Regulation mechanism of aging behavior and mechanical properties of 2195-T34 Al-Li alloy at different stress levels

Fei Chen; Li-hua Zhan; Yong-qian Xu; Chun-hui Liu; Bo-lin Ma; Quan-qing Zeng; Zheng-gen Hu; Wen-li Zhu; Dong-yang Yan

doi:10.1007/s11771-023-5526-y

Journal of Central South University ›› 2024, Vol. 31 ›› Issue (1) : 11-24. DOI: 10.1007/s11771-023-5526-y

Article

Regulation mechanism of aging behavior and mechanical properties of 2195-T34 Al-Li alloy at different stress levels

Fei Chen¹ ,
Li-hua Zhan¹^,²^,³^,^b ,
Yong-qian Xu¹^,³ ,
Chun-hui Liu¹^,³ ,
Bo-lin Ma¹ ,
Quan-qing Zeng¹ ,
Zheng-gen Hu¹^,⁴ ,
Wen-li Zhu⁴ ,
Dong-yang Yan⁴

Author information +

History +

Abstract

The effect of aging on the mechanical properties of the 2195-T34 Al−Li alloy at different stress levels was investigated. When the stress was below the high-temperature yield strength (YS), the YS and elongation (EL) of the low-stress aged (LSA) and stress-free aged (SFA) specimens were similar. When the stress exceeded the high-temperature YS, the ultimate tensile stress (UTS) and EL of the specimens (HSA specimens) decreased significantly. This decrease suggested that an increase in stress reduced the damage resistance of the material. Transmission electron microscopy (TEM) and scanning electron microscopy (SEM) observations showed that variations in the effect of stress on the material properties were attributed to the combined effect of internal precipitate characteristics and Cu-rich precipitates at the grain boundary. The increase in stress induced the segregation of Cu atoms at the grain boundaries to form Cu-rich precipitates, facilitating the formation of precipitation-free zones (PFZ) at the grain boundaries. In addition, Cu-rich precipitates could act as damage nucleation sites, reducing the ductility of the material.

Keywords

Al-Li alloy / stress-aging / mechanical properties / stress levels

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Fei Chen, Li-hua Zhan, Yong-qian Xu, Chun-hui Liu, Bo-lin Ma, Quan-qing Zeng, Zheng-gen Hu, Wen-li Zhu, Dong-yang Yan. Regulation mechanism of aging behavior and mechanical properties of 2195-T34 Al-Li alloy at different stress levels. Journal of Central South University, 2024, 31(1): 11‒24 https://doi.org/10.1007/s11771-023-5526-y

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Wang S C, Starink M J. Precipitates and intermetallic phases in precipitation hardening Al−Cu−Mg−(Li) based alloys [J]. International Materials Reviews, 2005, 50(4): 193-215, CrossRef Google scholar

[2]	Honma T, Yanagita S, Hono K, et al.. Coincidence Doppler broadening and 3DAP study of the pre-precipitation stage of an Al−Li−Cu−Mg−Ag alloy [J]. Acta Materialia, 2004, 52(7): 1997-2003, CrossRef Google scholar

[3]	Gupta R K, Nayan N, Nagasireesha G, et al.. Development and characterization of Al−Li alloys [J]. Materials Science and Engineering A, 2006, 420(1–2): 228-234, CrossRef Google scholar

[4]	Liu C-H, Ma Z-Y, Ma P-P, et al.. Multiple precipitation reactions and formation of θ′-phase in a pre-deformed Al−Cu alloy [J]. Materials Science and Engineering A, 2018, 733: 28-38, CrossRef Google scholar

[5]	Abd el-aty A, Xu Y, Guo X-Z, et al.. Strengthening mechanisms, deformation behavior, and anisotropic mechanical properties of Al−Li alloys: A review [J]. Journal of Advanced Research, 2017, 10: 49-67, CrossRef Google scholar

[6]	Dorin T, de Geuser F, Lefebvre W, et al.. Strengthening mechanisms of T1 precipitates and their influence on the plasticity of an Al−Cu−Li alloy [J]. Materials Science and Engineering A, 2014, 605: 119-126, CrossRef Google scholar

[7]	Donnadieu P, Shao Y, de Geuser F, et al.. Atomic structure of T1 precipitates in Al−Li−Cu alloys revisited with HAADF-STEM imaging and small-angle X-ray scattering [J]. Acta Materialia, 2011, 59(2): 462-472, CrossRef Google scholar

