Influence of Solution Temperature on γ→ε Transformation and Damping Capacity of Fe-19Mn Alloy

doi:10.11900/0412.1961.2020.00005

Acta Metall Sin

2020, Vol. 56

Issue (9): 1217-1226 DOI: 10.11900/0412.1961.2020.00005

Current Issue | Archive | Adv Search

Influence of Solution Temperature on γ→ε Transformation and Damping Capacity of Fe-19Mn Alloy

WANG Shihong, LI Jian(

), CHAI Feng, LUO Xiaobing, YANG Caifu, SU Hang

Department of Structure Steels, Central Iron and Steel Research Institute, Beijing 100081, China

Cite this article:

WANG Shihong, LI Jian, CHAI Feng, LUO Xiaobing, YANG Caifu, SU Hang. Influence of Solution Temperature on γ→ε Transformation and Damping Capacity of Fe-19Mn Alloy. Acta Metall Sin, 2020, 56(9): 1217-1226.

Download:

HTML

PDF(3920KB)
Export: BibTeX | EndNote (RIS)

Abstract

Due to the high damping capacity and excellent mechanical properties, Fe-Mn alloy is considered to be a promising high damping alloy, and suitable for constructional and vehicle metal parts application, which can enhance the fatigue property of structures and metal parts, and also improve the working and living environment. It's generally accepted at present that damping capacity of Fe-Mn alloy is influenced by the stacking fault boundaries in γ-austenite and ε-martensite, γ/ε phase boundaries and ε/ε variant boundaries; another view is that boundaries of the above damping sources are made up of partial dislocations, so the damping capacity of Fe-Mn alloy is caused by the motion of partial dislocations, and interpreted by G-L dislocation pinning model and stacking fault probabilities calculation. But there is no distinction between the probabilities of different type stacking faults. Both deformation stacking fault and growth stacking fault can be formed in γ-austenite and ε-martensite, and the change of process parameters has different influence on them, which will lead to different changes of deformation and growth stacking fault probabilities. So it's necessary to analyze whether boundaries of different stacking fault types will have different effects on damping capacity of Fe-Mn alloy. Based on that, a hot-rolled Fe-19Mn alloy is prepared and then solution treated between 950~1100 ℃. Damping capacity is measured by dynamic mechanical analyzer (DMA). The microstructure evolution is observed by OM and TEM, and XRD is used to analyze phase constitution and to measure stacking fault probabilities. The results reveal that Fe-19Mn alloy shows amplitude-dependent damping capacity which almost linearly increases with amplitude, and frequency-independent damping capacity. From G-L plot, the variation of damping capacity below the critical amplitude A' (A'≈30 μm) is interpreted by G-L model, while it's associated with micro-plastic deformation when above A'. As the increase of solution treatment temperature, the damping capacity of Fe-19Mn decreases, and possesses the best performance at 950 ℃; furthermore, it shows different characteristics in different amplitude ranges: when the amplitude is lower than 170 μm, damping capacity decreases in exponential form, which changes similarily with deformation stacking fault probability in ε-martensite, so it can be considered the boundaries of deformation stacking fault as the main damping source; when the amplitude is higher than 170 μm, damping capacity decreases linearly, which changes similarily with the relative length of γ/ε phase boundary, so it can be considered γ/ε phase boundary as the main damping source. Based on TEM observation of stacking faults in γ-austenite, it can be inferred that stacking fault boundaries in γ-austenite have no obvious contribution to the change of damping capacity of Fe-19Mn with amplitude.

Key words: Fe-Mn alloy damping capacity γ→ε transformation stacking fault probability γ/ε interface

Received: 02 January 2020

ZTFLH:

TG135.7

	Service

	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	（）
	Articles by authors
	Shihong WANG
	Jian LI
	Feng CHAI
	Xiaobing LUO
	Caifu YANG
	Hang SU

URL:

https://www.ams.org.cn/EN/10.11900/0412.1961.2020.00005 OR https://www.ams.org.cn/EN/Y2020/V56/I9/1217

Fig.1 Influence of amplitude (a) and frequency (b) on damping capacity of Fe-19Mn alloy (A—amplitude, f—frequency, δ—phase lag angle, tanδ—damping value)

Fig.2 The influence of solution temperature on damping capacity of Fe-19Mn alloy in different A ranges (f=50 Hz)

Fig.3 OM images of microstructures of Fe-19Mn alloy under different solution temperatures

Fig.4 The influence of solution temperature on ε-mar-tensite plate size (a) and relative length of γ/ε interface (b)

