海洋工程用钢的大气腐蚀与耐候钢的发展

doi:10.13228/j.boyuan.issn1006-9356.20220180

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Abstract A bibliographic review of literatures about atmospheric corrosion of steels for marine engineering and development of weathering steel has been presented, especially the related achievements in recent ten years. Firstly, the electrochemical model of atmospheric corrosion for steels is introduced. Subsequently, the protection mechanism of rust layers on weathering steel is introduced in term of rust layer structures and alloying element roles. And then, the influences of environmental factors, including the relative humidity, pollutants, light shining and damnification in rust layers, on atmospheric corrosion behavior of weathering steel are analyzed. Finally, the development of weathering steel in recent years and the effect of non-alloy factors such as grain size and microstructures on the development of weathering steel are summarized, providing guidance for the design and application of advanced weathering steel.

Key words： steels for marine engineering atmospheric corrosion rust layer alloy element weathering steel

Received: 24 February 2022

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	ZHOU Lu-jun
	YANG Shan-wu

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ZHOU Lu-jun,YANG Shan-wu. Atmospheric corrosion of steels for marine engineering and development of weathering steels[J]. China Metallurgy, 2022, 32(8): 7-24.

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http://www.zgyj.ac.cn/EN/10.13228/j.boyuan.issn1006-9356.20220180 OR http://www.zgyj.ac.cn/EN/Y2022/V32/I8/7

[1]	王国栋. 海洋工程钢铁材料[M]. 北京: 化学工业出版社,2016.
[2]	周鲁军. 耐候钢锈层损伤特征及其对腐蚀行为的影响[D]. 北京: 北京科技大学,2021.
[3]	刘国超, 董俊华, 韩恩厚, 等. 耐候钢锈层研究进展[J]. 腐蚀科学与防护技术, 2006, 18(4): 268.
[4]	Morcillo M, Chico B, Díaz I, et al. Atmospheric corrosion data of weathering steels. A review[J]. Corrosion Science, 2013, 77: 6.
[5]	Morcillo M, Díaz I, Chico B, et al. Weathering steels: From empirical development to scientific design. A review[J]. Corrosion Science, 2014, 83: 6.
[6]	Evans U R, Taylor C A J. Mechanism of atmospheric rusting[J]. Corrosion Science, 1972, 12(3): 227.
[7]	Evans U R. The economic advantages of a sound painting scheme[J]. Transactions of the Institute of Metal Finishing, 1960, 37: 1.
[8]	Evans U R. Electrochemical mechanism of atmospheric rusting[J]. Nature, 1965, 206(4988): 980.
[9]	Evans U R. Mechanism of rusting[J]. Corrosion Science, 1969, 9(11): 813.
[10]	Stratmann M, Bohnenkamp K, Engell H J. An electrochemical study of phase-transitions in rust layers[J]. Corrosion Science, 1983, 23(9): 969.
[11]	Stratmann M, Bohnenkamp K, Ramchandran T. The influence of copper upon the atmospheric corrosion of iron[J]. Corrosion Science, 1987, 27(9): 905.
[12]	Stratmann M, Müller J. The mechanism of the oxygen reduction on rust-covered metal substrates[J]. Corrosion Science, 1994, 36(2): 327.
[13]	Stratmann M, Streckel H. On the atmospheric corrosion of metals which are covered with thin electrolyte layers-I. Verification of the experimental technique[J]. Corrosion Science, 1990, 30(6): 681.
[14]	Stratmann M, Streckel H. On the atmospheric corrosion of metals which are covered with thin electrolyte layers-II. Experimental results[J]. Corrosion Science, 1990, 30(6): 697.
[15]	Stratmann M, Streckel H, Kim K T, et al. On the atmospheric corrosion of metals which are covered with thin electrolyte layers-Ⅲ. The measurement of polarisation curves on metal surfaces which are covered by thin electrolyte layers[J]. Corrosion Science, 1990, 30(6): 715.
[16]	Antony H, Perrin S, Dillmann P, et al. Electrochemical study of indoor atmospheric corrosion layers formed on ancient iron artefacts[J]. Electrochimica Acta, 2007, 52(27): 7754.
[17]	Antony H, Peulon S, Legrand L, et al. Electrochemical synthesis of lepidocrocite thin films on gold substrate-EQCM, IRRAS, SEM and XRD study[J]. Electrochimica Acta, 2004, 50(4): 1015.
