Liliang Shao, Rongsheng Bai, Yanxue Wu, Jing Zhou, Xing Tong, Hailong Peng, Tao Liang, Zongzhen Li, Qiaoshi Zeng, Bo Zhang, Haibo Ke*, and Weihua Wang*,
Mater. Futures, 3, 025301 (2024);
36. Effect of pinning on shear banding in metallic glasses,
Yang Liu, Zhihuang Yan, Huashan Liu, Baoshuang Shang*, and Hailong Peng*,
Phys. Rev. B, 109, 054115 (2024);
35. Fast crystal growth in deeply undercooled ZrTi melts,
Zhihuang Yan, Feiqi Huang, Yanxue Wu, Huashan Liu, and Hailong Peng*,
J. Chem. Phys., 160, 044505 (2024);
该工作被美国物理联合会(AIP)公众号报道:https://mp.weixin.qq.com/s/YqN6AtkbL7pWZjkENQ-Dyg
34. Non-affine atomic rearrangement of glasses through stress-induced structural anisotropy,
Jie Dong#, Hailong Peng#*, Hui Wang#, Yang Tong*, Yutian Wang, Wojciech Dmowski, Takeshi Egami, Baoan Sun*, Weihua Wang, and Haiyang Bai*,
Nat. Phys., 19, 1896–1903 (2023);
论文在Springer Nature上的报道: “Structural anisotropy: a 'fingerprint' of atomic-scale deformation mechanism of glasses”;
该工作在Nature Physics上的专门评述:"Rearranged under stress"
该工作在中南大学新闻网上报道: https://news.csu.edu.cn/info/1003/157114.htm
33. Structural origin for composition-dependent nearest atomic distance in Cu–Zr metallic glass,
Chi Zhang, Hua-Shan Liu, and Hai-Long Peng*,
Chin. Phys. B, 32, 116101 (2023);
32. Ab initio study of chemical effect on structural properties of Ti–Al melts,
Yun Feng, Yan Feng, and Hai-Long Peng*,
Chin. Phys. B, 32, 106101 (2023);
31. High-throughput design of Co-based magnetic Heusler compounds,
Kun Hu, Ruiwen Xie, Chen Shen*, Hailong Peng, Huashan Liu*, and Hongbin Zhang,
Acta. Mater., 259, 119255 (2023);
Jing Zhou, Xuesong Li, Xibei Hou, Haibo Ke, Xingdu Fan, Junhua Luan, Hailong Peng, Qiaoshi Zeng, Hongbo Lou, Jianguo Wang, Chain Tsuan Liu, Baolong Shen, Baoan Sun*, Weihua Wang, and Haiyang Bai*,
Adv. Mater., 35, 2304490 (2023);
29. Chemically ordered structure and dynamics in Al80Ti20 liquids,
Yun Feng, Yan Feng*, Zongbo Li, Hailong Peng*
Comput. Mater. Sci., 226, 112256 (2023);
28. Local structures and undercooling ability of Zr–Ti melts,
Chi Zhang, Yun Feng, Huashan Liu, Sandro Szabó, Dirk Holland-Moritz, Zach Evenson, Fan Yang, Hailong Peng*,
J. Non-Cryst. Solids, 613, 122348 (2023);
27. Pinning effect on the correlations of nonaffine displacement in metallic glasses,
Yang Liu, Huashan Liu, Hailong Peng*,
J. Non-Cryst. Solids, 601, 122052 (2023);
26. Nonmonotonic Dynamical Correlations beneath the Surface of Glass-Forming Liquids,
Hailong Peng*, Huashan Liu, and Thomas Voigtmann*,
Phys. Rev. Lett., 129, 215501 (2022);
该工作在中南大学新闻网上报道:https://news.csu.edu.cn/info/1003/154660.htm
在科研留声机微信公众号上报道:https://mp.weixin.qq.com/s/t4uO9r_AC6UH9m7D3YMWqA
25. Spatial correlation of irreversible displacement in oscillatory-sheared metallic glasses,
Shiheng Cui, Huashan Liu, and Hailong Peng*,
Chin. Phys. B, 157, 034701 (2022);
24. Anisotropic correlations of plasticity on the yielding of metallic glasses,
Shiheng Cui, Huashan Liu, and Hailong Peng*,
Phys. Rev. E, 106, 104607 (2022);
Min Liu, Huashan Liu, and Hailong Peng*,
J. Chem. Phys. 157, 034701 (2022);
该工作被美国物理联合会(AIP)公众号报道:https://mp.weixin.qq.com/s/XO8w-p8Qfd9AoNlQFOwW-Q
22. Crystal growth in deeply undercooled Ni50Al50: Signature of the ordering sequence at the interface,
Qianjin Yang, Huashan Liu*, and Hailong Peng*,
J. Chem. Phys.154, 194503 (2021);
Min Liu, Hayato Shiba, Huashan Liu, and Hailong Peng*,
