個人簡介:
王高峰,男,1982年7月生,内蒙古包頭人,博士,教授,碩士生導師。
教育背景:
2008.03-2012.03于西班牙薩拉戈薩大學攻讀凝聚态物理專業博士學位
2004.09-2007.07于内蒙古師範大學攻讀凝聚态物理專業碩士學位
2000.09-2004.07于内蒙古師範大學攻讀物理學教育專業學士學位。
工作經曆:
2019.01-今 伟德投注官网下载,教授
2016.01-2018.12 伟德投注官网下载,副教授
2012.07-2015.12 伟德投注官网下载,講師
講授課程:
《大學物理》、《熱學》、《大學物理實驗》
研究方向:
磁性材料研究
科研項目:
[1] 内蒙古自治區自然科學基金(2021LHMS01005):硬磁粉對Mn-Fe-P-Si合金磁性能的影響機制,項目主持人,2021.01-2023.12
[2] 國家自然科學基金(11564030):NaZn13型混合稀土-Fe-Si基合金的吸氫行為及相關磁性能研究,項目主持人,2016.01.01-2019.12.31
[3] 内蒙古自治區高等學校“青年科技英才支持計劃”(NJYT-18-B07),項目主持人,2018.01.01-2019.12.31
[4] 内蒙古自治區自然科學基金(2017MS0110):放電等離子燒結MnFe基化合物的微觀結構演變與磁特性關系的研究,項目主持人,2017.01.01 -2019.12.31
[5] 内蒙古自治區留學人員科技活動擇優資助項目:白雲鄂博共伴生混合稀土基室溫磁制冷材料的制備與性能研究,項目主持人,2018.01.01-2018.12.31
[6] 内蒙古自治區高等學校科學技術研究項目:Fe-Mn-Zr-B軟磁非晶合金的可控制備及磁熱效應研究,項目主持人,2014.01.01-2016.12.31
[7] 伟德投注官网下载青年學術骨幹培養專項項目(2016YQL02):放電等離子燒結MnFe基化合物的磁熱效應研究,項目主持人,2016.07.01-2018.06.30
[8] 國家重點研發項目(2016YFB0700903):高豐度稀土永磁材料的高通量規模組合式制備技術研究,項目參與人,2016.07.01-2020.06.30
榮譽獎勵:
[1] 入選2021年内蒙古自治區“新世紀321人才工程”二層次
[2] 入選2018年度内蒙古自治區高等學校“青年科技英才支持計劃”
[3] 獲内蒙古自治區自然科學獎二等獎1項
[4] 獲内蒙古自治區科技進步獎二等獎1項。
學術兼職:
《International Journal of Multifunctional Materials and Photoscience》期刊的編委員會成員,《Journal of Alloys and Compounds》、《Scientific Reports》、《Journal of Physics and Chemistry of Solids》、《Journal of Magnetism and Magnetic Materials》、《Ceramics International》、《稀土》等期刊審稿人。
授權專利:
[1] 王高峰,趙增茹,等,一種錳鐵基室溫磁制冷材料及其制備方法,ZL201810473757.0,2019
[2] 王高峰,譚欣,等,一種具有低熱滞的錳鐵基磁制冷材料及其制備方法和應用,ZL201911294212.4,2021
代表性論著:
專著:
[1] GaoFeng Wang,Magnetic and Calorimetric Study of the Magnetocaloric Effect in Intermetallics Exhibiting First-order Magnetostructural Transitions,Prensas Universitarias de Zaragoza,pp1-260, ISBN 978-84-15538-29-5, 2012
[2] 王高峰,趙增茹,磁制冷材料的相變與磁熱效應,哈爾濱工業大學出版社,pp1-136, ISBN 978-7-5603-6652-4, 2017
學術論文:
[1] G.F. Wang,W, Ren, B.Y. Yang, Study on magnetocaloric effect and pahse transition in La0.7(La-Ce)0.3FexAl11.5-xSi1.5alloys, Intermetallics, 136 (2021) 107269(SCI收錄)
[2] G.F. Wang, X. Tan et al., Hydrogenation and magnetocaloric effect in La-excessive LaxFe11.5Si1.5Hδalloys, Journal of Alloys and Compounds, 816 (2020) 152614(SCI收錄)
[3] G.F. Wang, Z.R. Zhao, T. Jing et al., Enhanced magnetocaloric properties in off-stoichiometric LaxFe11.5Si1.5alloys, Intermetallics, 93 (2018) 355(SCI收錄)
[4] G.F. Wang, Z.R. Zhao et al., Peculiar effect of rare earth doping on magnetic and magnetocaloric properties in Fe-rich amorphous ribbons, Journal of Alloys and Compounds, 735 (2018) 104(SCI收錄)
[5] G.F. Wang, Z.R. Zhao et al., Enhancement of magnetocaloric effect in mischmetal doped La-Fe-Si alloys, 8 (2018) 056413(SCI收錄)
[6] G.F. Wang, B.Y. Yang et al., A Comparative Study of the Magnetocaloric Effect in MnFePSiGeB Prepared by Traditional Sintering and Spark Plasma Sintering, IEEE Transactions on Magnetics, 55 (2019) 2500705(SCI收錄)
[7] G.F. Wang, H.L. Li et al., Stable magnetocaloric effect and refrigeration capacity in Co-doped FeCoMnZrNbB amorphous ribbons near room temperature, Journal of Alloys and Compounds, 692 (2017) 793(SCI收錄)
[8] G.F. Wang, Z.R. Zhao et al., Magnetocaloric effect and critical behavior in Fe-doped La0.67Sr0.33Mn1-xFexO3manganites, Ceramics International, 42 (2016) 18196(SCI收錄)
[9] G.F. Wang, H.L. Li et al., Journal of Superconductivity and Novel Magnetism, 29 (2016) 1837(SCI收錄)
[10] G. F. Wang, Z. R. Zhao et al., Effect of non-stoichiometry on the structural, magnetic and magnetocaloric properties of La0.67Ca0.33Mn1+δO3, J. Magn. Magn. Mater., 397 (2016) 198(SCI收錄)
[11] G.F. Wang, Z.R. Zhaoet al., Tunable Curie temperature and magnetocaloric effect in Mg-doped (La,Sr)MnO3manganites, IEEE Transactions on Magnetics, 51 (2015) 2502704(SCI收錄)
[12] G.F. Wang, Z.R. Zhao et al., Influence of demagnetizing field on the magnetocaloric effect and critical behavior in Mn39Co26Ge35, Journal of Alloys and Compounds, 651 (2015) 72(SCI收錄)
[13] G.F. Wang, Z.R. Zhao et al., Enhancement of refrigeration capacity and table-like magnetocaloric effect in La0.8Ca0.2MnO3/La0.8K0.2MnO3nanocrystalline composite, Ceramics International, 41 (2015) 9035(SCI收錄)
[14] 王高峰,趙增茹,等,La0.9Ce0.1Fe11.44Si1.56化合物吸氫反應動力學機理,材料熱處理學報, 36 (2015) 27.(EI收錄)
[15] G.F. Wang,L.J. Mu et al., Hydriding and dehydriding kinetics in magnetocaloric La(Fe,Si)13compounds,Journal of Applied Physics, 115 (2014) 143903(SCI收錄)
[16] G.F. Wang, L.R. Li et al., Structural and magnetocaloric effect of Ln0.67Sr0.33MnO3(Ln=La, Pr and Nd) nanoparticles,Ceramics International, 40 (2014) 16449(SCI收錄)
[17] G.F. Wang, E. Palacios et al., Comparative analysis of magnetic and caloric determinations of the magnetocaloric effect in Mn0.99Co0.01As, EPJ Web of Conferences, 75 (2014) 04003(ISTP收錄)
[18] G.F. Wang, Z.R. Zhaoet al., First-order phase transition and magnetocaloric effect of MnFeP0.63Ge0.12Si0.25compound, Advanced Materials Research, 1053 (2014) 37(EI收錄)
[19] G. F. Wang, Z. R. Zhao et al., Analysis of the first-order phase transition of (Mn,Fe)2(P,Si,Ge) using entropy change scaling, Journal of Physics D: Applied Physics, 46 (2013) 295001(SCI收錄)
[20] G. F. Wang, Z. R. Zhao et al., Peculiar influence of Mn/Fe ratio on the magnetic and magnetocaloric properties of Mn2−xFexP0.6Si0.25Ge0.15compounds, Journal of Alloys and Compounds, 554 (2013) 208(SCI收錄)