Fig.5 Variations of austenite grain size and $M s γ → ε$ with solution temperature ( $M s γ → ε$ —starting temperature of γ→ε transformation)

Fig.6 Bright-field TEM image of γ-austenite and ε-martensite (a), dark-field images of γ-austenite (b) and ε-martensite (c) of 1100 ℃ solution treated sample, and corresponding selected area electron diffraction (SAED) patterns for areas A~C in Fig.6a (d~f)

Fig.7 Bright-field (a, d) and dark-field (b, e) TEM images of stacking faults in γ-austenite of 950 ℃ (a, b) and 1050 ℃ (d, e) solution treated sample under two-beam condition, and corresponding SAED patterns for circle areas A (c) and B (f) in Figs.7a and d, respectively

Fig.8 Bright-field TEM images of stacking faults in ε-martensite with different plate thickness under two-beam condition (a~c), and corresponding SAED patterns for ε-martensite in Fig.7a (d), and for ε-martensite in Figs.7b and c (e),respectively

Fig.9 XRD spectra (a) and phase fractions (b) of samples treated in different solution temperatures

Fig.10 The influence of solution temperature on stacking fault probabilities in γ-austenite (a) and ε-martensite (b) (α—deformation fault probab-ility, β—growth fault probability)

Fig.11 The influence of austenite grain size (D_γ) on stacking fault energy (Γ) of γ-austenite (a) and driving force ( $Δ G γ → ε$ ) (b)

Fig.12 G-L plot of Fe-19Mn alloy (δ_H—damping, A'—critical amplitude )

