[1] LYNCH S P.Hydrogen embrittlement and liquid-metal embrittlement in nickel single crystals[J].Scripta Metallurgica,1979,13(11):1051-1056.
[2] ORIANI R A,JOSEPHIC P H.Equilimrium aspects of hydrogen-induced cracking of steels[J].Acta Metallurgica,1974,22(9):1065-1074.
[3] 封辉,池强,吉玲康,等.管线钢氢脆研究现状及进展[J].腐蚀科学与防护技术,2017,29(3):318-322.
FENG Hui,CHI Qiang,JI Lingkang,et al.Research and development of hydrogen embrittlement of pipeline steel[J].Corrosion Science and Protetion Technology,2017,29(3):318-322.
[4] ROBERTSON I M,SOFRONIS P,NAGAO A,et al.Hydrogen embrittlement understood[J].Metallurgical and Materials Transactions B,2015,46(3):1085-1103.
[5] ROBERTSON I M,BIRNBAUM H K,SOFRONIS P.Hydrogen effects on plasticity[J].Dislocations in Solids,2009,15:249-293.
[6] 赵晓丽,张永健,邵成伟,等.两相区退火处理冷轧0.1C-5Mn中锰钢的氢脆敏感性[J].金属学报,2018,54(7):1031-1041.
ZHAO Xiaoli,ZHANG Yongjian,SHAO Chengwei,et al.Hydrogen embrittlement of intercritically annealed cold-rolled 0.1C-5Mn steel[J].Acta Metallurgica Sinica,2018,54(7):1031-1041.
[7] HAYWARD E,FU Chuchun.Interplay between hydrogen and vacancies in α-Fe[J].Physical Review B,2013,87(17):174103.
[8] XING Xiao,CHEN Weixing,ZHANG Hao.Atomistic study of hydrogen embrittlement during cyclic loading:quantitative model of hydrogen accumulation effects[J].International Journal of Hydrogen Energy,2017,42(7):4571-4578.
[9] 胡茹萌,杜敏.海水中阴极极化对X80钢应力腐蚀及氢脆敏感性的影响[J].装备环境工程,2018,15(3):1-8.
HU Rumeng,DU Min.Effects of Cathodic polarization on stress corrosion cracking and hydrogen embrittlement of X80 steel in seawater[J].Equipment Environmental Engineering,2018,15(30):1-8.
[10] 张智,刘志伟,谢玉洪,等.井筒载荷-腐蚀耦合作用对碳钢套管服役寿命的影响[J].石油学报,2017,38(3):342-347.
ZHANG Zhi,LIU Zhiwei,XIE Yuhong,et al.Influence of shaft load-corrosion coupling on the service life of carbon steel casing pipe[J].Acta Petrolei Sinica,2017,38(3):342-347.
[11] 董亮,姜子涛,杜艳霞,等.地铁杂散电流对管道牺牲阳极的影响及防护[J].石油学报,2016,37(1):117-124.
DONG Liang,JIANG Zitao,DU Yanxia,et al.Influence and protection of metro stray current on pipeline sacrificial anode[J].Acta Petrolei Sinica,2016,37(1):117-124.
[12] CHEN Weixing,SUTHERBY R L.Crack growth behavior of pipeline steel in near-neutral pH soil environments[J].Metallurgical and Materials Transactions A,2007,38(6):1260-1268.
[13] YU M,CHEN W,KANIA R,et al.Underload-induced crack growth behaviour of minor cycles of pipeline steel in near-neutral pH environment[J].Fatigue & Fracture of Engineering Materials & Structures,2015,38(6):681-692.
[14] SONG Jun,CURTIN W A.A nanoscale mechanism of hydrogen embrittlement in metals[J].Acta Materialia,2011,59(4):1557-1569.
[15] 张鹏,彭杨.考虑随机变量相关性的腐蚀管道失效概率[J].石油学报,2016,37(10):1293-1301.
ZHANG Peng,PENG Yang.Failure probability of corroded pipeline considering random variables correlation[J].Acta Petrolei Sinica,2016,37(10):1293-1301.
[16] CHEN W,KANIA R,WORTHINGHAM R,et al.Transgranular crack growth in the pipeline steels exposed to near-neutral pH soil aqueous solutions:the role of hydrogen[J].Acta Materialia,2009,57(20):6200-6214.
[17] YU Mengshan,XING Xiao,ZHANG Hao,et al.Corrosion fatigue crack growth behavior of pipeline steel under underload-type variable amplitude loading schemes[J].Acta Materialia,2015,96:159-169.
