock-up experiment of transmutation system with massive MA (kg order) Irradiation experiment with small amount of MA Basic research (LBE loop test, KUCA experiments) 2010 2020 2030 2050 year 18 Working Party to Review Partitioning and Transmutation Technology The Ministry of Education, Culture, Sports Science and Technology (MEXT) in Japan has launched a Working Party to review Partitioning and Transmutation Technology in August, 2013. An interim report was issued in November, 2013. Key Descriptions: To reduce the burden of HLW management, it is expected that flexibility in future political decision is extended by showing possibilities of new concepts of back-end with high social receptivity. The ADS Target Test Facility (TEF-T) is being proposed under J-PARC to verify the feasibility of the beam window. It is appropriate to shift the R&D of the facility to the next stage. The Transmutation Physics Experimental Facility (TEF-P) is being proposed under J-PARC to overcome difficulties in reactor physics issues such as for a subcritical core and an MA-loaded one. Since this facility is proposed as a nuclear reactor, the safety review by the new regulation is to be applied. With taking care of this point, it is appropriate to shift the R&D of the facility to the next stage. For MYRRHA Program, it is appropriate to proceed with negotiation about JAEA’s participation at a reasonable level and mutual collaboration with Belgium and other relevant countries. Progress of the development should be checked according to its stage. 19 Concluding Remarks ADS provides us a possibility to flexibly cope with the waste management in various situations of nuclear power. R&D on ADS and its compact fuel cycle are under way in JAEA, and we are proposing the Transmutation Experimental Facility as the Phase-II of J-PARC. To overcome various technical challenges for this technology, the international collaboration is of great importance. 20
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