[18]	Antony H, Legrand L, Maréchal L, et al. Study of lepidocrocite γ-FeOOH electrochemical reduction in neutral and slightly alkaline solutions at 25 ℃[J]. Electrochimica Acta, 2005, 51(4): 745.
[19]	Lair V, Antony H, Legrand L, et al. Electrochemical reduction of ferric corrosion products and evaluation of galvanic coupling with iron[J]. Corrosion Science, 2006, 48(8): 2050.
[20]	Hoerlé S, Mazaudier F, Dillmann P, et al. Advances in understanding atmospheric corrosion of iron. II. Mechanistic modelling of wet-dry cycles[J]. Corrosion Science, 2004, 46(6): 1431.
[21]	Dillmann P, Mazaudier F, Hoerle S. Advances in understanding atmospheric corrosion of iron. I. Rust characterisation of ancient ferrous artefacts exposed to indoor atmospheric corrosion[J]. Corrosion Science, 2004, 46(6): 1401.
[22]	Monnier J, Neff D, Réguer S, et al. A corrosion study of the ferrous medieval reinforcement of the Amiens cathedral. Phase characterisation and localisation by various microprobes techniques[J]. Corrosion Science, 2010, 52(3): 695.
[23]	Burger E, Fénart M, Perrin S, et al. Use of the gold markers method to predict the mechanisms of iron atmospheric corrosion[J]. Corrosion Science, 2011, 53(6): 2122.
[24]	Monnier J, Burger E, Berger P, et al. Localisation of oxygen reduction sites in the case of iron long term atmospheric corrosion[J]. Corrosion Science, 2011, 53(8): 2468.
[25]	MA Y, LI Y, WANG F. Corrosion of low carbon steel in atmospheric environments of different chloride content[J]. Corrosion Science, 2009, 51(5): 997.
[26]	WAN Y, TAN J, ZHU S, et al. Insight into atmospheric pitting corrosion of carbon steel via a dual-beam FIB/SEM system associated with high-resolution TEM[J]. Corrosion Science, 2019, 152: 226.
[27]	Melchers R E. A new interpretation of the corrosion loss processes for weathering steels in marine atmospheres[J]. Corrosion Science, 2008, 50(12): 3446.
[28]	Hara S, Kamimura T, Miyuki H, et al. Taxonomy for protective ability of rust layer using its composition formed on weathering steel bridge[J]. Corrosion Science, 2007, 49(3): 1131.
[29]	张全成, 吴建生, 郑文龙, 等. 耐候钢表面稳定锈层形成机理的研究[J]. 腐蚀科学与防护技术, 2001, 13(3): 143.
[30]	Kihira H, Ito S, Murata T. The behavior of phosphorous during passivation of weathering steel by protective patina formation[J]. Corrosion Science, 1990, 31: 383.
[31]	Misawa T, Asami K, Hashimoto K, et al. The mechanism of atmospheric rusting and the protective amorphous rust on low alloy steel[J]. Corrosion Science, 1974, 14(4): 279.
[32]	Horton J. The rusting of low alloy steel in the atmosphere[C]// Proceedings of the Pittsburgh regional technical meeting of the American Iron and Steel Institute. [S.l]: American Iron and Steel Institute, 1965: 1.
[33]	Okada H, Hosoi Y, Naito H. Electrochemical reduction of thick rust layers formed on steel surfaces[J]. Corrosion, 1970, 26(10): 429.
[34]	Díaz I, Cano H, Chico B, et al. Some clarifications regarding literature on atmospheric corrosion of weathering steels[J]. International Journal of Corrosion, 2012, 5: 445.
[35]	Choi Y S, Shim J J, Kim J G. Effects of Cr, Cu, Ni and Ca on the corrosion behavior of low carbon steel in synthetic tap water[J]. Journal of Alloys and Compounds, 2005, 391(1): 162.
[36]	ZHANG X, YANG S W, ZHANG W H, et al. Influence of outer rust layers on corrosion of carbon steel and weathering steel during wet-dry cycles[J]. Corrosion Science, 2014, 82: 165.
[37]	ZHOU L, YANG S. Investigation on crack propagation in band-like rust layers on weathering steel[J]. Construction and Building Materials, 2021, 281: 122564.
[38]	Misawa T, Hashimoto K, Shimodaira S. The mechanism of formation of iron oxide and oxyhydroxides in aqueous solutions at room temperature[J]. Corrosion Science, 1974, 14(2): 131.
