(#共同第一作者; *通訊作者)

X. S. Yang*, S. Q. Yuan, H. Fu,andY. J. Wang*, Grain boundary-mediated plasticity accommodating thecracking process in nanograined gold: In situ observations and simulations,Scr.Mater. 194, 113693 (2021).Y. J. Duan, J. C. Qiao*, T.Wada, H. Kato,Y. J. Wang, E. Pineda, D. Crespo, Inelastic deformation ofmetallic glasses under dynamic cyclic loading,Scr. Mater. 194, 113675(2021).Y. B. Yang, Q. Yang, D. Wei, L. H. Dai, H. B. Yu, andY. J. Wang*,Unraveling strongly entropic effect on β-relaxation in metallic glass: Insightsfrom enhanced atomistic samplings over experimentally relevant timescales,Phys. Rev. B 102,174103 (2020).X. Li,D. Wei, J. Y. Zhang, X. D. Liu, Z. Li, T. Y.Wang, Q.F. He,Y. J. Wang*, J. Ma*, W. H. Wang, Y. Yang*, Ultrasonic plasticity ofmetallic glass near room temperature,Appl. Mater. Today 21, 100866(2020).F. H. Cao,Y. J. Wang*, and L. H. Dai*, Novel atomic-scale mechanism of incipient plasticity in a chemically complex CrCoNi medium-entropy alloy associated with inhomogeneity in local chemical environment,Acta Mater. 194, 283-294 (2020).D. Han, D. Wei, P. H. Cao,Y. J. Wang*, and L. H. Dai*, Statistical complexity of potential energy landscape as a dynamic signature of the glass transition,Phys. Rev. B 101,064205 (2020).D. Han, D. Wei, J. Yang, H. L. Li, M. Q. Jiang,Y. J. Wang*, L. H. Dai* and A. Zaccone*,Atomistic structural mechanism for the glass transition: Entropic contribution,Phys. Rev. B 101,014113 (2020).L. W. Liang,Y. J. Wang*, Y. Chen, H. Y. Wang, L. H. Dai*, Dislocation nucleation and evolution at the ferrite-cementite interface under cyclic loadings,Acta Mater.186, 267-277 (2020).X. F. Liu, Z. L. Tian, X. F. Zhang, H. H. Chen, T. W. Liu, Y. Chen,Y. J. Wang, L. H. Dai*, “Self-sharpening” tungsten high-entropy alloy,Acta Mater.186, 257-266 (2020).J. Ma, C. Yang, X. D. Liu, B. S. Shang, Q. F. He, F. C. Li, T. Y. Wang, D. Wei, X. Liang, X. Y. Wu,Y. J. Wang, F. Gong*, P. F. Guan*, W. H. Wang* and Y. Yang*, Fast surface dynamics enabled cold joining of metallic glasses,Sci. Adv. 5, eaax7256 (2019).D. Wei, J. Yang, M. Q. Jiang, B. C. Wei,Y. J. Wang*and L. H. Dai*,Revisiting the structureu2013property relationships of metallic glasses: Common spatial correlation revealed as a hidden rule,Phys. Rev. B 99,014115 (2019). (Figure was featured as a PRB Kaleidoscope)J. Yang,Y. J. Wang*, A. Zaccone, E. Ma, L. H. Dai and M. Q. Jiang*,Structural Parameter of Orientational Order to Predict the Boson Vibrational Anomaly in Glasses,Phys. Rev. Lett.122,015501 (2019).D. Wei, J. Yang, M. Q. Jiang, L. H. Dai,Y. J. Wang, J. Dyre, I. Douglass and Peter Harrowell, Assessing the Utility of Structure in Amorphous Materials,J. Chem. Phys. 150, 114502 (2019).Z. Y. Yang,Y. J. Wang* and L. H. Dai*, Susceptibility of shear banding to chemical short-range order in metallic glasses,Scr. Mater. 162, 141 (2019).Y. J. Wang*, J. P. Du, S. Shinzato, L. H. Dai* and S. Ogata*, A free energy landscape perspective on the nature of collective diffusion in amorphous solids,Acta Mater. 157, 165 (2018).B. Y. Cui, J. Yang, J. C. Qiao, M. Q. Jiang, L. H. Dai,Y. J. Wang*and A. Zaccone*, Atomic theory of viscoelastic response and memory effects in metallic glass,Phys. Rev. B96, 094203 (2017).Z. L. Tian,Y. J. Wang, Y. Chen and L. H. Dai*, Strain gradient drives shear banding in metallic glass,Phys. Rev. B96, 094103 (2017).M. Q. Jiang*, M. Peterlechner,Y. J. Wang, W. H. Wang, F. Jiang, L. H. Dai and G. Wilde, Universal structural softening in metallic glasses indicated by boson heat capacity peak,Appl. Phys. Lett. 111, 261901 (2017).J. C. Qiao,Y. J. Wang*, L. Z. Zhao, L. H. Dai, D. Crespo, J. M. Pelletier, L. M. Keer and Y. Yao*, Transition from stress-driven to thermally activated stress relaxation in metallic glasses,Phys. Rev. B94, 104203 (2016).J. P. Du,Y. J. Wang*, Y. C. Lo, L. Wan and S. Ogata*, Mechanism transition and strong temperature dependence of dislocation nucleation from grain boundaries: An accelerated molecular dynamics study,Phys. Rev. B94, 104110 (2016).X. S. Yang#,Y. J. Wang#, H. R. Zhai, G. Y. Wang, Y. J. Su, L. H. Dai, S. Ogata and T. Y. Zhang*, Time-, stress-, and temperature-dependent deformation in nanostructured copper: Creep tests and simulations,J. Mech. Phys. Solids 94, 191-206 (2016).X. S. Yang#,Y. J. Wang#, G. Y. Wang, H. R. Zhai, L. H. Dai and T. Y. Zhang*, Time, stress and temperature-dependent deformation in nanostructured copper: stress relaxation tests and simulations,Acta Mater. 108, 252-263 (2016).Y. J. Wang*, M. Q. Jiang, Z. L. Tian and L. H. Dai*,Direct atomic-scale evidence for shearu2013dilatation correlation in metallic glasses,Scr. Mater.112, 37 (2016).N. Miyazaki, M. Wakeda*,Y. J. Wangand S. Ogata*, Prediction of pressure-promoted thermal rejuvenation in metallic glasses,npj Comput. Mater. 2,16013 (2016).Y. J. Wang*, S. Ogata* and L. H. Dai*, Universal enthalpy-entropy compensation rule in the deformation of metallic glasses,Phys. Rev. B92,174118 (2015).J. C. Qiao,Y. J. Wang, J. M. Pelletier, Leon M. Keer, Morris E. Fine and Y. Yao*,Characteristics of stress relaxation kinetics of La₆₀Ni₁₅Al₂₅bulk metallic glass,Acta Mater. 98, 43 (2015).Y. J. Wang*, G. J. Gao and S. Ogata*,Atomistic understanding of diffusion kinetics in nanocrystals from molecular dynamics simulations,Phys. Rev. B88, 115413 (2013).Y. J. Wang*, A. Ishii and S. Ogata*,Entropic effect on creep in nanocrystalline metals,Acta Mater. 61, 3866(2013).Y. J. Wang*, G. J. J. Gao and S. Ogata*, Size-dependent transition of deformation mechanism, and nonlinear elasticity in Ni₃Al nanowires,Appl. Phys. Lett. 102,041902(2013).Y. J. Wang*, A. Ishii and S. Ogata*,Transition of creep mechanism in nanocrystalline metals,Phys. Rev. B84, 224102 (2011). (Figure was featured as a PRB Kaleidoscope)Y. J. Wang*and C. Y. Wang, A comparison of the ideal strength between L1₂Co₃(Al,W) and Ni₃Al under tension and shear from first-principles calculations,Appl. Phys. Lett. 94, 261909 (2009).Y. J. Wang*and C. Y. Wang, Influence of the alloying element Re on the ideal tensile and shear strength of-Ni₃Al,Scr. Mater.61, 179-200 (2009).

