[1] MARUYAMA I, KONTANI O, TAKIZAWA M, et al. Development of soundness assessment procedure for concrete members affected by neutron and gamma-ray irradiation［J］. J Adv Concr Technol, 2017, 15(9): 440-523.

[2] KAMBAYASHI D, SASANO H, SAWADA S, et al. Numerical analysis of a concrete biological shielding wall under neutron irradiation by 3D RBSM［J］. J Adv Concr Technol, 2020, 18(10): 618-632.

[3] BRUCK P M, ESSELMAN T C, ELAIDI B M, et al. Structural assessment of radiation damage in light water power reactor concrete biological shield walls［J］. Nucl Eng Des, 2019, 350: 9-20.

[4] FIELD K G, REMEC I, LE PAPE Y. Radiation effects in concrete for nuclear power plants-Part I: Quantification of radiation exposure and radiation effects［J］. Nucl Eng Des, 2015, 282: 126-143.

[5] GIORLA A, VAITOV M, LE PAPE Y, et al. Meso-scale modeling of irradiated concrete in test reactor［J］. Nucl Eng Des, 2015, 295: 59-73.

[6] HILSDORF H, KROPP J, KOCH H J. The effects of nuclear radiation on the mechanical properties of concrete［J］. Spec Publ, 1978, 55: 223-254.

[7] ISHIKAWA S, MARUYAMA I, TAKIZAWA M, et al. Hydrogen production and the stability of hardened cement paste under gamma irradiation［J］. J Adv Concr Technol, 2019, 17(12): 673-685.

[8] LE PAPE Y, FIELD K G, REMEC I. Radiation effects in concrete for nuclear power plants, Part II: Perspective from micromechanical modeling［J］. Nucl Eng Des, 2015, 282: 144-157.

[9] SASANO H, MARUYAMA I, SAWADA S, et al. Meso-scale modelling of the mechanical properties of concrete affected by radiation-induced aggregate expansion［J］. J Adv Concr Technol, 2020, 18(10): 648-677.

[10] LE PAPE Y. Structural effects of radiation-induced volumetric expansion on unreinforced concrete biological shields［J］. Nucl Eng Des, 2015, 295: 534-548.

[11] MURTY K L, CHARIT I. An introduction to nuclear materials: fundamentals and applications［M］. New Jersey: John Wiley & Sons, Ltd., 2013.

[12] KONTANI O, ICHIKAWA Y, ISHIZAWA A, et al. Irradiation effects on concrete structures［C］//Infrastructure Systems for Nuclear Energy. Chichester, UK: John Wiley & Sons, Ltd, 2013: 459-473.

[14] ESSELMAN T, BRUCK P, ROSSEEL T. Light water reactor sustainability program［R］. Expected condition of concrete exposed to radiation at age 80 years of reactor operation, ORNL/TM-2018/769, Tennessee: Oak Ridge National Laboratory, 2018: 15-29.

[15] MARUYAMA I, HABA K, SATO O, et al. A numerical model for concrete strength change under neutron and gamma-ray irradiation［J］. J Adv Concr Technol, 2016, 14(4): 144-162.

[16] REMEC I. Light water reactor sustainability program［R］. Radiation environment in concrete biological shields of nuclear power plants, TWE-LPI-001, Tennessee: Oak Ridge National Laboratory, 2013: 6-10.

[17] REMEC I, ROSSEEL T M, FIELD K G, et al. Characterization of radiation fields in biological shields of nuclear power plants for assessing concrete degradation［J］. EPJ Web Conf, 2016, 106: 02002.

[18] JING Y X, XI Y P. Long-term neutron radiation levels in distressed concrete biological shielding walls［J］. J Hazard Mater, 2019, 363: 376-384.

[20] LE PAPE Y, SANAHUJA J, ALSAID M H F. Irradiation-induced damage in concrete-forming aggregates: Revisiting literature data through micromechanics［J］.Mater Struct, 2020, 53(3): 1-35.

[21] DENISOV A. Radiation changes of concrete aggregates under the influence of gamma radiation［J］. Mag Civ Eng, 2020, 96: 94-109.

[22] BRINKMAN J A. Production of atomic displacements by high-energy particles［J］. Am J Phys, 1956, 24(4): 246-267.

[23] ANOOP KRISHNAN N M, LE PAPE Y, SANT G, et al. Disorder- induced expansion of silicate minerals arises from the breakage of weak topological constraints［J］. J Non Cryst Solids, 2021, 564: 120846.

[24] SILVA C M, ROSSEEL T M, KIRKEGAARD M C. Radiation- induced changes in quartz, A mineral analog of nuclear power plant concrete aggregates［J］. Inorg Chem, 2018, 57(6): 3329-3338.