[39]	Yamashita M, Misawa T. Recent progress in the study of protective rust-layer formation on weathering steel[C] // Corrosion `98. San Diego, CA (United States): NACE International, 1998: 95.
[40]	Yamashita M, Miyuki H, Matsuda Y, et al. The long term growth of the protective rust layer formed on weathering steel by atmospheric corrosion during a quarter of a century[J]. Corrosion Science, 1994, 36(2): 283.
[41]	MA Y, LI Y, WANG F. The effect of β-FeOOH on the corrosion behavior of low carbon steel exposed in tropic marine environment[J]. Materials Chemistry and Physics, 2008, 112(3): 844.
[42]	Asami K, Kikuchi M. In-depth distribution of rusts on a plain carbon steel and weathering steels exposed to coastal-industrial atmosphere for 17 years[J]. Corrosion Science, 2003, 45(11): 2671.
[43]	ZHANG Q C, WU J S, WANG J J, et al. Corrosion behavior of weathering steel in marine atmosphere[J]. Materials Chemistry and Physics, 2003, 77(2): 603.
[44]	张全成, 郑文龙. 合金元素的二次分配对耐候钢抗大气腐蚀性能的影响[J]. 材料保护, 2001, 34(4): 4.
[45]	Nishimura T, Kodama T. Clarification of chemical state for alloying elements in iron rust using a binary-phase potential-pH diagram and physical analyses[J]. Corrosion Science, 2003, 45(5): 1073.
[46]	DONG J H, CHEN X H, HAN E H. The synergistic inhibition to atmospheric corrosion in Mn-Cu alloying steel[C]// Proceedings of the Second International Conference on Advanced Structural Steels. Shanghai: State Key Laboratory of Corrosion and Protection for Metals, Institute Research of Metal, Chinese Academy of Sciences, 2004: 332.
[47]	Schwitter H, Böhni H. Influence of accelerated weathering on the corrosion of low-alloy steels[J]. Journal of The Electrochemical Society, 1980, 127(1): 15.
[48]	Suzuki I, Hisamatsu Y, Masuko N. Nature of atmospheric rust on iron[J]. Journal of The Electrochemical Society, 1980, 127(10): 2210.
[49]	Chen Y Y, Tzeng H J, Wei L I, et al. Corrosion resistance and mechanical properties of low-alloy steels under atmospheric conditions[J]. Corrosion Science, 2005, 47(4): 1001.
[50]	Chen Y Y, Tzeng H J, Wei L, et al. Mechanical properties and corrosion resistance of low-alloy steels in atmospheric conditions containing chloride[J]. Materials Science and Engineering A, 2005, 398(1): 47.
[51]	ZHANG Q C, WU J S, WANG J J, et al. Corrosion behavior of weathering steel in marine atmosphere[J]. Materials Chemistry and Physics, 2002, 77(2): 603.
[52]	Ishikawa T, Ueno T, Yasukawa A, et al. Influences of metal ions on the structure of poorly crystallized iron oxide rust[J]. Corrosion Science, 2003, 45(5): 1037.
[53]	Ishikawa T, Katoh R, Yasukawa A, et al. Influences of metal ions on the formation of β-FeOOH particles[J]. Corrosion Science, 2001, 43(9): 1727.
[54]	Ishikawa T, Kumagai M, Yasukawa A, et al. Influences of metal ions on the formation of γ-FeOOH and magnetite rusts[J]. Corrosion Science, 2002, 44(5): 1073.
[55]	Mizoguchi T, Ishii Y, Okada T, et al. Magnetic property based characterization of rust on weathering steels[J]. Corrosion Science, 2005, 47(10): 2477.
[56]	Kumar A, Balasubramaniam R. Corrosion product analysis of corrosion resistant ancient Indian iron[J]. Corrosion Science, 1998, 40(7): 1169.
[57]	Balasubramaniam R, Ramesh Kumar A. Characterization of Delhi iron pillar rust by X-ray diffraction, Fourier transform infrared spectroscopy and Mössbauer spectroscopy[J]. Corrosion Science, 2000, 42(12): 2085.
[58]	Balasubramaniam R. On the corrosion resistance of the Delhi iron pillar[J]. Corrosion Science, 2000, 42(12): 2103.
[59]	Dillmann P, Balasubramaniam R, Beranger G. Characterization of protective rust on ancient Indian iron using microprobe analyses[J]. Corrosion Science, 2002, 44(10): 2231.