[8]	Araullo-Peters V, Gault B, de Geuser F, et al.. Microstructural evolution during ageing of Al−Cu−Li−X alloys [J]. Acta Materialia, 2014, 66: 199-208, CrossRef Google scholar

[9]	Kim K, Zhou B-C, Wolverton C. First-principles study of crystal structure and stability of T1 precipitates in Al−Li−Cu alloys [J]. Acta Materialia, 2018, 145: 337-346, CrossRef Google scholar

[10]	Ringer S P, Muddle B C, Polmear I J. Effects of cold work on precipitation in Al−Cu−Mg−(Ag) and Al−Cu−Li−(Mg−Ag) alloys [J]. Metallurgical and Materials Transactions A, 1995, 26(7): 1659-1671, CrossRef Google scholar

[11]	Gable B M, Zhu A W, Csontos A A, et al.. The role of plastic deformation on the competitive microstructural evolution and mechanical properties of a novel Al−Li−Cu−X alloy [J]. Journal of Light Metals, 2001, 1(1): 1-14, CrossRef Google scholar

[12]	Ma P-P, Zhan L-H, Liu C-H, et al.. Pre-strain-dependent natural ageing and its effect on subsequent artificial ageing of an Al−Cu−Li alloy [J]. Journal of Alloys and Compounds, 2019, 790: 8-19, CrossRef Google scholar

[13]	Li H Y, Kang W, Lu X C. Effect of age-forming on microstructure, mechanical and corrosion properties of a novel Al−Li alloy [J]. Journal of Alloys and Compounds, 2015, 640: 210-218, CrossRef Google scholar

[14]	Hu L-B, Zhan L-H, Shen R-L, et al.. Effects of uniaxial creep ageing on the mechanical properties and micro precipitates of Al−Li−S4 alloy [J]. Materials Science and Engineering A, 2017, 688: 272-279, CrossRef Google scholar

[15]	Ma P-P, Zhan L-H, Liu C-H, et al.. Strong stress-level dependence of creep-ageing behavior in Al−Cu−Li alloy [J]. Materials Science and Engineering A, 2021, 802: 140381, CrossRef Google scholar

[16]	Zhang J, Wang C, Zhang Y, et al.. Effects of creep aging upon Al−Cu−Li alloy: Strength, toughness and microstructure [J]. Journal of Alloys and Compounds, 2018, 764: 452-459, CrossRef Google scholar

[17]	Suresh S, Vasudevan A K, Tosten M, et al.. Microscopic and macroscopic aspects of fracture in lithium-containing aluminum alloys [J]. Acta Metallurgica, 1987, 35(1): 25-46, CrossRef Google scholar

[18]	Vasudévan A K, Ludwiczak E A, Baumann S F, et al.. Grain boundary fracture in Al−Li alloys [J]. Materials Science and Technology, 1986, 2(12): 1205-1209, CrossRef Google scholar

[19]	Jha S C, Sanders T H, Dayananda M A. Grain boundary precipitate free zones in Al−Li alloys [J]. Acta Metallurgica, 1987, 35(2): 473-482, CrossRef Google scholar

[20]	Chen F, Zhan L-H, Gao T-J, et al.. Creep aging properties variation and microstructure evolution for 2195 Al−Li alloys with various loading rates [J]. Materials Science and Engineering A, 2021, 827: 142055, CrossRef Google scholar

[21]	Zhou C, Zhan L-H, Li H. Improving creep age formability of an Al−Cu−Li alloy by electropulsing [J]. Journal of Alloys and Compounds, 2021, 870: 159482, CrossRef Google scholar

[22]	Jiang D-D, Yang R-B, Wang D-F, et al.. Effect of external stress on the microstructure and mechanical properties of creep-aged Al−Cu−Li−Ag alloy [J]. Micron, 2021, 143: 103011, CrossRef Google scholar

[23]	Han J-Q, Wang H-M, Xu A-J, et al.. Enhanced matrix precipitation of T₁ (Al₂CuLi) phase in AA2055 Al−Li alloy during stress aging process [J]. Materials Science and Engineering A, 2021, 827: 142057, CrossRef Google scholar

[24]

Dorin

, Deschamps

, de Geuser

, et al.. Quantitative description of the T₁ formation kinetics in an Al−Cu−Li alloy using differential scanning calorimetry, small-angle X-ray scattering and transmission electron microscopy [J]. Philosophical Magazine, 2014, 94(10): 1012-1030,