[1]	Jun J H, Choi C S. Change in stacking-fault energy with Mn content and its influence on the damping capacity of the austenitic phase in Fe-high Mn alloys [J]. J. Mater. Sci., 1999, 34: 3421
[2]	Choi W S, De Cooman B C. Effect of carbon on the damping capacity and mechanical properties of thermally trained Fe-Mn based high damping alloys [J]. Mater. Sci. Eng., 2017, A700: 641
[3]	Sun H Y, Giron-Palomares B, Qu W H, et al. Effects of Cr addition and cold pre-deformation on the mechanical properties, damping capacity, and corrosion behavior of Fe-17%Mn alloys [J]. J. Alloys Compd., 2019, 803: 250
[4]	Jee K K, Jang W Y, Baik S H, et al. Damping mechanism and application of Fe-Mn based alloys [J]. Mater. Sci. Eng., 1999, A273-275: 538
[5]	Watanabe Y, Sato H, Nishino Y, et al. Training effect on damping capacity in Fe-20 mass% Mn binary alloy [J]. Mater. Sci. Eng., 2008, A490: 138
[6]	Jun J H, Choi C S. The influence of Mn content on microstructure and damping capacity in Fe-(17~23)%Mn alloys [J]. Mater. Sci. Eng., 1998, A252: 133
[7]	Kim J C, Han D W, Baik S H, et al. Effects of alloying elements on martensitic transformation behavior and damping capacity in Fe-17Mn alloy [J]. Mater. Sci. Eng., 2004, A378: 323
[8]	Jun J H, Baik S H, Lee Y K, et al. The influence of aging on damping capacity of Fe-17%Mn-X%C alloys [J]. Scr. Mater., 1998, 39: 39
[9]	Jee K K, Jang W Y, Baik S H, et al. Transformation behavior and its effect on damping capacity in Fe-Mn based alloys [J]. J. Phys. IV, 1995, 5: C8-385
[10]	Huang S K, Liu J H, Li C A, et al. Effect of pre-deformation on stacking fault probability and damping capacity of Fe-Mn alloy [J]. Acta Metall. Sin., 2009, 45: 937
	(黄姝珂, 刘建辉, 李昌安等. 预变形对Fe-Mn合金层错几率和阻尼性能的影响 [J]. 金属学报, 2009, 45: 937)
[11]	Wang H J, Wang H, Zhang R Q, et al. Effect of high strain amplitude and pre-deformation on damping property of Fe-Mn alloy [J]. J. Alloys Compd., 2019, 770: 252
[12]	Lee Y K, Jun J H, Choi C S. Damping capacity in Fe-Mn binary alloys [J]. ISIJ Int., 1997, 37: 1023
[13]	Warren B E. X-Ray Diffraction [M]. New York: Dover Publications, 1990: 285
[14]	Kwon K H, Suh B C, Baik S I, et al. Deformation behavior of duplex austenite and ε-martensite high-Mn steel [J]. Sci. Technol. Adv. Mater., 2013, 14: 014204 pmid: 27877552
[15]	Pramanik S, Gazder A A, Saleh A A, et al. Nucleation, coarsening and deformation accommodation mechanisms of ε-martensite in a high manganese steel [J]. Mater. Sci. Eng., 2018, A731: 506
[16]	Cohen J B, Wagner C N J. Determination of twin fault probabilities from the diffraction patterns of fcc metals and alloys [J]. J. Appl. Phys., 1962, 33: 2073
[17]	Jiang B H, Qi X, Zhou W M, et al. Comment on "Influence of austenite grain size on γ→ε martensitic transformation temperature in Fe-Mn-Si-Cr alloys" [J]. Scr. Mater., 1996, 34: 771
[18]	Yang J H, Wayman C M. On secondary variants formed at intersections of ε martensite variants [J]. Acta Metall. Mater., 1992, 40: 2011
[19]	Li B, Yan P F, Sui M L, et al. Transmission electron microscopy study of stacking faults and their interaction with pyramidal dislocations in deformed Mg [J]. Acta Mater., 2010, 58: 173
[20]	Ma R Z, Wang S L. The γ→ε martensitic transformation in iron-manganese alloys [J]. Trans. Met. Heat Treat., 1982, (2): 27
	(马如璋, 王世亮. 铁锰合金中γ→ε马氏体相变 [J]. 金属热处理学报, 1982, (2): 27)
[21]	Xu Z Y. Martensitic Transformation and Martensite [M]. 2nd Ed., Beijing: Science Press, 1999: 133
	(徐祖耀. 马氏体相变与马氏体 [M]. 第2版,北京: 科学出版社, 1999: 133)
[22]	Olson G B, Cohen M. A general mechanism of martensitic nucleation: Part I. General concepts and the FCC→HCP transformation [J]. Metall. Trans., 1976, 7A: 1897
[23]	Nakano J, Jacques P J. Effects of the thermodynamic parameters of the hcp phase on the stacking fault energy calculations in the Fe-Mn and Fe-Mn-C systems [J]. Calphad, 2010, 34: 167
[24]	Takaki S, Nakatsu H, Tokunaga Y. Effects of austenite grain size on ε martensitic transformation in Fe-15mass%Mn alloy [J]. Mater. Trans., JIM, 1993, 34: 489
[25]	Jun J H, Choi C S. Variation of stacking fault energy with austenite grain size and its effect on the M_S temperature of γ→ε martensitic transformation in Fe-Mn alloy [J]. Mater. Sci. Eng., 1998, A257: 353
[26]	Guo Z H, Rong Y H, Chen S P, et al. Formation mechanism of thermally induced ε-martensite in Fe-Mn-Si based shape memory alloys [J]. J. Shanghai Jiaotong Univ., 1998, 32(2): 43
	(郭正洪, 戎咏华, 陈世朴等. Fe-Mn-Si系形状记忆合金中热诱发ε马氏体的形成机制 [J]. 上海交通大学学报, 1998, 32(2): 43)
[27]	Jun J H, Lee Y K, Choi C S. Damping mechanisms of Fe-Mn alloy with (γ+ε) dual phase structure [J]. Mater. Sci. Technol., 2000, 16: 389 doi: 10.1179/026708300101507974
[28]	Huang S K, Li N, Wen Y H, et al. Effects of deep-cooling and temperature on damping capacity of Fe-Mn alloy [J]. Acta Metall. Sin., 2007, 43: 807
	(黄姝珂, 李宁, 文玉华等. 深冷处理和温度对Fe-Mn合金阻尼性能的影响 [J]. 金属学报, 2007, 43: 807)
[29]	Fan G D, Zheng M Y, Hu X S, et al. Internal friction and microplastic deformation behavior of pure magnesium processed by equal channel angular pressing [J]. Mater. Sci. Eng., 2013, A561: 100
[30]	Ma Y L, Ge T S. Dislocation damping peaks appearing within the temperature range for the direct and inverse martensitic transformations of an iron-manganese alloy [J]. Acta Phys. Sin., 1964, 20: 909
	(马应良, 葛庭燧. 铁锰合金在正、反马氏体型相变温度范围内出现的位错内耗峰 [J]. 物理学报, 1964, 20: 909) doi: 10.7498/aps.20.909
[31]	Yang X S, Sun S, Ruan H H, et al. Shear and shuffling accomplishing polymorphic fcc γ→hcp ε→bct α martensitic phase transformation [J]. Acta Mater., 2017, 136: 347 doi: 10.1016/j.actamat.2017.07.016
[32]	Jun J H, Choi C S. Strain amplitude dependence of the damping capacity in Fe-17%Mn alloy [J]. Scr. Mater., 1998, 38: 543 doi: 10.1016/S1359-6462(97)00525-3
[33]	Jee K K, Jang W Y, Baik S H, et al. Damping capacity in Fe-Mn based alloys [J]. Scr. Mater., 1997, 37: 943 doi: 10.1016/S1359-6462(97)00198-X
[34]	De A K, Cabanas N, De Cooman B C. FCC-HCP transformation-related internal friction in Fe-Mn alloys [J]. Z. Metallkd., 2002, 93: 228 doi: 10.3139/146.020228