-主持項目-

1.國家自然科學基金面上項目，2021-2024；新型無序固體塑性變形微觀機制的熵效應

2. 國家自然科學基金面上項目，2017-2020；金屬玻璃應力松弛與蠕變多級動力學跨時間尺度計算機模擬

3. 國家重點研發(fā)計劃材料基因工程關鍵技術與支撐平臺重點專項，2017-2020；高通量并發(fā)式材料計算算法和軟件；任務負責人。

4. 國家自然科學基金青年科學基金，2015-2017；非晶/納米晶復合材料原子尺度塑性機制

5.中國科學院青年創(chuàng)新促進會會員人才專項經(jīng)費，2017-2020

-參與項目-

1. 國家重點研發(fā)計劃材料基因工程關鍵技術與支撐平臺重點專項，2017-2020；多場耦合條件下金屬結(jié)構(gòu)材料損傷演化行為的跨尺度關聯(lián)評價；研究骨干。

2.國家自然基金重大項目，2017-2020；無序合金塑性流動與強韌化機理；研究骨干。

3. 中國科學院“超常環(huán)境下系統(tǒng)力學問題研究與驗證”先導專項（B類）項目，2016-2020；研究骨干。

4. 中國科學院前沿科學重點研究項目，2017-2021；新型高強金屬材料剪切帶的涌現(xiàn)與調(diào)控；參與。