Transition to thorium fuel cycle on a heavy water moderated molten salt reactor by using low enrichment uranium
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[1] Xiangzhou Cai,et al. Ex‐core transition to thorium cycle in a small modular heavy‐water moderated molten salt reactor with unchanged concentration of heavy metal nuclides in the fuel salt , 2021, International Journal of Energy Research.
[2] Jian-Hui Wu,et al. Preliminary analysis of fuel cycle performance for a small modular heavy water-moderated thorium molten salt reactor , 2020, Nuclear Science and Techniques.
[3] T. Xiao,et al. Methodology development and application of X-ray imaging beamline at SSRF , 2020, Nuclear Science and Techniques.
[4] J. Křepel,et al. The EQL0D fuel cycle procedure and its application to the transition to equilibrium of selected molten salt reactor designs , 2020 .
[5] Xiangzhou Cai,et al. Nuclear non‐proliferation review and improving proliferation resistance assessment in the future , 2020, International Journal of Energy Research.
[6] Xiangzhou Cai,et al. Transition to thorium fuel cycle in a small modular molten salt reactor based on a batch reprocessing mode , 2020 .
[7] Xiangzhou Cai,et al. A novel concept for a molten salt reactor moderated by heavy water , 2019, Annals of Nuclear Energy.
[8] Guifeng Zhu,et al. Preliminary study on TRUs utilization in a small modular Th-based molten salt reactor (smTMSR) , 2018, Nuclear Engineering and Design.
[9] Xiangzhou Cai,et al. 149Sm evolution behavior in a small modular molten salt reactor , 2018, Annals of Nuclear Energy.
[10] Jianhui Wu,et al. Transition to thorium fuel cycle for TMSR , 2018 .
[11] E. Hoffman,et al. Advanced Fuel Cycle Cost Basis – 2017 Edition , 2017 .
[12] Xiangzhou Cai,et al. Possible scenarios for the transition to thorium fuel cycle in molten salt reactor by using enriched uranium , 2017 .
[13] Xiangzhou Cai,et al. Transition toward thorium fuel cycle in a molten salt reactor by using plutonium , 2017 .
[14] Chen Guo,et al. Flow effect on 135I and 135Xe evolution behavior in a molten salt reactor , 2017 .
[15] Jeffrey J. Powers,et al. Molten salt reactor neutronics and fuel cycle modeling and simulation with SCALE , 2017 .
[16] Xiangzhou Cai,et al. Minor actinide incineration and Th-U breeding in a small FLiNaK Molten Salt Fast Reactor , 2017 .
[17] O. Chvála,et al. Comparative economic analysis of the Integral Molten Salt Reactor and an advanced PWR using the G4-ECONS methodology , 2017 .
[18] Chenggang Yu,et al. Optimization of temperature coefficient and breeding ratio for a graphite-moderated molten salt reactor , 2015 .
[19] Lie-Wen Chen,et al. Constraints on the skewness coefficient of symmetric nuclear matter within the nonlinear relativistic mean field model , 2014, 1402.4242.
[20] M. Allibert,et al. Towards the thorium fuel cycle with molten salt fast reactors , 2014 .
[21] S. Ohki,et al. Enhancement of proliferation resistance properties of commercial FBRs by material barriers , 2014 .
[22] Samuel E. Bays,et al. Technology Insights and Perspectives for Nuclear Fuel Cycle Concepts , 2010 .
[23] Jun Li,et al. The sensitivity of fuel cycle performance to separation efficiency , 2010 .
[24] Materials Section,et al. Spent fuel reprocessing options , 2008 .
[25] R. Brissot,et al. Optimized Transition from the Reactors of Second and Third Generations to the Thorium Molten Salt Reactor , 2007 .
[26] Materials Section. Thorium fuel cycle : potential benefits and challenges , 2005 .
[27] A. Billebaud,et al. Potential of thorium molten salt reactorsdetailed calculations and concept evolution with a view to large scale energy production , 2005 .
[28] J. Lamarsh. Introduction to Nuclear Engineering , 1975 .
[29] R. C. Robertson,et al. CONCEPTUAL DESIGN STUDY OF A SINGLE-FLUID MOLTEN-SALT BREEDER REACTOR. , 1971 .