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王慧遠

(河北工業大學黨委常委、副校長)

鎖定
王慧遠,男,1974年12月出生,博士,教授、博士生導師。國家傑出青年基金獲得者,全國優秀博士學位論文獲得者。 [1] 
現任河北工業大學黨委常委、副校長。 [2]  [4-6] 
中文名
王慧遠
國    籍
中國
出生日期
1974年12月
主要成就
國家傑出青年科學基金
性    別

目錄

  1. 1 人物經歷
  2. 教育經歷
  3. 工作經歷
  4. 2 社會兼職
  1. 3 教學科研
  2. 研究方向
  3. 講授課程
  4. 學術成就
  1. 科研項目
  2. 學術論文
  3. 所獲榮譽
  4. 治學格言

王慧遠人物經歷

王慧遠教育經歷

1994.09-1998.08 原吉林工業大學材料科學與工程學院焊接工藝及設備專業 獲學士學位 學士
1999.09-2002.03吉林大學材料科學與工程學院材料加工工程專業 獲碩士學位 碩士
2002.04-2004.12吉林大學材料科學與工程學院材料加工工程專業 獲博士學位 博士,博士學位論文獲“2007年全國百篇優秀博士學位論文”(師從姜啓川教授)。 [1]  [5] 

王慧遠工作經歷

2005年按照吉林大學“青年學術骨幹人才”引進學校,並被特評特聘為教授。2006年入選教育部“新世紀優秀人才”支持計劃;2007年獲吉林省傑出青年基金;2007年入選第二批吉林省拔尖創新人才工程;2008年獲得吉林省第十批突出貢獻中青年專業技術人才稱號。2009年被聘為博士生導師,同年擔任材料科學與工程學院副院長,分管學院科研工作。
曾任吉林大學材料科學與工程學院院長。
現任河北工業大學黨委常委、副校長。 [5] 

王慧遠社會兼職

《Scientific Reports》編委、《Journal of Materials Science & Technology》編委等。 [5] 

王慧遠教學科研

王慧遠研究方向

王慧遠教授主要從事輕合金非平衡凝固與組織控制等製備科學與加工技術研究。 [5] 
所在學科專業: 材料加工工程
所研究方向:非平衡凝固與組織控制;強韌化與塑性變形;新型能源電池;第一性原理 [1] 

王慧遠講授課程

本科生課程:《冶金原理》、《液態金屬成型研究新進展》
碩士生課程:《晶體生長》和《材料研究專題與學科最新進展》
博士生課程:《金屬材料設計與製備》 [1] 

王慧遠學術成就

入選吉林省高級專家、長白山學者、教育部新世紀優秀人才
曾獲國家技術發明二等獎和吉林省科學技術(自然類)一等獎。作為項目負責人,主持國家自然科學基金傑出青年基金、國家重點研發項目(政府間國際合作)、國家863計劃課題、973計劃子題、十二五支撐計劃專題、吉林省重大科技項目研發人才團隊項目等國家和省、部級項目25項。授權發明專利13件,發表SCI 論文124 篇,被SCI 他引1659 次;H 因子25。 [5] 

王慧遠科研項目

[1] 國家自然科學基金(青年基金),“變質高硅鎂合金非平衡凝固過程中Mg2Si生長形態的選擇規律”,批准號:50501010,經費:28.00萬元,運行日期:2006.1-2008.12,負責人:王慧遠。
[2] 國家自然科學基金(面上),“熔體內金屬間化合物的燃燒合成與非平衡凝固”,批准號:50671044,經費:28.00萬元,運行日期:2007.01-2009.12,負責人:王慧遠。
[3] 國家科技部“863”計劃,“高性能、低成本、可控陶瓷顆粒體積分數梯度增強金屬基複合材料”,批准號:2006AA03Z566,經費:100.00萬元,運行日期:2006.12-2009.11,負責人:王慧遠。
[4] 教育部“新世紀優秀人才”計劃,“鑄造過程燃燒合成陶瓷顆粒梯度增強金屬基複合材料的機制”,批准號:NCET-06-0308,經費:25.00萬元,運行日期:2007.01-2009.12,負責人:王慧遠。
[5] 全國優秀博士學位論文作者專項資金,“鎂-硅系合金中Mg2Si的變質機理”,批准號:2007B38,經費:42.00萬元,運行日期:2008.1-2010.12,負責人:王慧遠。 [1] 