CrossRef Google scholar

[25]	Gumbmann E, de Geuser F, Sigli C, et al.. Influence of Mg, Ag and Zn minor solute additions on the precipitation kinetics and strengthening of an Al−Cu−Li alloy [J]. Acta Materialia, 2017, 133: 172-185, CrossRef Google scholar

[26]	Gumbmann E, Lefebvre W, de Geuser F, et al.. The effect of minor solute additions on the precipitation path of an Al−Cu−Li alloy [J]. Acta Materialia, 2016, 115: 104-114, CrossRef Google scholar

[27]	Dorin T, Deschamps A, de Geuser F, et al.. Quantification and modelling of the microstructure/strength relationship by tailoring the morphological parameters of the T₁ phase in an Al−Cu−Li alloy [J]. Acta Materialia, 2014, 75: 134-146, CrossRef Google scholar

[28]	Yang J-S, Liu C-H, Ma P-P, et al.. Superposed hardening from precipitates and dislocations enhances strength-ductility balance in Al−Cu alloy [J]. International Journal of Plasticity, 2022, 158: 103413, CrossRef Google scholar

[29]	Rodgers B I, Prangnell P B. Quantification of the influence of increased pre-stretching on microstructure-strength relationships in the Al−Cu−Li alloy AA2195 [J]. Acta Materialia, 2016, 108: 55-67, CrossRef Google scholar

[30]	Zhang Q, Wu Y-N, Li T-F, et al.. Significant enhancement in tensile strength of room-temperature rolled Al−8Zn−1Mg alloy induced by profuse microbands [J]. Materials Science and Engineering A, 2022, 861: 144359, CrossRef Google scholar

[31]	Chen Y-M, Wu Y-N, Li Y, et al.. RT ECAP and rolling bestow high strength and good ductility on a low lithium aluminum alloy [J]. Journal of Materials Research and Technology, 2023, 25: 5561-5574, CrossRef Google scholar

[32]	Zhuo X-R, Zhang Q, Liu H, et al.. Enhanced tensile strength and ductility of an Al−6Si−3Cu alloy processed by room temperature rolling [J]. Journal of Alloys and Compounds, 2022, 899: 163321, CrossRef Google scholar

[33]	Wang X-M, Shao W-Z, Jiang J-T, et al.. Quantitative analysis of the influences of pre-treatments on the microstructure evolution and mechanical properties during artificial ageing of an Al−Cu−Li−Mg−Ag alloy [J]. Materials Science and Engineering A, 2020, 782: 139253, CrossRef Google scholar

[34]	Zhang J, Li Z-D, Xu F-S, et al.. Regulating effect of pre-stretching degree on the creep aging process of Al−Cu−Li alloy [J]. Materials Science and Engineering A, 2019, 763: 138157, CrossRef Google scholar

[35]	Yang X-H, Wang J-S, Zhang M-S, et al.. Achieving high strength and ductility of Al−Cu−Li alloy via creep aging treatment with different pre-strain levels [J]. Materials Today Communications, 2021, 29: 102898, CrossRef Google scholar

[36]	Decreus B, Deschamps A, Donnadieu P, et al.. On the role of microstructure in governing fracture behavior of an aluminum-copper-lithium alloy [J]. Materials Science and Engineering A, 2013, 586: 418-427, CrossRef Google scholar

[37]	Zhou C, Zhan L-H, Li H. Improving creep age formability of an Al−Cu−Li alloy by electropulsing [J]. Journal of Alloys and Compounds, 2021, 870: 159482, CrossRef Google scholar

[38]	Brodusch N, Trudeau M, Michaud P, et al.. Contribution of a new generation field-emission scanning electron microscope in the understanding of a 2099 Al−Li alloy [J]. Microscopy and Microanalysis, 2012, 18(6): 1393-1409, CrossRef Google scholar

[39]	Lei C, Li H, Zheng G W, et al.. Thermal-mechanical loading sequences related creep aging behaviors of 7050 aluminum alloy [J]. Journal of Alloys and Compounds, 2018, 731: 90-99, CrossRef Google scholar

[40]	Deschamps A, Fribourg G, Br’echet Y, et al.. In situ evaluation of dynamic precipitation during plastic straining of an Al−Zn−Mg−Cu alloy [J]. Acta Materialia, 2012, 60(5): 1905-1916, CrossRef Google scholar

[41]	Prasad N E, Prasad K S, Kamat S V, et al.. Influence of microstructural features on the fracture resistance of aluminium-lithium alloy sheets [J]. Engineering Fracture Mechanics, 1995, 51(1): 87-96, CrossRef Google scholar