[60]	Balasubramaniam R, Ramesh Kumar A. Corrosion resistance of the Dhar iron pillar[J]. Corrosion Science, 2003, 45(11): 2451.
[61]	Monnier J, Vantelon D, Reguer S, et al. X-ray absorption spectroscopy study of the various forms of phosphorus in ancient iron samples[J]. Journal of Analytical Atomic Spectrometry, 2011, 26(5): 885.
[62]	Kamimura T, Stratmann M. The influence of chromium on the atmospheric corrosion of steel[J]. Corrosion Science, 2001, 43(3): 429.
[63]	Kamimura T, Nasu S, Segi T, et al. Corrosion behavior of steel under wet and dry cycles containing Cr3+ ion[J]. Corrosion Science, 2003, 45(8): 1863.
[64]	王建军, 郭小丹, 郑文龙, 等. 海洋大气暴露3 年的碳钢与耐候钢表面锈层分析[J]. 腐蚀与防护, 2002, 23(7): 288.
[65]	ZHANG Q C, WU J S, ZHENG W L, et al. Characterization of rust layers formed in low alloy steel exposed in marine atmosphere[J]. Journal of Materials Science and Technology, 2002, 18(5): 455.
[66]	张全成, 王建军, 吴建生, 等. 锈层离子选择性对耐候钢抗海洋性大气腐蚀性能的研究[J]. 金属学报, 2001, 37(2): 193.
[67]	CHENG X Q, JIN Z, LIU M, et al. Optimizing the nickel content in weathering steels to enhance their corrosion resistance in acidic atmospheres[J]. Corrosion Science, 2017, 115: 135.
[68]	QIAN Y H, MA C H, NIU D, et al. Influence of alloyed chromium on the atmospheric corrosion resistance of weathering steels[J]. Corrosion Science, 2013, 74: 424.
[69]	QIAN Y H, NIU D, XU J J, et al. The influence of chromium content on the electrochemical behavior of weathering steels[J]. Corrosion Science, 2013, 71: 72.
[70]	YANG X, YANG Y, SUN M, et al. A new understanding of the effect of Cr on the corrosion resistance evolution of weathering steel based on big data technology[J]. Journal of Materials Science and Technology, 2022, 104: 67.
[71]	SUN M, DU C, LIU Z, et al. Fundamental understanding on the effect of Cr on corrosion resistance of weathering steel in simulated tropical marine atmosphere[J]. Corrosion Science, 2021, 186: 109427.
[72]	ZHANG T, XU X, LI Y, et al. The function of Cr on the rust formed on weathering steel performed in a simulated tropical marine atmosphere environment[J]. Construction and Building Materials, 2021, 277: 122298.
[73]	Nishimura T, Katayama H, Noda K, et al. Effect of Co and Ni on the corrosion behavior of alloy steels in wet/dry environments[J]. Corrosion Science, 2000, 42(9): 1611.
[74]	Kimura M, Kihira H, Ohta N, et al. Control of Fe(O,OH)6 nano-network structures of rust for high atmospheric-corrosion resistance[J]. Corrosion Science, 2005, 47(10): 2499.
[75]	CHEN X H, DONG J H, HAN E H, et al. Effect of Ni on the ion-selectivity of rust layer on low alloy steel[J]. Materials Letters, 2007, 61(19): 4050.
[76]	Diaz I, Cano H, de la Fuente D, et al. Atmospheric corrosion of Ni-advanced weathering steels in marine atmospheres of moderate salinity[J]. Corrosion Science, 2013, 76: 348.
[77]	Rajendran N, Nishimura T. Monitor of pH and chloride ion within the rust of low alloy steels under atmospheric corrosion environment [C]// Proceedings of Second International Conference on Advanced Structural Steels (ICASS 2004). Shanghai(CN): Corrosion Resistant Design Group, Steel Research Center, National Institute for Materials Science (NIMS), 2004: 425.
[78]	Artigas A, Bustos O, Sipos K, et al. Influence of Ni and Ti on the response to simulated marine corrosion of weathering steel A242[J]. Matéria (Rio de Janeiro), 2015, 20(3): 646.
[79]	刘芮, 陈小平, 王向东, 等. Ni 对耐候钢在模拟海洋大气环境下耐蚀性的影响[J]. 腐蚀科学与防护技术, 2016, 28(2): 122.
[80]	Nishimura T, Tahara A, Kodama T. Effect of Al on the corrosion behavior of low alloy steels in wet/dry environment[J]. Materials Transactions JIM, 2001, 42(3): 478.