[25] OKADA N, OHKUBO T, MARUYAMA I, et al. Characterization of irradiation-induced novel voids in α-quartz［J］. AIP Adv, 2020, 10(12): 125212.

[26] VAITOV M, TEMBERK P, ROSSEEL T M. Fuzzy logic model of irradiated aggregates［J］. Neural Netw World, 2019, 29(1): 1-18.

[27] LUU V N, MURAKAMI K, SAMOUH H, et al. Swelling of alpha-quartz induced by MeV ions irradiation: critical dose and swelling mechanism［J］. J Nucl Mater, 2020, 539: 152266.

[28] PRIMAK W. Fast-neutron-induced changes in quartz and vitreous silica［J］. Phys Rev, 1958, 110(6): 1240-1254.

[29] MA C, FITZGERALD J D, EGGLETON R A, et al. Analytical electron microscopy in clays and other phyllosilicates: Loss of elements from a 90-nm stationary beam of 300-keV electrons［J］. Clays Clay Miner, 1998, 46(3): 301-316.

[30] MARUYAMA I, MUTO S. Change in relative density of natural rock minerals due to electron irradiation［J］. J Adv Concr Technol, 2016, 14(11): 706-716.

[31] ALSAID M H. Toward the understanding of irradiation effects on concrete: the irradiated minerals, aggregates, and concrete database(in Chinese, dissertation). Tennessee: University of Tennessee, 2017.

[32] PIGNATELLI I, KUMAR A, FIELD K G, et al. Direct experimental evidence for differing reactivity alterations of minerals following irradiation: the case of calcite and quartz［J］. Sci Rep, 2016, 6: 20155.

[33] SEYDOUX-GUILLAUME A M, MONTEL J M, WIRTH R, et al. Radiation damage in diopside and calcite crystals from uranothorianite inclusions［J］. Chem Geol, 2009, 261(3-4): 318-332.

[34] SILVA C M, ROSSEEL T M, HOLLIDAY K S. Radiation-induced changes in single crystal calcite and dolomite: mineral analogues of light water reactor, nuclear power plant concrete aggregates［J］. J Phys Chem C, 2022, 126(1): 634-646.

[35] ZHOU S, JU J W. The damage and healing of quartz under radiation at high temperatures［J］. Int J Damage Mech, 2020, 29(6): 923-942.

[37] LE PAPE Y, ALSAID M H F, GIORLA A B. Rock-forming minerals radiation-induced volumetric expansion-revisiting literature data［J］. J Adv Concr Technol, 2018, 16(5): 191-209.

[38] ANOOP KRISHNAN N M, LE PAPE Y, SANT G, et al. Effect of irradiation on silicate aggregates’ density and stiffness［J］. J Nucl Mater, 2018, 512: 126-136.

[39] ANOOP KRISHNAN N M, RAVINDER R, KUMAR R, et al. Density-stiffness scaling in minerals upon disordering: Irradiation vs. vitrification［J］. Acta Mater, 2019, 166: 611-617.

[40] WANG B, ANOOP KRISHNAN N M, YU Y T, et al. Irradiation-induced topological transition in SiO2: Structural signature of networks' rigidity［J］. J Non Cryst Solids, 2017, 463: 25-30.

[41] KHMUROVSKA Y, TEMBERK P. Catalogue of radiation-induced damage of rock aggregates identified by RBSM analysis［J］. J Adv Concr Technol, 2021, 19(6): 668-686.

[42] KHMUROVSKA Y, TEMBERK P. RBSM-based model for prediction of radiation-induced volumetric expansion of concrete aggregates［J］. Constr Build Mater, 2021, 294: 123553.

[43] LUU V N, MURAKAMI K, SAMOUH H, et al. Changes in properties of alpha-quartz and feldspars under 3 MeV Si-ion irradiation［J］. J Nucl Mater, 2021, 545: 152734.

[44] ROSSEEL T M, GUSSEV M N, MORA L F. The Effects of Neutron Irradiation on the Mechanical Properties of Mineral Analogues of Concrete Aggregates［C］//JACKSON J, PARAVENTI D, WRIGHT M. Proceedings of the 18th International Conference on Environmental Degradation of Materials in Nuclear Power Systems - Water Reactors. Cham: Springer, 2019: 1367-1377.

[45] ELLEUCH L, DUBOIS F, RAPPENEAU J. Effects of neutron radiation on special concretes and their components［J］. Spec. Publ., 1972, 34: 1071-1108.

[47] KRISHNAN N M A, WANG B, SANT G, et al. Revealing the effect of irradiation on cement hydrates: evidence of a topological self- organization［J］. ACS Appl Mater Interfaces, 2017, 9(37): 32377-32385.

