1 |
Core neutronic characterization of a large molten-salt cooled thorium-based solid fuel fast reactor Peng Y, Zhu GF, Zou Y, Liu SJ, Xu HJ International Journal of Energy Research, 44(10), 8062, 2020 |
2 |
Oxygen reduction reaction with efficient, metal-free nitrogen, fluoride-codoped carbon electrocatalysts derived from melamine hydrogen fluoride salt Zhang HJ, Yao SW, Geng J, Ma ZF, Yang JH Journal of Colloid and Interface Science, 535, 436, 2019 |
3 |
Experimental study on the heat transfer characteristics of fluoride salt in the new conceptual passive heat removal system of molten salt reactor Liu MH, Zhang DL, Wang CL, Qiu SZ, Su GH, Tian WX International Journal of Energy Research, 42(4), 1635, 2018 |
4 |
Thermodynamic assessment of the (LiF + UF3) and (NaF + UF3) systems Beilmann M, Benes O, Konings RJM, Fanghanel T Journal of Chemical Thermodynamics, 57, 22, 2013 |
5 |
Nitriding of 316 stainless steel in molten fluoride salt by an electrochemical technique Watanabe T, Kondo M, Sagara A Electrochimica Acta, 58, 681, 2011 |
6 |
Thermodynamic evaluation and optimization of the (LiF plus NaF + KF + MgF2 + CaF2 + SrF2) system Renaud E, Robelin C, Heyrman M, Chartrand P Journal of Chemical Thermodynamics, 41(5), 666, 2009 |
7 |
Thermodynamic evaluation of the (LiF + NaF + BeF2 + PuF3) system: An actinide burner fuel Benes O, Konings RJM Journal of Chemical Thermodynamics, 41(10), 1086, 2009 |
8 |
High-temperature liquid-fluoride-salt closed-Brayton-cycle solar power towers Forsberg CW, Peterson PF, Zhao HH Journal of Solar Energy Engineering-Transactions of The ASME, 129(2), 141, 2007 |
9 |
Electrolytic partial fluorination of organic compounds. Part 34. Regioselective anodic fluorination of benzyl thiocyanate and its derivatives Hou YK, Higashiya S, Fuchigami T Electrochimica Acta, 45(18), 3005, 2000 |
10 |
Electrochemical separation of aluminum from uranium for research reactor spent nuclear fuel applications Slater SA, Raraz AG, Willit JL, Gay EC Separation and Purification Technology, 15(3), 197, 1999 |