[81]	刘丽宏, 齐慧滨, 卢燕平, 等. 耐大气腐蚀钢的研究概况[J]. 腐蚀科学与防护技术, 2003, 15(2): 86.
[82]	Refaey S. Inhibition of chloride pitting corrosion of mild steel by sodium gluconate[J]. Applied Surface Science, 2000, 157(3): 199.
[83]	Sakashita M, Sato N. The effect of molybdate anion on the ion-selectivity of hydrous ferric oxide films in chloride solutions[J]. Corrosion Science, 1977, 17(6): 473.
[84]	XIAO X M, PENG Y, MA C Y, et al. Effects of alloy element and microstructure on corrosion resistant property of deposited metals of weathering steel[J]. Journal of Iron and Steel Research International, 2016, 23(2): 171.
[85]	Nishimura T. Rust formation and corrosion performance of Si-and Al-bearing ultrafine grained weathering steel[J]. Corrosion Science, 2008, 50(5): 1306.
[86]	Nishimura T, Noda K, Kodama T. Corrosion behavior of tungsten-bearing steel in a wet/dry environment containing chloride ions[J]. Corrosion, 2001, 57(9): 753.
[87]	Ishikawa T, Motoki T, Kandori K, et al. Influence of hydrolyzed and nonhydrolyzed Ti, Cr, and Al ions on the formation of β-FeOOH particles[J]. Journal of Colloid and Interface Science, 2003, 265: 320.
[88]	Ishikawa T, Motoki T, Katoh R, et al. Structures of β-FeOOH particles formed in the presence of Ti(IV), Cr(III), and Cu(II) ions[J]. Journal of Colloid and Interface Science, 2002, 250: 74.
[89]	Nakayama T, Ishikawa T, Konno T J. Structure of titanium-doped goethite rust[J]. Corrosion Science, 2005, 47(10): 2521.
[90]	HOU W, LING C. Eight-year atmospheric corrosion exposure of steels in China[J]. Corrosion, 1999, 55(1): 65.
[91]	Cano H, Neff D, Morcillo M, et al. Characterization of corrosion products formed on Ni2.4wt%-Cu0.5wt%-Cr0.5wt% weathering steel exposed in marine atmospheres[J]. Corrosion Science, 2014, 87: 438.
[92]	王晶晶, 黄峰, 周学俊, 等. 合金元素对耐候钢在海洋大气中耐蚀性影响的交互作用[J]. 腐蚀与防护, 2015, 36(1): 58.
[93]	周学俊, 黄峰, 王晶晶,等. 镍铜质量比和硅含量对海洋环境用耐候钢电化学腐蚀行为的影响[J]. 腐蚀与防护, 2016, 37(10): 789.
[94]	DONG B, LIU W, ZHANG T, et al. Corrosion failure analysis of low alloy steel and carbon steel rebar in tropical marine atmospheric environment: Outdoor exposure and indoor test[J]. Engineering Failure Analysis, 2021, 129: 105720.
[95]	WU W, WANG Q, YANG L, et al. Corrosion and SCC initiation behavior of low-alloy high-strength steels microalloyed with Nb and Sb in a simulated polluted marine atmosphere[J]. Journal of Materials Research and Technology, 2020, 9: 12976.
[96]	DONG B, LIU W, CHEN L, et al. Optimize Ni, Cu, Mo element of low Cr-steel rebars in tropical marine atmosphere environment through two years of corrosion monitoring[J]. Cement and Concrete Composites, 2022, 125: 104317.
[97]	Dehri I, Erbil M. The effect of relative humidity on the atmospheric corrosion of detive organic coating materials: an EIS study with a new approach[J]. Corrosion Science, 2000, 42(6): 969.
[98]	WANG Z F, LIU J R, WU L X, et al. Study of the corrosion behavior of weathering steels in atmospheric environments[J]. Corrosion Science, 2013, 67: 1.
[99]	王树涛, 杨善武, 高克玮, 等. 新型低碳贝氏体钢在含氯离子环境中的腐蚀行为和表观力学性能的变化[J]. 金属学报, 2008, 44(9): 1116.
[100]	WANG S T, YANG S W, GAO K W, et al. Corrosion behavior and corrosion products of a low-alloy weathering steel in Qingdao and Wanning[J]. International Journal of Minerals, Metallurgy and Materials, 2009, 16(1): 58.
[101]	FAN Y, LIU W, LI S, et al. Evolution of rust layers on carbon steel and weathering steel in high humidity and heat marine atmospheric corrosion[J]. Journal of Materials Science and Technology, 2020, 39: 190.
