个人简历

舒世立、副教授/博导，从事金属增材制造及控形控性研究。作为第一/通讯作者在Composites Part B: Engineering (IF=11.322), Materials & Design (IF=9.417), Opto-Electronic Advances (IF=8.933)等国际期刊上发表SCI论文30余篇；其中，中科院1区Top期刊论文22篇，ESI高被引论文2篇；获吉林省技术发明一等奖1项；获美国授权发明专利3项，获国家授权发明专利20余项，其中5项已成果转化；承担国家级项目3项，省部市级项目6项。担任 SCI 期刊《Metals》编委，教育部学位中心评审专家及10 余种 SCI 期刊审稿人；获评吉林省人才政策2.0版E类人才，入选吉林大学励新优秀青年教师培养计划（重点培养阶段）。\r
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教育经历\r
2008.9 -- 2013.6 吉林大学 博士\r
2004.9 -- 2008.6 吉林大学 学士\r
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工作经历\r
2020.5 -- 至今 吉林大学 副教授/博导\r
2016.9 -- 2020.5 中国科学院长春光学精密机械与物理研究所 副研究员/硕导\r
2013.7 -- 2016.9 中国科学院长春光学精密机械与物理研究所 助理研究员\r
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荣誉与获奖\r
[1] 入选吉林大学励新优秀青年教师培养计划（重点培养阶段）\r
[2] 获评吉林省人才政策2.0版E类人才\r
[3] 高功率高亮度半导体激光芯片及系统关键技术，吉林省技术发明一等奖（3/12）\r
[4] 高功率激光离轴外腔反馈光谱合束方法，长春光机所优秀成果奖（4/8）\r
[5] 高功率极低发散角圆形光束半导体边发射激光器，中国光学重要成果奖（4/10）

研究领域

"""""[1] 金属增材制造\r
[2] 仿生智能制造"

近期论文

Investigation on the elevated-temperature tribological behaviors and mehanism of Al-Cu-Mg composites reinforced by in-situ size-tunable TiB2-TiC particles, Tribology International, 2023, 177: 177943. (1区Top, IF=5.620)\r
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Application of ceramic nanoparticles in microstructure manipulation and simultaneously strengthening toughness and wear resistance of tool and die steels, Ceramics International, 2023, 49:16661-16672. (1区Top，IF=5.532)\r
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Instantaneous efficient microstructure manipulation of eutectic Al–Si alloy by trace in-situ nanoparticles and their mechanism in superior tensile properties, Materials Characterization, 2023, 199: 112755. (1区Top，IF=4.537)\r
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Microstructure manipulation and strengthening mechanism of TiAl composites reinforced by Cr solid solution and in-situ nanometer-sized TiB2 particles, Materials Science and Engineering: A, 2022, 845: 143214. (1区Top, IF=6.044)\r
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Multilevel Microstructure Control of Cast Al–7.0Si–4.0Cu Alloy with High Strength–toughness Synergy via Micro-alloying Combined with Manipulation by in-situ Nano-ceramics, Journal of Materials Research and Technology, 2022, 21: 3248-3261. (1区Top, IF=6.267)\r
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Role of V in microstructure and strength enhancement of 4 vol.% nano-TiB2/TiAl composites, Materials Science and Engineering: A, 2022, 861: 144342. (1区Top, IF=6.044)\r
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Interface formation and bonding control in high-volume-fraction (TiC+TiB2)/Al composites and their roles in properties enhancement, Composites Part B: Engineering, 2021, 209: 108605. (1区Top, IF=11.322, ESI高被引论文)\r
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Insight into solidification microstructure control by trace TiCN-TiB2 particles for yielding fine-tuned nanoprecipitates in a hypoeutectic Al-Si-Mg alloy, Materials Science and Engineering: A, 2021, 827: 142093. (1区Top, IF=6.044)\r
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Microstructure evolution and mechanical property enhancement of high-Cr hot work die steel manipulated by trace amounts of nano-sized TiC. Materials Science and Engineering A, 2021, 824: 141788. (1区Top, IF=6.044)\r
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Microstructural configuration and compressive deformation behavior of a TiAl composite reinforced by Mn and in situ Ti2AlC particles. Materials Science and Engineering A, 2021, 823: 141772. (1区Top, IF=6.044)\r
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Microstructure manipulation and strengthening mechanisms of 40Cr steel via trace TiC nanoparticles. Materials Science and Engineering A, 2021, 8 22: 141639. (1区Top, IF=6.044)\r
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Simultaneously improved strength and toughness of in situ bi-phased TiB2-Ti(C,N)-Ni cermets by Mo addition, Journal of Alloys and Compounds, 2020, 820: 153068. (1区Top, IF=6.371, ESI高被引论文)\r
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Strengthening mechanism of TiC/Al composites using Al-Ti-C/CNTs with doping alloying elements (Mg, Zn and Cu), Journal of Materials Research and Technology, 2020, 9(3): 6475-6487. (1区Top, IF=6.267) \r
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Effect of Ta addition on the microstructures and mechanical properties of in situ bi-phase (TiB2-TiCxNy)/(Ni-Ta) cermets, Ceramics International, 2019, 45: 4408-4417. (1区Top, IF=5.532) \r
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Progress of optically pumped GaSb based semiconductor disk laser, Opto-Electronic Advances, 2018, 1: 170003. (1区Top, IF=8.933)\r
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Effects of Fe, Co and Ni elements on the ductility of TiAl alloy. Journal of Alloys and Compounds, 2014, 617:302–305. (1区Top, IF=6.371)\r
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Comparative study of the compression properties of TiAl matrix composites reinforced with nano–TiB2 and nano–Ti5Si3 particles. Materials Science and Engineering A, 2013, 560: 596–600. (1区Top, IF=6.044)\r
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Effect of B4C size on the fabrication and compression properties of in situ TiB2–Ti2AlC/TiAl composites. Journal of Alloys and Compounds, 2013, 551:88–91. (1区Top, IF=6.371)\r
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Phase transitions and compression properties of Ti2AlC/TiAl composites fabricated by combustion synthesis reaction. Materials Science and Engineering A, 2012, 539: 344-348. (1区Top, IF=6.044)\r
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Compression properties and work-hardening behavior of Ti2AlC/TiAl composites fabricated by combustion synthesis and hot press consolidation in the Ti–Al–Nb–C system. Materials & Design, 2011, 32: 5061-5065. (1区Top, IF=9.417)\r
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High volume fraction TiCx/Al composites with good comprehensive performance fabricated by combustion synthesis and hot press consolidation. Materials Science and Engineering A, 2011, 528: 1931-1936. (1区Top, IF=6.044)\r
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Effects of alloy elements (Mg, Zn, Sn) on the microstructures and compression properties of high-volume-fraction TiCx/Al composites. Scripta Materialia, 2010, 63: 1209-1211. (1区Top, IF=6.302)