Faculty

SHU Shili

Associate Professor

Email: shushili@jlu.edu.cn

Website: https://www.researchgate.net/profile/Shili_Shu

Educational Background

2008.09 – 2013.06, Jilin University, Doctor

2004.09 – 2008.06, Jilin University, Bachelor

Professional Experience

2020.05–Now, Associate Professor, Jilin University

2016.09–2020.05, Associate Professor, Changchun Institute of Optics, Fine

Mechanics and Physics, Chinese Academy of Sciences

2013.07–2016.09, Assistant Professor, Changchun Institute of Optics, Fine

Mechanics and Physics, Chinese Academy of Sciences

Research Interests

[1] Laser additive manufacturing

[2] Laser manufacturing technology and equipment

[3] Strengthening and toughening of aviation light alloy

Research Projects

[1] State Key Laboratory free exploration project, ascl-zytsxm-202015, Study of nano particle control mechanism of magnesium alloy with high strength and toughness for lightweight vehicle, 2020/04-2023/03, In research, Project leader;

[2] National Natural Science Foundation of China (NSFC), 51501176, Interface control and thermal stability study in pakage application of CNTs-TiC/Al gradient composite, 2016/01-2018/12, Completed, Project leader;

[3] Jilin Province Science and technology development plan project, 20140520127jh, Research on hundred Watts small volume semiconductor laser module cooled by micro/nano heat pipes, 2014/01-2016/12, Completed, Project leader;

[4] Jilin University Innovation Program, 20121087, Strengthening and toughening mechanism of ceramic particle reinforced TiAl matrix composites, 2012/06-2013/06, Completed, Project leader;

Selected Publications

1. Corresponding author, 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.

2. Corresponding author, 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.

3. Corresponding author, Application of nanoparticles in cast steel: An overview, China Foundry, 2020, 17: 111-126.

4. Corresponding author, Pulse control in self-mode-locked 2.8?m Er-doped fluoride fiber lasers, Optics and Laser Technology, 2020, 129: 106285.

5. Corresponding author, Effects of alloy elements on the compression properties of in-situ nano-Ti5Si3/TiAl composite, International Journal of Modern Physics B, 2019, 33: 1940051.

6. Corresponding author, High beam quality broad-area diode lasers by spectral beam combining with double filters, Chinese Optics Letters, 2019, 17(1): 011401.

7. Corresponding author, Effects of alloying elements on the phase constitution and microstructure of in situ SiC/Al composites, International Journal of Modern Physics B, 2019, 33: 1940048.

8. Corresponding author, 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.

9. First author, Progress of optically pumped GaSb based semiconductor disk laser, Opto-Electronic Advances, 2018, 1:170003.

10. First author, Heat dissipation in high-power semiconductor lasers with heat pipe cooling system, Journal of Mechanical Science and Technology, 2017, 31 (6): 2607~2612.

11. Corresponding author, Fabrication and Characterization of In Situ Synthesized SiC/Al Composites by Combustion Synthesis and Hot Press Consolidation Method, Scanning, 2017, 2017(9): 1~11.

12. First author, Effects of ternary elements on the ductility of TiAl, Canadian Metallurgical Quarterly, 2016, 55(2): 156~160.

13. Corresponding author, Tunneling-assisted coherent population transfer and creation of coherent superposition states in triple quantum dots, Laser Physics Letters, 2016, 13(12): 125203.

14. First author, Fabrication of TiCx-TiB2/Al Composites for Application as a Heat Sink, Materials, 2016, 9(8): 642.

15. Corresponding author, Control of coherence transfer via tunneling in quadruple and multiple quantum dots, Laser Physics Letters, 2016, 13(12): 125205.

16. First author, Effect of Ceramic Content on the Compression Properties of TiB2-Ti2AlC/TiAl Composites. Metals, 2015, 5: 2200-2209.

17. First author, Effect of Mn, Fe and Co on the compression properties of TiB2/TiAl composites. SpringerPlus, 2015, 4: 784.

18. First author, Effects of Fe, Co and Ni elements on the ductility of TiAl alloy. Journal of Alloys and Compounds, 2014, 617:302–305.

19. First author, Effects of Mn and strain rate on the compression behavior of TiAl alloy fabricated by combustion synthesis and hot press consolidation. Intermetallics, 2013, 43:24–28.

20. First author, 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.

21. First author, 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.

22. First author, Study of effect of Mn addition on the mechanical properties of Ti2AlC/TiAl composites through first principles study and experimental investigation. Intermetallic, 2012, 28:65-70.

23. First author, Phase transitions and compression properties of Ti2AlC/TiAl composites fabricated by combustion synthesis reaction. Materials Science and Engineering A, 2012, 539:344-348.

24. First author, 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 and Design, 2011, 32:5061-5065.

25. First author, 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.

26. First author, 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.

Courses

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Patents and Applications

1. Small volume and high power semiconductor laser with heat pipe cooling system, ZL201610064811.7, China

2. Coherent beam combining system and method, ZL201610132600.2, China

3. Structure and fabrication of a quantum cascade laser with high efficiency and lateral heat conduction, ZL201410821162.1, China

4. A spectral beam combining system of semiconductor laser, ZL201710779625.6, China

5. Spectral beam combined laser system and method,US10,333,265 B2, U.S.A.

Other Professional Activities

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Honors and Awards

2020 Jilin Province, First prize of technological invention (3/12);

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