Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Zheng, Qiang
Ma, Han
Ma, En
and
Xu, Jian
2006.
Mg–Cu–(Y,Nd) pseudo-ternary bulk metallic glasses: The effects of Nd on glass-forming ability and plasticity.
Scripta Materialia,
Vol. 55,
Issue. 6,
p.
541.
Zheng, Qiang
Xu, Jian
and
Ma, Evan
2007.
High glass-forming ability correlated with fragility of Mg–Cu(Ag)–Gd alloys.
Journal of Applied Physics,
Vol. 102,
Issue. 11,
Li, Y.
Poon, S. J.
Shiflet, G. J.
Xu, J.
Kim, D. H.
and
Löffler, J. F.
2007.
Formation of Bulk Metallic Glasses and Their Composites.
MRS Bulletin,
Vol. 32,
Issue. 8,
p.
624.
Ma, Han
Shi, Ling-Ling
Xu, Jian
and
Ma, En
2007.
Chill-cast in situ composites in the pseudo-ternary Mg–(Cu,Ni)–Y glass-forming system: Microstructure and compressive properties.
Journal of Materials Research,
Vol. 22,
Issue. 2,
p.
314.
Wang, Yan-Ling
and
Xu, Jian
2008.
Ti (Zr)-Cu-Ni Bulk Metallic Glasses with Optimal Glass-Forming Ability and Their Compressive Properties.
Metallurgical and Materials Transactions A,
Vol. 39,
Issue. 12,
p.
2990.
Zhang, Li
Zhuo, Mu-Jin
and
Xu, Jian
2008.
Enhancing bulk metallic glass formation in Ni–Nb–Sn-based alloys via substitutional alloying with Co and Hf.
Journal of Materials Research,
Vol. 23,
Issue. 3,
p.
688.
Zhang, Li
Shi, Ling-ling
and
Xu, Jian
2009.
Hf–Cu–Ni–Al bulk metallic glasses: Optimization of glass-forming ability and plasticity.
Journal of Non-Crystalline Solids,
Vol. 355,
Issue. 16-17,
p.
1005.
Sun, Y.
Zhang, H.F.
Fu, H.M.
Wang, A.M.
and
Hu, Z.Q.
2009.
Mg–Cu–Ag–Er bulk metallic glasses with high glass forming ability and compressive strength.
Materials Science and Engineering: A,
Vol. 502,
Issue. 1-2,
p.
148.
Suo, Z.Y.
Qiu, K.Q.
Li, Q.F.
You, J.H.
Ren, Y.L.
and
Hu, Z.Q.
2010.
A new parameter to evaluate the glass-forming ability of bulk metallic glasses.
Materials Science and Engineering: A,
Vol. 528,
Issue. 1,
p.
429.
Hui, X.
Sun, G.Y.
Zhang, C.M.
Liu, S.N.
Wang, E.R.
Wang, M.L.
and
Chen, G.L.
2010.
Mg–Cu–Y–Ag bulk metallic glasses with enhanced compressive strength and plasticity.
Journal of Alloys and Compounds,
Vol. 504,
Issue. ,
p.
S6.
Gebert,, A.
2011.
Corrosion of Magnesium Alloys.
p.
207.
Peng, Hao
Li, Shuang Shou
Qi, Yun Peng
and
Huang, Tian You
2011.
Mg–Ni–Gd–Ag bulk metallic glass with improved glass-forming ability and mechanical properties.
Intermetallics,
Vol. 19,
Issue. 7,
p.
829.
Carow-Watamura, U.
Louzguine, D. V.
and
Takeuchi, A.
2011.
Physical Properties of Ternary Amorphous Alloys. Part 3: Systems from Cr-Fe-P to Si-W-Zr.
Vol. 37B3,
Issue. ,
p.
90.
Wang, Shao-Gang
Shi, Ling-Ling
and
Xu, Jian
2011.
Mg-based bulk metallic glasses: Elastic properties and their correlations with toughness and glass transition temperature.
Journal of Materials Research,
Vol. 26,
Issue. 7,
p.
923.
Laws, K.J.
Saxey, D.W.
McKenzie, W.R.
Marceau, R.K.W.
Gun, B.
Ringer, S.P.
and
Ferry, M.
2012.
Analysis of dynamic segregation and crystallisation in Mg65Cu25Y10 bulk metallic glass using atom probe tomography.
Materials Science and Engineering: A,
Vol. 556,
Issue. ,
p.
558.
Tan, J.
Pan, F.S.
Zhang, Y.
Wang, Z.
Stoica, M.
Sun, B.A.
Kühn, U.
and
Eckert, J.
2012.
Effect of Fe addition on glass forming ability and mechanical properties in Zr–Co–Al–(Fe) bulk metallic glasses.
Materials Science and Engineering: A,
Vol. 539,
Issue. ,
p.
124.
Takeuchi, Akira
and
Inoue, Akihisa
2012.
Compositional features of bulk metallic glasses analyzed with a tetrahedral composition diagram from s-, p-, d- and f-blocks.
International Journal of Materials Research,
Vol. 103,
Issue. 9,
p.
1102.
Wang, Shao-Gang
and
Xu, Jian
2013.
Strengthening and toughening of Mg-based bulk metallic glass via in-situ formed B2-type AgMg phase.
Journal of Non-Crystalline Solids,
Vol. 379,
Issue. ,
p.
40.
Zhao, Y.F.
Lin, D.Y.
Chen, X.H.
Liu, Z.K.
and
Hui, X.D.
2014.
Sluggish mobility and strong icosahedral ordering in Mg–Zn–Ca liquid and glassy alloys.
Acta Materialia,
Vol. 67,
Issue. ,
p.
266.
Mezbahul-Islam, Mohammad
and
Medraj, Mamoun
2015.
Thermodynamic modeling of Cu–Ni–Y system coupled with key experiments.
Materials Chemistry and Physics,
Vol. 153,
Issue. ,
p.
32.