Phys. Chem. Chem. Phys., 23, 6496-6508 (2021);
20. Atomic dynamics under oscillatory shear in metallic glasses,
Hongkuan Li, Huashan Liu, and Hailong Peng*,
J. Non-Cryst. Solids, 539, 120069 (2020);
19. Ultrasonic vibration accelerated aging in La-based bulk metallic glasses,
Siyuan Chen, Song Li*, Jiang Ma, Haibin Yu, Huashan Liu*, and Hailong Peng*,
J. Non-Cryst. Solids, 535, 119967 (2020);
Fan Zhang, Yu Ren, Zhiqing Yang, Huhu Su, Zhen Lu, Chengwen Tan, Hailong Peng, Kentaro Watanabe, Bin Li, Matthew R. Barnett, and Mingwei Chen*,
Acta Mater., 188, 203 (2020);
17. Chemical effect on the structural and dynamical properties in Zr-Ni-Al liquids,
H. L. Peng*, F. Yang, S. T. Liu, D. Holland-Moritz, T. Kordel, T. Hansen, and Th. Voigtmann*,
Phys. Rev. B, 100, 104202 (2019);
16. Structural origin for vibration-induced accelerated aging and rejuvenation in metallic glasses,
Zhen-Ya Zhou, Hai-Long Peng, and Hai-Bin Yu*,
J. Chem. Phys., 150, 204507 (2019);
Hailong Peng*, Momoji Kubo and Hayato Shiba*,
Physical Chemistry Chemical Physics 20, 9796 -9805(2018).
该工作被PCCP评为该年度研究热点:https://pubs.rsc.org/en/content/articlelanding/2018/cp/c8cp00698a
14. Crystal growth in fluid flow: Nonlinear response effects,
H. L. Peng, D. M. Herlach, and Th. Voigtmann,
Phys. Rev. Materials, 1, 030401(R) (2017);
13. Five-fold local symmetry in metallic liquids and glasses,
M. Z. Li*, H. L. Peng, Y. C. Hu, F. X. Li, H. P. Zhang, and W. H. Wang,
Chinese Physics B, 26, 016104 (2017);
H. L. Peng, H. R. Schober, and Th. Voigtmann,
Phys. Rev. E94, 060601(R) (2016).
11. Decoupled length scales for diffusivity and viscosity in glass-forming liquids,
H. L. Pengand Th. Voigtmann,
Phys. Rev. E94, 042621 (2016).
10. Heterogeneous diffusion, viscosity and the Stokes Einstein relation in binary liquids
H. R. Schober* and H. L. Peng,
Phys. Rev. E93, 052507 (2016).
9. Formation and dilatation of shear bands in a Cu-Zr metallic glass: A free volume perspective,
Chunguang Tang*, Hailong Peng, Yu Chen, and Michael Ferry,
Journal of Applied Physics120, 235101 (2016).
8. Structural and dynamical properties of liquid Al-Au alloys,
H. L. Peng, Th. Voigtmann, G. Kolland, H. Kobatake, and J. Brillo,
Phys. Rev. B92, 184201 (2015).
7. Stress-versus temperature-induced structural evolution in metallic glasses,
H. L. Peng, M. Z. Li, and W. H. Wang,
Appl. Phys. Lett.102, 131908 (2013).
6. Evolution of structural and dynamic heterogeneities and activation energy distribution of deformation units in metallic glass,
W. Jiao, P. Wen, H. L. Peng, H. Y. Bai, B. A. Sun, W. H. Wang,
Appl. Phys. Lett. 102, 101903 (2013).
5. Characterization of mechanical heterogeneity in amorphous solids,
H. L. Peng, M. Z. Li, B. A. Sun, and W. H. Wang,
Journal of Applied Physics112, 023516 (2012).
4. The activation energy and volume of flow units of metallic glasses,
S.T. Liu, Z. Wang, H.L. Peng, H.B. Yu, W.H. Wang,
Scripta Mater. 67, 9 (2012).
3. Structural Signature of Plastic Deformation in Metallic Glasses,
H. L. Peng, M. Z. Li, and W. H. Wang,
Phys. Rev. Lett. 106, 135503 (2011).
2. Homogeneous deformation of metallic glass at room temperature reveals large dilatation,
H.B. Ke, P. Wen, H.L. Peng, W.H. Wang and A.L. Greer,
Scripta Mater.64, 966 (2011).
H. L. Peng, M. Z. Li, W. H. Wang, C.-Z. Wang, and K. M. Ho,
Appl. Phys. Lett.96, 021901 (2010).
该工作被Nature 子刊 NPG Asia Materials 评为亮点文章:https://www.nature.com/articles/am2010115