[102]	Soares C G, Garbatov Y, Zayed A, et al. Influence of environmental factors on corrosion of ship structures in marine atmosphere[J]. Corrosion Science, 2009, 51(9): 2014.
[103]	De la Fuente D, Díaz I, Simancas J, et al. Long-term atmospheric corrosion of mild steel[J]. Corrosion Science, 2011, 53(2): 604.
[104]	Oh S J, Cook D C, Townsend H E. Atmospheric corrosion of different steels in marine, rural and industrial environments[J]. Corrosion Science, 1999, 41(9): 1687.
[105]	ZHANG X, YANG S W, GUO H, et al. Atmospheric corrosion behavior of weathering steel in periodically changed environment[J]. ISIJ International, 2014, 54(4): 909.
[106]	Riazi H R, Danaee I, Peykari M. Influence of ultraviolet light irradiation on the corrosion behavior of carbon steel AISI 1015[J]. Metals and Materials International, 2013, 19(2): 217.
[107]	Moussa S O,Hocking M G. The photo-inhibition of localized corrosion 304 stainless steel in sodium chloride environment[J]. Corrosion Science, 2001, 43(11): 2037.
[108]	Breslin C B, Macdonald D D, Sikora E, et al. Photo-inhibition of pitting corrosion on types 304 and 316 stainless steels in chloride-containing solutions[J]. Electrochimica Acta, 1997, 42(1): 137.
[109]	卢大容. 辐照对金属腐蚀的影响[J]. 中国腐蚀与防护学报, 1981, 1(3): 37.
[110]	SONG L Y, CHEN Z Y, HOU B R. The role of the photovoltaic effect of γ-FeOOH and β-FeOOH on the corrosion of 09CuPCrNi weathering steel under visible light[J]. Corrosion Science, 2015, 93: 191.
[111]	SONG L Y, MA X M, CHEN Z Y, et al. The role of UV illumination on the initial atmospheric corrosion of 09CuPCrNi weathering steel in the presence of NaCl particles[J]. Corrosion Science, 2014, 87:427.
[112]	SONG L Y, CHEN Z Y. The role of UV illumination on the NaCl-induced atmospheric corrosion of Q235 carbon steel[J]. Corrosion Science, 2014, 86: 318.
[113]	SONG L Y, CHEN Z Y. Effect of γ-FeOOH and γ-Fe2O3 on the corrosion of Q235 carbon steel under visible light[J]. Journal of The Electrochemical Society, 2015, 162(3): C79.
[114]	SONG L Y, SHI H, HAN P, et al. Corrosion trend on Q450 weathering steel deposited with Na2SO4, NaCl under ultraviolet light illumination[J]. Journal of Industrial and Engineering Chemistry, 2021,102: 206.
[115]	LIU Y, ZHANG J, WEI Y, et al. Effect of different UV intensity on corrosion behavior of carbon steel exposed to simulated Nansha atmospheric environment[J]. Materials Chemistry and Physics, 2019, 237: 121855.
[116]	Dünnwald J, Otto A. An investigation of phase transitions in rust layers using Raman spectroscopy[J]. Corrosion Science, 1989, 29(9):1167.
[117]	GUO J, YANG S W, SHANG C J, et al. Influence of carbon content and microstructure on corrosion behaviour of low alloy steels in a Cl- containing environment[J]. Corrosion Science, 2009, 51(2): 242.
[118]	Ueda M, Takabe H. Effect of environmental factor and microstructure on morphology of corrosion products in CO2 environments[C]// Corrosion 99. San Antonio, Texas (United States): NACE International, 1999: NACE-99013.
[119]	Nyborg R, Gulbrandsen E, Loeland T, et al. Effect of steel microstructure and composition on inhibition of CO2 corrosion [C]// Corrosion 2000. Orlando, Florida: NACE International, 2000: NACE-00023.
[120]	De la Fuente D, Díaz I, Simancas J, et al. Long-term atmospheric corrosion of mild steel[J]. Corrosion Science, 2011, 53(2): 604.
[121]	崔雷, 杨善武, 王树涛, 等. 锈层损伤对低碳贝氏体钢在含 Cl-环境中腐蚀行为的影响[J]. 金属学报, 2009, 45(4): 442.
[122]	王树涛, 高克玮, 杨善武, 等. 热震对结构钢锈层裂纹的影响[J]. 腐蚀与防护, 2009, 30(3): 153.