[48] ZHOU Y, CHEN Y, JIN M, et al. Insights at the neutron irradiation-induced structural homogenization effect of calcium silicate hydrates and degradation mechanism of mechanical properties: A molecular dynamics study［J］. J Sustain Cem Based Mater, 2023, 12(2): 116-128.

[49] MARUYAMA I, OHKUBO T, HAJI T, et al. Dynamic microstructural evolution of hardened cement paste during first drying monitored by 1H NMR relaxometry［J］. Cem Concr Res, 2019, 122: 107-117.

[50] MARUYAMA I, RYME J. Temperature dependency of short-term length-change and desorption isotherms of matured hardened cement［J］. J Adv Concr Technol, 2019, 17(5): 188-194.

[51] TAJUELO RODRIGUEZ E, HUNNICUTT W A, MONDAL P, et al. Examination of gamma-irradiated calcium silicate hydrates. Part I: Chemical-structural properties［J］. J Am Ceram Soc, 2020, 103(1): 558-568.

[52] YIN C, DANNOUX-PAPIN A, HAAS J, et al. Influence of calcium to silica ratio on H2 gas production in calcium silicate hydrate［J］. Radiat Phys Chem, 2019, 162: 66-71.

[53] HUNNICUTT W, RODRIGUEZ E T, MONDAL P, et al. Examination of gamma-irradiated calcium silicate hydrates. part II: Mechanical properties［J］. J Adv Concr Technol, 2020, 18(10): 558-570.

[54] CHARTIER D, SANCHEZ-CANET J, BESSETTE L, et al. Influence of formulation parameters of cement based materials towards gas production under gamma irradiation［J］. J Nucl Mater, 2018, 511: 183-190.

[55] DENISOV A, ALEKSANDR D. Analytical description of the hydrogen evolution from concrete under the effect of gamma radiation［J］. IOP Conf Ser Mater Sci Eng, 2020, 869(3): 32013-32023.

[56] ROBIRA M, HILLOULIN B, LOUKILI A, et al. Multi-scale investigation of the effect of γ irradiations on the mechanical properties of cementitious materials［J］. Constr Build Mater, 2018, 186: 484-494.

[57] HILLOULIN B, ROBIRA M, LOUKILI A. Coupling statistical indentation and microscopy to evaluate micromechanical properties of materials: application to viscoelastic behavior of irradiated mortars［J］. Cem Concr Compos, 2018, 94: 153-165.

[59] MARUYAMA I, NISHIOKA Y, IGARASHI G, et al. Microstructural and bulk property changes in hardened cement paste during the first drying process［J］. Cem Concr Res, 2014, 58: 20-34.

[60] RECHES Y. A multi-scale review of the effects of gamma radiation on concrete［J］. Results Mater, 2019, 2: 100039.

[61] POTTS A, LEAY L. Evidence for pore water composition controlling carbonate morphology in concrete and the further effect of gamma radiation［J］. Constr Build Mater, 2021, 275: 122049.

[62] JING Y X, XI Y P. Theoretical modeling of the effects of neutron irradiation on properties of concrete［J］. J Eng Mech, 2017, 143(12): 04017137.

[63] TORRENCE C E, GIORL A B, LI Y J, et al. MOSAIC: an effective FFT-based numerical method to assess aging properties of concrete［J］. J Adv Concr Technol, 2021, 19(2): 149-167.

[64] LI Y, LE PAPE Y, TAJUELO RODRIGUEZ E, et al. Microstructural characterization and assessment of mechanical properties of concrete based on combined elemental analysis techniques and Fast-Fourier transform-based simulations［J］. Constr Build Mater, 2020, 257: 119500.

[65] CHEN F, SANAHUJA J, BARY B, et al. Effects of internal swelling on residual elasticity of a quasi-brittle material through a composite sphere model［J］. Int J Mech Sci, 2022, 229: 107390.

[66] GIORLA A B, LE PAPE Y, DUNANT C F. Computing creep-damage interactions in irradiated concrete［J］. J Nanomech Micromech, 2017, 7(2): 04017001.

[67] CHEN F, GAO C, JIN L, et al. Numerical investigations on the viscoelastic-damage behaviors of RIVE-induced concrete［J］. Int J Mech Sci, 2023, 239: 107899.

[68] LE PAPE Y, GIORLA A, SANAHUJA J. Combined effects of temperature and irradiation on concrete damage［J］. J Adv Concr Technol, 2016, 14(3): 70-86.

[71] ZHANG Y, ZHOU Q, JU J W, et al. New insights into the mechanism governing the elasticity of calcium silicate hydrate gels exposed to high temperature: A molecular dynamics study［J］. Cem Concr Res, 2021, 141: 106333.

[72] JING Y X. Deterioration of multi-functional cementitious materials in nuclear power plants(in Chinese, dissertation). Boulder: University of Colorado Boulder, 2018.