參考文獻

[1]　Yamamoto Y, Brady M P, Lu Z P, et al. Creep?resistant, Al₂O₃?forming austenitic stainless steels [J]. Science, 2007, 316 (5823): 433?436.

[2]　Brady M P, Magee J, Yamamoto Y, et al. Co?optimization of wrought alumina?forming austenitic stainless steel composition ranges for high?temperature creep and oxidation/corrosion resistance [J]. Materials Science and Engineering: A, 2014, 590: 101?115.

[3]　Trotter G, Baker I. The effect of aging on the microstructure and mechanical behavior of the alumina?forming austenitic stainless steel Fe?20Cr?30Ni?2Nb?5Al [J]. Materials Science and Engineering: A, 2015, 627: 270?276.

[4]　吳曉東,?吳剛,?朱晶晶,?等. 含鋁奧氏體耐熱鋼的高溫抗氧化性能?[J]. 金屬熱處理, 2016, 41 (08): 1?5.

[5]　Zhou D Q, Zhao W X, Mao H H, et al. Precipitate characteristics and their effects on the high?temperature creep resistance of alumina?forming austenitic stainless steels [J]. Materials Science and Engineering: A, 2015, 622: 91?100.

[6]　孫勝英. 合金成分設(shè)計對含鋁奧氏體耐熱鋼組織和性能的影響?[D].北京:北京科技大學(xué), 2019.

[7]　范吉富. 一種700℃以上等級超超臨界電站鍋爐用奧氏體耐熱鋼的研究?[D].上海:上海交通大學(xué), 2016.

[8]　Yamamoto Y, Brady M P, Lu Z P, et al. Alumina?forming austenitic stainless steels strengthened by Laves phase and MC carbide precipitates [J]. Metallurgical and Materials Transactions A, 2007, 38 (11): 2737?2746.

[9]　Brady M P, Yamamoto Y, Santella M L, et al. Effects of minor alloy additions and oxidation temperature on protective alumina scale formation in creep?resistant austenitic stainless steels [J]. Scripta Materialia, 2007, 57 (12): 1117?1120.

[10]　Yamamoto Y, Brady M P, Lu Z P, et al. Alumina?forming austenitic stainless steels strengthened by laves phase and MC carbide precipitates [J]. Metallurgical and Materials Transactions:A,2007, 38A (11): 2737?2746.

[11]　徐向棋,?呂昭平. 新一代新型抗高溫氧化奧氏體耐熱鋼的研究進展?[J]. 中國材料進展, 2011, 30 (12): 1?5.

[12]　Brady M P, Unocic K A, Lance M J, et al. Increasing the upper temperature oxidation limit of alumina forming austenitic stainless steels in air with water vapor [J]. Oxidation of Metals, 2011, 75 (5?6): 337?357.

[13]　Jozaghi T, Wang C, Arroyave R, et al. Design of alumina?forming austenitic stainless steel using genetic algorithms [J]. Materials & Design, 2020, 186: 16.

[14]　Brady M P, Magee J, Yamamoto Y, et al. Co?optimization of wrought alumina?forming austenitic stainless steel composition ranges for high?temperature creep and oxidation/corrosion resistance [J].Materials Science and Engineering:A,2014, 590: 101?115.

[15]　Yamamoto Y, Santella M L, Liu C T, et al. Evaluation of Mn substitution for Ni in alumina?forming austenitic stainless steels [J]. Materials Science and Engineering:A,2009, 524 (1?2): 176?185.

[16]　董楠. 合金化元素對新型含Al奧氏體耐熱鋼/氧化層界面結(jié)構(gòu)形成及結(jié)合能力的影響?[D].太原:太原理工大學(xué), 2017.

[17]　高秋志. 新型高Cr鐵素體耐熱鋼相變行為及焊接性?[D].天津:天津大學(xué), 2012.

[18]　雍岐龍,?孫新軍,?鄭磊,?等. 鋼鐵材料中第二相的作用?[J]. 科技創(chuàng)新導(dǎo)報, 2009,?(08): 2?3.

[19]　Hayakawa H, Nakashima S, Kusumoto J, et al. Creep deformation characterization of heat resistant steel by stress change test [J]. International Journal of Pressure Vessels and Piping, 2009, 86 (9): 556?562.

[20]　Takeyama M. Novel Concept of Austenitic Heat Resistant Steels Strengthened by Intermetallics [J].Materials Science Forum, 2007, 539?543: 3012?3017.

[21]　Yamamoto Y, Takeyama A, Lu Z P, et al. Alloying effects on creep and oxidation resistance of austenitic stainless steel alloys employing intermetallic precipitates [J]. Intermetallics, 2008, 16 (3): 453?462.

[22]　Zhou D Q, Zhao W X, Mao H H, et al. Precipitate characteristics and their effects on the high?temperature creep resistance of alumina?forming austenitic stainless steels [J]. Materials Science and Engineering:A,2015, 622: 91?100.

[23]　Bei H, Yamamoto Y, Brady M P, et al. Aging effects on the mechanical properties of alumina?forming austenitic stainless steels [J]. Materials Science and Engineering: A, 2010, 527 (7?8): 2079?2086.

[24]　Trotter G, Rayner G, Baker I, et al. Accelerated precipitation in the AFA stainless steel Fe?20Cr?30Ni?2Nb?5Al via cold working [J]. Intermetallics, 2014, 53: 120?128.

[25]　Wang M, Sun Y?D, Feng J?K, et al. Microstructural evolution and mechanical properties of an Fe?18Ni?16Cr?4Al base alloy during aging at 950℃[J]. International Journal of Minerals, Metallurgy, and Materials, 2016, 23 (3): 314?322.

[26]　Asteman H, Spiegel M. A comparison of the oxidation behaviours of Al₂O₃ formers and Cr₂O₃ formers at 700 degrees C ? Oxide solid solutions acting as a template for nucleation [J]. Corrosion Science, 2008, 50 (6): 1734?1743.

[27]　Boulesteix C, Gregoire B, Pedraza F. Oxidation performance of repaired aluminide coatings on austenitic steel substrates [J]. Surface & Coatings Technology, 2017, 326: 224?237.