[123]	王树涛, 高克玮, 杨善武,等. 低碳贝氏体钢在青岛曝晒一年的锈层力学性能和抗热震性能研究[J]. 腐蚀科学与防护技术, 2010, 22(1): 9.
[124]	张文华, 杨善武, 郭佳, 等. 冰冻/解冻对低合金耐候钢大气腐蚀的影响[J]. 北京科技大学学报, 2010, 32(7): 883.
[125]	张全成, 吴建生. 耐候钢表面保护性锈层的力学性能[J]. 钢铁研究学报, 2006, 18(3):42.
[126]	崔雷, 杨善武, 王树涛, 等. 低碳贝氏体钢在三种典型环境中的腐蚀行为和腐蚀产物[J]. 北京科技大学学报, 2009, 31(3): 306.
[127]	ZHANG Y, ZHENG K, ZHU J, et al. Research on corrosion and fatigue performance of weathering steel and high-performance steel for bridges[J]. Construction and Building Materials, 2021, 289: 123108.
[128]	GUO X, ZHU J, KANG J, et al. Rust layer adhesion capability and corrosion behavior of weathering steel under tension during initial stages of simulated marine atmospheric corrosion[J]. Construction and Building Materials, 2020, 234: 117393.
[129]	Pongsaksawad W P, Piya Khamsuk, Sorachot S, et al. Chloride distribution model and corrosion map of structural steels for tropical climate in Thailand[J]. Science of the Total Environment, 2021, 787: 147465.
[130]	Alcántara J, Chico B, Díaz I, et al. Airborne chloride deposit and its effect on marine atmospheric corrosion of mild steel[J]. Corrosion Science, 2015, 97: 74.
[131]	Syed S. Atmospheric corrosion of hot and cold rolled carbon steel under field exposure in Saudi Arabia[J]. Corrosion Science, 2008, 50(6): 1779.
[132]	WU W, HAO W, LIU Z, et al. Comparative study of the stress corrosion behavior of a multiuse bainite steel in the simulated tropical marine atmosphere and seawater environments[J]. Construction and Building Materials, 2020, 239: 117903.
[133]	GONG K, WU M, XIE F, et al. Effect of Cl- and rust layer on stress corrosion cracking behavior of X100 steel base metal and heat-affected zone in marine alternating wet/dry environment[J]. Materials Chemistry and Physics, 2021, 270: 124826.
[134]	Díaz I, Cano D H, Lopesino P, et al. Five-year atmospheric corrosion of Cu, Cr and Ni weathering steels in a wide range of environments[J]. Corrosion Science, 2018, 141: 146.
[135]	CHEN H, CUI H, HE Z, et al. Influence of chloride deposition rate on rust layer protectiveness and corrosion severity of mild steel in tropical coastal atmosphere[J]. Materials Chemistry and Physics, 2021, 259: 123971.
[136]	MA Y, LI Y, WANG F. The atmospheric corrosion kinetics of low carbon steel in a tropical marine environment[J]. Corrosion Science, 2010, 52(5): 1796.
[137]	Iwei F. Atmospheric corrosion of carbon steels and weathering steels in Taiwan[J]. British Corrosion Journal, 1991, 26(3): 209.
[138]	Raja V K B, Palanikumar K, Renish R R, et al. Corrosion resistance of corten steel-A review[J]. Materials Today: Proceedings, 2021, 46: 3572.
[139]	Kishikawa H, Miyuki H, Hara S, et al. Development of surface treatment technique promoting protective rust formation[J]. Sumitomo Search, 1998, 60: 20.
[140]	ZHANG C L, CAI D Y, LIAO B, et al. A study on the dual-phase treatment of weathering steel 09CuPCrNi[J]. Materials Letters, 2004, 58(9): 1524.
[141]	黄桂桥, 郁春娟. 金属材料在海洋飞溅区的腐蚀[J]. 材料保护, 1999, 32(2): 28.
[142]	陈小平, 王向东, 江社明, 等. 晶粒尺寸对耐候钢抗大气腐蚀性能的影响[J]. 材料保护, 2005, 38(7): 14.
[143]	彭冲, 杨善武, 贺信莱. 晶粒尺寸对耐候钢抗海洋大气腐蚀性能的影响[C]//全国材料计算与模拟学术会议. 北戴河: 中国金属学会,燕山大学, 2007: 97.