[1]	WANG Yu, HU Bin, LIU Xingyi, ZHANG Hao, ZHANG Haoyun, GUAN Zhiqiang, LUO Haiwen. Influence of Annealing Temperature on Both Mechanical and Damping Properties of Nb-Alloyed High Mn Steel[J]. 金属学报, 2021, 57(12): 1588-1594.
[2]	Yantao YAO, Liqing CHEN, Wenguang WANG. Damping Capacities of (B₄C+Ti) Hybrid Reinforced Mg and AZ91D Composites Processed by In Situ Reactive Infiltration Technique[J]. 金属学报, 2019, 55(1): 141-148.
[3]	Xiaofeng HU,Yubin DU,Desheng YAN,Lijian RONG. Cu Precipitation and Its Effect on Damping Capacity and Mechanical Properties of FeCrMoCu Alloy[J]. 金属学报, 2017, 53(5): 601-608.
[4]	LIU Gang SUN Yali HU Jin ZHOU Ke. DAMPING CAPACITY OF Bi₂O₃–COATED Al₁₈B₄O₃₃WHISKER REINFORCED Al MATRIX COMPOSITES[J]. 金属学报, 2010, 46(8): 979-983.
[5]	HUANG Shuke LIU Jianhui LI Chang'an ZHOU Danchen LI Ning WEN Yuhua. EFFECT OF PRE-DEFORMATION ON STACKING FAULT PROBABILITY AND DAMPING CAPACITY OF Fe-Mn ALLOY[J]. 金属学报, 2009, 45(8): 937-942.
[6]	HU Xiaofeng LI Xiuyan ZHANG Bo RONG Lijian LI Yiyi. INFLUENCES OF ADDITIONS OF Nb, Ti AND Cu ON DAMPING CAPACITY AND CORROSION RESISTANCE OF Fe--13Cr--2.5Mo ALLOY[J]. 金属学报, 2009, 45(6): 717-722.
[7]	XIAO Fu ZHAO Xinqing XU Huibin JIANG Haichang RONG Lijian. DAMPING CAPACITY AND MECHANICAL PROPERTY OF NiTiNb SHAPE MEMORY ALLOYS[J]. 金属学报, 2009, 45(1): 18-24.
[8]	Xu Yun-Wei; MA Tian-Yu; Mi YAN. MAGNETOSTRICTION IN ANTIFERROMAGNETIC Fe1-xMnx (0.30 ≤ x ≤ 0.55) ALLOYS[J]. 金属学报, 2008, 44(10): 1235-1237 .
[9]	Shu-Ke Huang; LI Ning. Effect of deep-cooling and measurement temperature on damping capacity of Fe-Mn alloy[J]. 金属学报, 2007, 43(8): 807-812 .
[10]	LIN Renrong; LIU Fang; CAO Mingzhou; YANG Rui. INFLUENCE OF ANNEALING AND SUBSTITUTION ELEMENTS ON DAMPING CAPACITY AND STRENGTH OF Fe-Cr-Al BASED ALLOYS[J]. 金属学报, 2005, 41(9): 958-962 .
[11]	WANG Weiguo; ZHOU Bangxin; ZHENG Zhongmin(Laboratory for Nuclear Fuel and Materials; Nuclear Power Institute of China; Chengdu 610041)Correspondent: WANG Weiguo; Tel: (028)5582199-88531. DAMPING CAPACITY OF Fe-Cr-Al-Si ALLOYS[J]. 金属学报, 1998, 34(10): 1039-1042.
[12]	TAN Yanchang;ZHAO Yuhua;WEI Suning Northeast University of Technology; Shenyang. EFFECT OF TEMPERING ON SHEAR MODULUS OF Fe-Mn BASE ALLOYS[J]. 金属学报, 1991, 27(4): 30-33.
[13]	YANG Minjie;CHEN Bingzhao Shanghai Institute of Metallurgy; Academia Sinica. SEPARATION AND CONCENTRATION OF Kr AND Xe FROM HYDROGEN USING TiFe_(0.86)Mn_(0.1) ALLOY[J]. 金属学报, 1988, 24(2): 194-198.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed