教师主页移动版

马宗青 教师名称：马宗青 教师拼音名称：Ma Zongqing 出生日期：1983-03-20 性别：男 职称：副教授 其他联系方式 邮箱：mzq0320@163.com 基本信息 研究方向 获奖情况 论文成果 Areas of research interestSuperconducting materials; W-based Alloys; Material thermodynamics and kinetics; sintering kineticsHonors and awardsAustralian Discovery Early Career Researcher Award 2014Excellent Doctoral Dissertations of Tianjin 2013Research projectsThe in-situ preparation of composite precursor for Y2O3 dispersion strengthened tungsten-based plasma facing materials and their sintering behavior National Natural Science Fund projectStudy on the formation mechanism of sintering texture in Fe-based superconducting materials and their current carrying capability National Natural Science Fund projectSelected publications (Journal articles, patents and books)[1] Qiu WB, Ma ZQ*, Liu YC, Shahriar Al Hossain M, Wang XL, Cai CB, Dou SX, Tuning superconductivity in FeSe thin films via Magnesium doping. ACS Appl. Mater. Interfaces 8 (2016) 7891-7896[2] Cheng F, Liu YC, Ma ZQ*, Shahriar Al Hossain M, Somer M, Improved Superconducting properties in the Mg11B2 low activation superconductor prepared by low-temperature sintering. Scientific Reports 6 (2016) 25498[3] Chen N, Liu YC, Ma ZQ*, Yu LM, Li HJ, Improvement in structure and superconductivity of bulk FeSe0.5Te0.5 superconductors by optimizing sintering temperature. Scripta Mater. 112 (2016)152-155[4] Chen N,Liu YC,Ma ZQ*, Li HJ, Significant enhancement of superconducting properties in the FeSe0.5Te0.5 bulks by minor Sn addition. Materials Letters 175 (2016)16-19[5] Chen N, Liu YC, Ma ZQ*, Li HJ, M. Shahriar Al Hossain, Enhancement of superconductivity in the sintered FeSe0.5Te0.5 bulks with proper amount of Sn addition. J. Alloys Compd. 633 (2015) 233-236[6] Liu YC, Lan F, Ma ZQ*, Chen N, Li HJ, Barua S, Patel D, Shahriar Al Hossain M, Acar S, Kim JH, Dou SX, Significantly enhanced critical current density in nano MgB2 grains formed at low temperature with homogeneous carbon doping. Supercond. Sci. Technol. 28 (2015) 055005[7] Cheng F, Liu YC, Ma ZQ*, Li HJ, M. Shahriar Al Hossain, Superior critical current density obtained in Mg11B2 low activation superconductor by using reactive amorphous 11B and optimizing sintering temperature. J. Alloys Compd. 650 (2015) 508-513[8] Barua S, Shahriar Al Hossain M, Ma Z, D. Patel, M. Mustapic, M. Somer, "Superior critical current density obtained in MgB2 bulks through low-cost carbon-encapsulated boron powder," Scripta Mater. vol. 104, pp. 37-40, 2015..[9] Lan F, Ma ZQ*, Liu YC, Chen N, Cai Q, Li HJ, Barua S, Patel D, Shahriar Al Hossain M, Kim JH, Dou SX, The formation of nano-layered grains and their enhanced superconducting transition temperature in Mg-doped FeSe0.9 bulks. Scientific Reports 4 (2014) 6481[10] Chen N,Ma ZQ*, Liu YC, Li XT, Cai Q, Li HJ, Yu LM, Influence of Sn doping on the phase formation and superconductivity of FeSe0.93,J. Alloys Compd.588 (2014) 418-421 [11] Ma ZQ, Liu YC , Cai Q, Yu LM, Significant improvement in the critical current density of MgB2 bulks in situ sintered at low temperature by excess Mg addition Physica C 496 (2014) 49-52[12] Ma ZQ, Dong ML, Liu YC, The sintering process and reaction kinetics of Fe-Se system after ball milling treatment. J. Supercond. Nov. Magn. 27 (2014) 775-780.[13] Xiong J, Cai Q, Ma ZQ*, Yu LM, Liu YC*, Enhancement of Critical Current Density in MgB2 Bulk with CNT-coated Al Addition. J. Supercond. Nov. Magn. 27 (2014) 1659-1664. [14] Cai Q, Liu YC, Ma ZQ, Yu LM, Xiong J, Li HJ. Pinning behavior of glycine-doped MgB2 bulks with excellent critical current density by Cu-activated low-temperature sintering. J. Alloys Compd. 585 (2014) 78-84.[15] Cai Q, Liu YC, Ma ZQ, Yu LM. Effects of MgO evolution on the critical current density in bulk MgB2 containing histidine. Physica C 496 (2014) 53-57.[16] Cai Q, Liu YC, Ma ZQ, Yu LM. Comparison of carbon-doped MgB2 bulks fabricated from pre-synthesized Mg/CNT and Mg/amorphous carbon composites. Appl Phys A-Mater Sci Process. 114 (2014) 919-924.[17] Ma ZQ, Liu YC, Cai Q, Jiang H, Yu LM, Excellent Jc in the low-temperature sintered MgB2 superconductors consisted of uncompleted MgB2 phase and residual Mg. Mater. Chem. Phys. 141 (2013) 378-382.[18] Jiang H, Ma ZQ*, Liu YC,Dong ZZ, Yu LM, Cai Q, Wang R, The effect of ball-milling treatment of original powders on the sintering process and critical current density of graphite-doped MgB2 bulks., J. Mater. Sci. 48 (2013) 2485-2489.[19] Cai Q, Liu YC, Ma ZQ, Li HJ, Yu LM, Variation of pinning mechanism and enhancement of critical current density in MgB2 bulk containing self-generated coherent MgB4 impurity. Appl. Phys. Lett 103 (2013) 132601.[20] Li XT, Gao ZM, Liu YC, Ma ZQ, Yu LM, Li HJ, Yang HZ, The microstructures and superconducting properties of FeSe0.5Te0.5 bulks with original milled powders. Cryogenics, 57 (2013) 50-54.[21] Li XT, Liu YC, Ma ZQ, Gao ZM, Characterization of low-temperature synthesized FeCr0.05Se superconductors, Cryogenics,55 (2013) 68-72.[22] Cai Q, Liu YC, Ma ZQ, Yu LM, Superconducting properties and growth mechanism of novel layered structure in MgB2 bulks with Cu/Y2O3 co-doping, J Mater Sci: Mater in Electro., 24 (2013) 1451-1457 .[23] Cai Q, Liu YC, Ma ZQ, Cardwell DA. Fishtail effects and improved critical current density in polycrystalline bulk MgB2 containing carbon nanotubes. Physica C. 492 (2013) 6-10.[24] Li XT, Ma ZQ, Liu YC, Dong ML, Yu LM, The sintering process and superconductivity of polycrystalline milled Fe-Se, IEEE Trans. Appl. Supercon., 23 (2013) 7000405.[25] Ma ZQ, Liu YC, Cai Q, The synthesis of lamellar nano MgB2 grains with nanoimpurities flux pinning centers and their significantly improved critical current density, Nanoscale 4 (2012) 2060-2065.[26] Ma ZQ, Liu YC, Cai Q, Yu LM, Investigation of phase composition and nanoscale microstructure of high-energy ball-milled MgCu sample, Nanoscale. Res. Lett. 7 (2012) 390.[27] Jiang H, Dong ZZ, Liu YC,Ma.ZQ*, Yu LM, Cai Q, Phase formation and superconductive properties of Cu doped MgB2 sintered with milled B powder, Physica C 480 (2012) 67-70.[28] Ma ZQ, Liu YC, Cai Q, The effect of Cu addition on the phase formation and critical current density in the sugar doped MgB2 superconductor, J. Supercond. Nov. Magn. 25 (2012) 1683-1688.[29] Cai Q, Liu YC, Ma ZQ, Yu LM, Significant enhancement of critical current density in Gly-doped MgB2 bulk by tailoring the formation of MgO, Scripta Mater. 67 (2012) 92-95.[30] Cai Q, Ma ZQ, Liu YC, Yu LM, Enhancement of critical current density in glycine-doped MgB2 bulks, Materials Chemistry and Physics, 136 (2012) 778-782[31] Cai Q, Ma ZQ, Liu YC, Zhao Q, Gao ZM, Effects of ball milling on the sintering process and superconducting properties of (MgB2)0.96Ni0.04 Bulks, IEEE Trans. Appl. Supercon.22 (2012) 6800405. [32] Li XT, Gao ZM, Liu YC, Ma ZQ, Yu LM, Influence of Pre-milling Time on The Sintering Process and Superconductive Properties of FeSe, IEEE Trans. Appl. Supercon. 22 (2012) 730015.[33] Cai Q, Liu YC, Ma ZQ, Dong ZZ, Superconducting properties of Y2O3/SiC Co-doped bulk MgB2, J. Supercond. Nov. Magn. 25 (2012) 357-361.[34] Ma ZQ, Liu YC, Low temperature synthesis of MgB2supercondutors, Inter. Mater. Rev.56 (2011) 267-286.[35] Ma ZQ,Liu YC, The varied kinetics mechanisms in the synthesis of MgB2 from elemental powders by low-temperature sintering, Mater. Chem. Phys. 126 (2011) 114-117.[36] Zhao Q, Liu YC, Zhao NQ, Penner S, Ma ZQ, A novel approach for efficient Ni nanoparticle doping of MgB2 by liquid-assisted sintering, IEEE Trans. Nanotechnol. 10 (2011) 331-337.[37] Cai Q, Ma ZQ, Zhao Q, Liu YC, Observation of Flux Jump in Bulk (MgB2)0.96Ni0.04 Doped with Milled Ni powders, J. Supercond. Nov. Magn. 24 (2011) 2013-2017.[38] Ma ZQ, Liu YC, Gao ZM, The synthesis and grain connectivity of lamellar MgB2 grains by Cu-activated sintering at low temperature, Scripta Mater.63 (2010) 399-402.[39] Ma ZQ, Jiang H, Liu YC, The accelerated low-temperature sintering of MgB2 bulks with high critical density by minor Sn-doping, Supercond. Sci. Technol. 23 (2010) 025005.[40] Ma ZQ,Liu YC, Hu WP, Gao ZM, Yu LM, Dong ZZ, The enhancement of Jc in the nanoSiC-doped MgB2 superconductors rapidly synthesized by activated sintering at low-temperature, Scripta Mater. 61 (2009) 836-839.[41] Ma ZQ,Liu YC, Huo J,Gao ZM, MgB2 superconductors with abnormally- improvedJc sintered after autoxidation of milled original powders, J. Appl. Phys.106 (2009) 113911.[42] Ma ZQ, Liu YC, Zhao Q, Dong ZZ, Yu LM, Mechanism analysis for enhanced electromagnetic properties in nano-SiC-doped MgB2 based on the discussion of the sintering process, Supercond. Sci. Technol. 22 (2009) 085015.[43] Ma ZQ, Liu YC, Huo J, Influence of ball-milled amorphous B powders on the sintering process and superconductive properties of MgB2, Supercond. Sci. Technol. 22 (2009) 125006.[44] Ma ZQ, Liu YC, Dong ZZ, Yu LM, Gao ZM, Zhao Q, The effect of Cu addition on the sintering process and superconductive properties of SiC-doped MgB2 bulks, Appl. Phys. A96 (2009) 975-978.[45] Ma ZQ, Liu YC, Shi QZ, Zhao Q, Gao ZM, The mechanism of accelerated phase formation of MgB2 by Cu-doping during low-temperature sintering, Mater. Res. Bull. 44 (2009) 531-537.[46] Ma ZQ, Liu YC, Shi QZ, Zhao Q, Gao ZM, Effect of Cu addition in reduction of MgO content for the synthesis of MgB2 through sintering, J. Alloys Compd. 471 (2009) 105-108.[47] Zhao Q, Liu YC, Han YJ, Ma ZQ, Shi QZ, Gao ZM, Effect of heating rates on microstructure and superconducting properties of pure MgB2, Physica C 469 (2009) 857-861.[48] Zhao Q, Liu YC, Shi QZ, Ma ZQ, Gao ZM. Characteristic and synthesis mechanism of MgB2 nanoparticles in solid-state reactive sintering, J Alloy Compd 470 (2009) 443-447.[49] Ma ZQ, Liu YC, Han YJ, Zhao Q, Gao ZM, Variation of the enhancement mechanism in the critical current density of Cu-doped MgB2 samples sintered at different temperatures, J. Appl. Phys.104 (2008) 063917.[50] Ma ZQ, Liu YC, Shi QZ, Zhao Q, Gao ZM, The accelerated formation of MgB2 bulks with high critical current density by low-temperature Cu-doping sintering, Supercond. Sci. Technol. 21 (2008) 065004.[51] Ma ZQ, Liu YC, Yu LM, Zhao Q, The accelerated formation of MgB2 phase with high critical current density by Cu and SiC multi-doping during the low-temperature sintering process, J. Appl. Phys. 104 (2008) 113917.[52] Ma ZQ, Liu YC, Shi QZ, Zhao Q, Gao ZM, The improved superconductive properties of MgB2 bulks with minor Cu addition through reducing the MgO impurity, Physica C 468 (2008) 2250-2253.[53] Shi QZ, Liu YC, Gao ZM, Zhao Q, Ma ZQ. In-situ formation process and mechanism of bulk MgB2 before Mg melting, J. Mater. Res. 23 (2008) 1840- 1848.[54] Shi QZ, Liu YC, Zhao Q, Ma ZQ. Phase formation process of bulk MgB2 analyzed by Differential Thermal Analysis during sintering, J. Alloys Compd. 458 (2008) 553-557.[55] Zhao Q, Liu YC, Shi QZ, Ma ZQ, Gao ZM. Characteristic and Synthesis Mechanism of MgB2 Nanoparticles in Solid-State Reactive Sintering, J. Alloys Compd. 470 (2008) 443-447[56] Liu YC, Shi QZ, Zhao Q, Ma ZQ, Kinetics analysis for the sintering of bulk MgB2 superconductor, J Mater Sci: Mater in Electro. 18 (2007) 855-861. Superconducting materials; W-based Alloys; Material thermodynamics and kinetics; sintering kinetics 暂无内容 暂无内容 教育经历 2006.9-2011.6 Tianjin University   博士 2002.9-2006.7 Tianjin University   学士 工作经历 2013.10 -2019.12 |Institute for Superconducting & Electronic Materials (ISEM) University of Wollongong|Visiting Fellow 2014.6 -2019.12 |Tianjin University|Associate Professor 2011.9 -2014.6 |Tianjin University|Lecturer