[144]	查春和, 李龙, 丁桦, 等. 晶粒尺寸对超细晶耐候钢的耐大气腐蚀性能的影响[C]// 第五届全国腐蚀大会. 北京: 中国腐蚀与防护学会, 2009:1.
[145]	姜鹏飞, 汪兵, 刘清友,等. 晶粒尺寸对Corten-B型耐候钢耐大气腐蚀性能的影响[J]. 钢铁, 2009, 44(12):67.
[146]	王珊, 米丰毅, 雷富军, 等. 晶粒尺寸对Cu-P-Cr-Ni-Mo-Nb耐候钢耐蚀性能的影响[J]. 青海大学学报(自然科学版), 2012, 30(3): 15.
[147]	李琳, 徐小连, 艾芳芳, 等. 晶粒尺寸对桥梁耐候钢耐大气腐蚀性能的影响[J]. 腐蚀与防护, 2013, 34(11): 1001.
[148]	张春玲, 蔡大勇, 廖波, 等. 双相化处理对09CuPCrNi耐候钢腐蚀性能的影响[J]. 钢铁, 2008, 43(12):79.
[149]	张春玲, 蔡大勇, 张克勤, 等. 热轧Cu-P-Cr-Ni-Mo双相耐候钢的组织与性能[J]. 材料热处理学报, 2012, 33(9):33.
[150]	ZHAO Y T, YANG S W, SHANG C J, et al. The mechanical properties and corrosion behaviors of ultra-low carbon microalloying steel[J]. Materials Science and Engineering A, 2007, 454/455: 695.
[151]	李少坡, 郭佳, 杨善武, 等. 碳含量和组织类型对低合金钢耐蚀性能的影响[J]. 北京科技大学学报, 2008, 30(1): 16.
[152]	ZHANG T, LIU W, DONG B, et al. Determining on welding methods and parameters for the 3%Ni steel welded joints-insights into the corrosion resistance of the fusion zone[J]. Materials Chemistry and Physics, 2022, 276: 125365.
[153]	WANG Z, ZHANG X, CHENG L, et al. Role of inclusion and microstructure on corrosion initiation and propagation of weathering steels in marine environment[J]. Journal of Materials Research and Technology, 2021, 10: 306.
[154]	XU X, CHENG H, WU W, et al. Stress corrosion cracking behavior and mechanism of Fe-Mn-Al-C-Ni high specific strength steel in the marine atmospheric environment[J]. Corrosion Science, 2021, 191: 109760
[155]	Nishimura T, Kodama T. Clarification of chemical state for alloying elements in iron rust using a binary-phase potential-PH diagram and physical analyses[J]. Corrosion Science, 2003, 45(6): 1073.
[156]	WU W, CHENG X, ZHAO J, et al. Benefit of the corrosion product film formed on a new weathering steel containing 3% nickel under marine atmosphere in Maldives[J]. Corrosion Science, 2020, 165: 108416.
[157]	Diaz H, Cano D, de la Fuente, et al. Atmospheric corrosion of Ni-advanced weathering steels in marine atmospheres of moderate salinity[J]. Corrosion Science, 2013, 76: 348.
[158]	Nishikata A, Suzuki F, Tsuru T. Corrosion monitoring of nickel-containing steels in marine atmospheric environment[J]. Corrosion Science, 2005, 47(10): 2578.
[159]	JIA J, WU W, CHENG X, et al. Ni-advanced weathering steels in Maldives for two years: Corrosion results of tropical marine field test[J]. Construction and Building Materials, 2020, 245: 118463.
[160]	SUN M, PANG Y, DU C, et al. Optimization of Mo on the corrosion resistance of Cr-advanced weathering steel designed for tropical marine atmosphere[J]. Construction and Building Materials, 2021, 302: 124346.
[161]	XU X, ZHANG T, WU W, et al. Optimizing the resistance of Ni-advanced weathering steel to marine atmospheric corrosion with the addition of Al or Mo[J]. Construction and Building Materials, 2021, 279: 122341.
[162]	JIA J, CHENG X, YANG X, et al. A study for corrosion behavior of a new-type weathering steel used in harsh marine environment[J]. Construction and Building Materials, 2020, 259: 119760.
[163]	孙毅, 李冠楠, 刘彬, 等.邯钢桥梁用耐候钢Q345qDNH的开发及应用[J].中国冶金,2021,31(1):59.
[164]	李春智, 马龙腾, 田志红, 等. 高性能Q460耐火耐候结构用钢的研发[J].中国冶金,2018,28(7):19.