王慧遠學術論文

[1] H.Y. Wang (王慧遠), Q.C. Jiang, X.L. Li, J.G. Wang, “In situ synthesis of TiC/Mg composites in molten magnesium”, Scripta Materialia, 2003; 48: 1349-1354.
[2] Q.C. Jiang, H.Y. Wang, Q.F. Guan, X.L. Li, “Effect of the temperature of molten magnesium on the thermal explosion synthesis reaction of Al-Ti-C system for fabricating TiC/Mg composite”, Advanced Engineering Materials, 2003; 5: 722-725.
[3] H.Y. Wang, Q.C. Jiang, X.L. Li, J.G. Wang, Q.F. Guan, H.Q. Liang, “In-situ synthesis of TiC from nanopowders in a molten magnesium”, Materials Research Bulletin, 2003; 38: 1387-1392.
[4] H.Y. Wang, Q.C. Jiang, Y.Q. Zhao, F. Zhao, B.X. Ma, Y. Wang, “Fabrication of TiB2 and TiB2-TiC particulate reinforced magnesium matrix composites”, Materials Science and Engineering A, 2004; 372: 109-114.
[5] Q.C. Jiang, H.Y. Wang, J.G. Wang, P. Lu, Y. Wang, B.X. Ma, “Effect of TiB2 particulate on partial remelting behavior of Mg-11Al-0.5Zn matrix composite”, Materials Science and Engineering A, 2004; 381: 224-230.
[6] H.Y. Wang, Q.C. Jiang, Y. Wang, B.X. Ma, F. Zhao, “Fabrication of TiB2 particulate reinforced magnesium matrix composites by powder metallurgy”, Materials letters, 2004; 58: 3509-3513.
[7] H.Y. Wang, Q.C. Jiang, X.L. Li, F. Zhao, “Effect of Al content on the self-propagating high-temperature synthesis reaction of Al-Ti-C system in molten magnesium”, Journal of Alloys and Compounds, 2004; 366: L9-L12.
[8] H.Y. Wang, Q.C. Jiang, Y.G. Zhao, F. Zhao, “In situ synthesis of TiB2/Mg composite by self-propagating high-temperature synthesis reaction of the Al-Ti-B system in molten magnesium”, Journal of Alloys and Compounds, 2004; 379: L4-L7.
[9] H.Y. Wang, Q.C. Jiang, B.X. Ma, Y. Wang, F. Zhao, “Fabrication of steel matrix composite locally reinforced with in situ TiB2 particulate using self-propagating high-temperature synthesis reaction of Ni-Ti-B system during casting”, Advanced Engineering Materials, 2005; 7: 58-63.
[10] H.Y. Wang, L. Huang, Q.C. Jiang, “In situ of TiB2-TiC particulates locally reinforced medium carbon steel matrix composites via the SHS reaction of Ni-Ti-B4C system during casting”, Materials Science and Engineering A, 2005; 407: 98-104.
[11] Q.C. Jiang, H.Y. Wang, Y. Wang, B.X. Ma, J.G. Wang, “Modification of Mg2Si in Mg-Si alloys with yttrium”, Materials Science and Engineering A, 2005; 392: 130-135.
[12] H.Y. Wang, Q.C. Jiang, B.X. Ma, Y. Wang, F. Zhao, “Reactive infiltration synthesis of TiB2-TiC particulates reinforced steel matrix composites”, Journal of Alloys and Compounds, 2005; 391: 55-59.
[13] H.Y. Wang, F. Zhao, Q.C. Jiang, Y. Wang, B.X. Ma “Effect of Mg addition on the self-propagating high temperature synthesis reaction in Al-Ti-C system”, Journal of Materials Science, 2005; 40: 1255-1257.
[14] H.Y. Wang, Q.C. Jiang, B.X. Ma, Y. Wang, J.G. Wang, J.B. Li, “Modification of Mg2Si in Mg–Si alloys with K2TiF6, KBF4 and KBF4+K2TiF6”, Journal of Alloys and Compounds, 2005; 387: 105–108.
[15] Q.C. Jiang, H.Y. Wang, Y.G. Zhao, X.L. Li, “Solid-state reaction behavior of Al-Ti-C powder mixture compacts”, Materials Research Bulletin, 2005; 40: 521-527.
[16] C.L. Xu, H.Y. Wang, C. Liu, Q.C. Jiang, “Growth of octahedral primary silicon in cast hypereutectic Al-Si alloys”, Journal of Crystal Growth, 2006; 291: 540-547.
[17] L. Huang, H.Y. Wang, F. Qiu, Q.C. Jiang, “Synthesis of dense ceramic particulate reinforced composites from Ni-Ti-C, Ni-Ti-B, Ni-Ti-B4C and Ni-Ti-C-B systems via the SHS reaction, arc melting and suction casting”, Materials Science and Engineering A, 2006; 422: 309-315.
[18] Y.F. Yang, H.Y. Wang, Y.H. Liang, Q.C. Jiang, Effect of nickel addition on the exothermic reaction of titanium and boron carbide, Journal of Materials Research, 2007; 22: 169-174.