[18] THOMAS J P,WEI R P.Corrosion fatigue crack growth of steels in aqueous solutions I:experimental results and modeling the effects of frequency and temperature[J].Materials Science and Engineering:A,1992,159(2):205-221.
[19] TAKETOMI S,MATSUMOTO R,MIYAZAKI N.Atomistic study of hydrogen distribution and diffusion around a {112}<111> edge dislocation in alpha iron[J].Acta Materialia,2008,56(15):3761-3769.
[20] MATSUMOTO R,TAKETOMI S,MATSUMOTO S,et al.Atomistic simulations of hydrogen embrittlement[J].International Journal of Hydrogen Energy,2009,34(23):9576-9584.
[21] SONG Jun,CURTIN W A.Atomic mechanism and prediction of hydrogen embrittlement in iron[J].Nature Materials,2013,12(2):145-151.
[22] DMYTRAKH I M,SMIYAN O D,SYROTYUK,et al.Relationship between fatigue crack growth behaviour and local hydrogen concentration near crack tip in pipeline steel[J].International Journal of Fatigue,2013,50:26-32.
[23] WANG Shuai,MARTIN M L,SOFRONIS P,et al.Hydrogen-induced intergranular failure of iron[J].Acta Materialia,2014,69:275-282.
[24] DOSHIDA T,NAKAMURA M,SAITO H,et al.Hydrogen-enhanced lattice defect formation and hydrogen embrittlement of cyclically prestressed tempered martensitic steel[J].Acta Materialia,2013,61(20):7755-7766.
[25] DEVER D J.Temperature dependence of the elastic constants in α-iron single crystals:relationship to spin order and diffusion anomalies[J].Journal of Applied Physics,1972,43(8):3293-3301.
[26] ANDERSON T L.Fracture mechanics-fundermentals and applications[M].Boca Raton:CRC Press,2005.
[27] SONG J,CURTIN W A.Mechanisms of hydrogen-enhanced localized plasticity:an atomistic study using α-Fe as a model system[J].Acta Materialia,2014,68:61-69.
[28] XING X,CHEN W,ZHANG H.Prediction of crack propagation under cyclic loading based on hydrogen diffusion[J].Materials Letters,2015,152:86-89.
[29] HAFTBARADARAN H,SONG Jun,CURTIN W A,et al.Continuum and atomistic models of strongly coupled diffusion,stress,and solute concentration[J].Journal of Power Sources,2011,196(10):361-370.
[30] HÖRNLUND E,FOSSEN J K T,HAUGER S,et al.Hydrogen diffusivities and concentrations in 520M carbon steel under cathodic protection in 0.5M NaCl and the effect of added sulphite,dithionite,thiosulphate,and sulphide[J].International Journal of Electrochemical Science,2007,2:82-92.
[31] LIU Xiaoyang,XIE Wenbo,CHEN Weixing,et al.Effects of grain boundary and boundary inclination on hydrogen diffusion in α-iron[J].Journal of Materials Research,2011,26(21):2735-2743.
[32] MARVASTI M H,CHEN Weixing,KANIA R,et al.Frequency dependence of fatigue and corrosion fatigue crack growth rate[C]//Proceedings of 20108th International Pipeline Conference.Calgary,Alberta,Canada:ASME,2010.
[33] 张新生,李亚云王小完.基于逆高斯过程的腐蚀油气管道维修策略[J].石油学报,2017,38(3):356-362.
ZHANG Xinsheng,LI Yayun,WANG Xiaowan.Maintenance strategy of corroded oil-gas pipeline based on inverse Gaussian process[J].Acta Petrolei Sinica,2017,38(3):356-362.
[34] XING Xiao,YU Menghsan,CHEN Weixing,et al.Atomistic simulation of hydrogen-assisted ductile-to-brittle transition in α-iron[J].Computational Materials Science,2017,127:211-221.
[35] BEEN J,EADIE R,SUTHERBY R.Prediction of environmentally assisted cracking on gas and liquid pipelines[C]//Proceedings of 2006 International Pipeline Conference.Calgary,Alberta,Canada:ASME,2006.
[36] LYNCH S P.Interpreting hydrogen-induced fracture surfaces in terms of deformation processes:a new approach[J].Scripta Materialia,2011,65(10):851-854.
[37] MURAKAMI Y,KANEZAKI T,MINE Y.Hydrogen effect against hydrogen embrittlement[J].Metallurgical and Materials Transactions A,2010,41(10):2548-2562. |