[19] W.N. Zhang, H.Y. Wang, S.Q. Yin, Q.C. Jiang, “Effect of Ti/C ratio on the SHS reaction of Cr-Ti-C system”, Materials Letters, 2007; 61: 3075-3078.
[20] H.Y. Wang, S.J. Lü, M. Zha, S.T. Li, C. Liu, Q.C. Jiang, “Influence of Cu addition on the self-propagating high-temperature synthesis of Ti5Si3 in Cu-Ti-Si system”, Materials Chemistry and Physics, 2008; 111: 463-468.
[21] H.Y. Wang, W. Wang, M. Zha, N. Zheng, Z.H. Gu, D. Li, Q.C. Jiang, “Influence of the amount of KBF4 on the morphology of Mg2Si in Mg-5Si alloys”, Materials Chemistry and Physics, 2008; 108: 353-358.
[22] Y.F. Yang, H.Y. Wang, R.Y. Zhao, Y.H. Liang, Q.C. Jiang, “Reaction mechanism Self-propagating high-temperature synthesis reaction in the Ni-Ti-B4C system”, Journal of Materials Research, 2008; 23: 2519-2527.
[23] Y.F. Yang, H.Y. Wang, J.G. Wang, Q.C. Jiang, “Lattice parameter and stoichiometry of TiCx produced in alloyed Ti-C systems by self-propagating high-temperature synthesis”, Journal of the American Ceramic Society, 2008; 91: 3813-3816.
[24] Y.F. Yang, H.Y. Wang, J. Zhang, R.Y. Zhao, Y.H. Liang, Q.C. Jiang, “The lattice parameter and stoichiometry of TiCx produced in the Ti-C and Ni-Ti-C systems by self-propagating high-temperature synthesis”, Journal of the American Ceramic Society, 2008; 91: 2736-2739.
[25] H.Y. Wang, N. Zheng, W. Wang, Z.H. Gu, D. Li, Q.C. Jiang, “Modification of Mg2Si in Mg-4Si Alloys with B”, ISIJ International, 2008; 48: 1662-1664.
[26] M. Zha, H.Y. Wang, S.T. Li, S.L. Li, Q.L. Guan, Q.C. Jiang, “Influence of Al addition on the products of self-propagating high-temperature synthesis of Al-Ti-Si system”, Materials Chemistry and Physics, 2009; 114: 709-715.
[27] Y.F. Yang, H.Y. Wang, R.Y. Zhao, Q.C. Jiang, “Effect of reactant particle size on the self-propagating high-temperature synthesis reaction behaviors in the Ni-Ti-B4C system”, Metallurgical and Materials Transactions A, 2009; 40: 232-239.
[28] M. Zha, H.Y. Wang, S.J. Lü, N. Zhang, D. Li, Q.C. Jiang, “Self–propagating high–temperature synthesis of Ti5Si3/TiAl3 intermetallics”, ISIJ International, 2009; 49: 453-457.
[29] H.Y. Wang, M. Zha, B. Liu, D.M. Wang, Q.C. Jiang, “Microstructural evolution behavior of Mg–5Si–1Al alloy modified with Sr–Sb during isothermal heat treatment”, Journal of Alloys and Compounds, 2009;480 (2): L25-L28.
[30] Q.L. Guan, H.Y. Wang, S.L. Li, C. Liu, Q.C. Jiang, “Microstructure characteristics of products in Ti–Si system via combustion synthesis reaction”, Journal of Materials Science, 2009; 44 (7): 1902-1908.
[32] Y.F. Yang, H.Y. Wang, J.G. Wang, Q.C. Jiang, “Thermal explosion reaction in the Ti-C system under air atmosphere”, Metallurgical and Materials Transactions A, 2009; 40: 2514-2518.
[33] H.Y. Wang, B. Liu, W. Xiao, L.L. Jiang, M. Zha, Q.C. Jiang, “Influence of morphology and size of Mg2Si on microstructural evolution of Mg-6.2Si alloys during partial remelting”, IJIJ International, 2009; 49: 1932-1937.
[34] H.Y. Wang, M. Zha, S.J. Lü, C. Wang, Q.C. Jiang, “Reaction pathway and phase transitions in Al-Ti-Si system during differential thermal analysis”, Solid State Sciences, 2010; 12: 1347-1351.
[35] H.Y. Wang, W.P. Si, S.L. Li, N. Zhang, Q.C. Jiang, “First-principles study of the structural and elastic properties of Ti5Si3 with substitutions Zr, V, Nb and Cr”, Journal of Materials Research, 2010; 25 (12): 2317-2324.

王慧遠所獲榮譽

2006年入選教育部“新世紀優秀人才”支持計劃;
2007年獲吉林省傑出青年基金;
2007年獲“全國百篇優秀博士學位論文”獎(師從姜啓川教授);
2007年入選第二批吉林省拔尖創新人才工程;
2008年獲得吉林省第十批突出貢獻中青年專業技術人才稱號;
2012年入選第三批(第二層次)吉林省拔尖創新人才工程;
2013年獲吉林省自然科學一等獎(排名第二);
2014年獲長白山學者特聘教授稱號;
2014年獲吉林省高級專家;
2016年獲國家傑出青年基金; [1]  [3] 

王慧遠治學格言

勤奮、認真、求實、創新 [1] 
參考資料