姓　　名： 孙宏祥
职务职称： 副教授、博士生导师
研究方向： 声拓扑绝缘体、声超材料、声超表面
研究生招生专业： 硕士：物理学、电子科学与技术、博士：计算机科学与技术
电话： **
E-mail： jsdxshx@ujs.edu.cn
通信地址： 江苏省镇江市学府路301号江苏大学理学院(212013)



学习经历：
2018/12－2019/12，新加坡南洋理工大学，访问****
2014/12－2018/07，江苏大学，动力工程与热物理，博士后
2010/09－2013/09，南京大学，声学, 博士
2006/09－2009/06，江苏大学，光学工程, 硕士
2000/09－2004/07，南京师范大学, 物理学, 本科
工作经历：
2004/07－至今，江苏大学理学院，教师


中国声学学会教育分会委员，江苏省声学学会青工委委员, Laser Photonics Rev.，Adv. Optical Mater., Adv. Mater. tech., Appl. Phys. Lett, Appl. Phys. Express, J.Phys.D, J. Appl. Phys., Sci. Rep., Mater.Res.Express, Chin. Phys. B，Acta Phys. Sin.等国际期刊审稿人。


● 声学人工材料 （研究生）
● 大学物理、大学物理实验（本科生）


江苏大学教改课题 (2017JGYB060), 主持(结题)


主持在研项目
[1] 国家自然科学基金面上项目 (**)
[2] 声场声信息国家重点实验室开放课题 (SKLOA201813)
主持完成项目
[1] 国家自然科学基金青年项目 (**)
[2] 江苏省自然科学基金青年项目 (BK**)
[3] 声场声信息国家重点实验室开放课题 (SKLOA201109)
[4] 声场声信息国家重点实验室开放课题 (SKLOA201308)
[5] 声场声信息国家重点实验室开放课题 (SKLOA201607)
[6] 中国博士后基金面上项目 (2015M571672)
[7] 近代声学教育部重点实验室开放课题 (1105)
[8] 近代声学教育部重点实验室开放课题 (1304)
[9] 近代声学教育部重点实验室开放课题 (1510)
[10] 江苏省高校自然科学研究面上项目 (12KJB14003)

专著、译著
孙宏祥著, 黏弹性复合材料激光超声理论与技术，科学出版社，2017年1月.


★2020年度SCI收录论文：(#同等贡献，*通讯作者)
[57] T. C. Zhang#, J. H. Chen#, J. Qian#, Y. Ge, S. Q. Yuan, H. X. Sun*, and X. J. Liu*. Observation of ultrabroadband acoustic focusing based on V-Shaped meta-atoms. Advanced Materials Technologies, 2020, **.
[56] Y. J. Lu#,Y. Ge#,S. Q. Yuan,H. X. Sun*, andX. J. Liu*. Acoustic logic gates by a curved waveguide with ultrathin metasurfaces. Journal of Physics D: Applied Physics, 2020, 53: 015301.

★2019年度SCI收录论文
[55] Y. H. Yang#, H. X. Sun#, J. P. Xia, H. R. Xue, Z. Gao, Y. Ge, D. Jia, S. Q. Yuan, Y. D. Chong*, and B. L. Zhang*. Topological triply degenerate point with double Fermi arcs. Nature Physics, 2019, 15: 645-649. (1区Top期刊, IF: 20.11)
[54] Y. H. Yang#, J. P. Xia#, H. X. Sun*, Y. Ge, D. Jia, S. Q. Yuan, S. Y. Yang, Y. D. Chong*, and B. L. Zhang*. Observation of a topological nodal surface and its surface-state arcs in an artificial acoustic crystal. Nature Communications, 2019, 10: 5185. (1区Top期刊, IF: 11.88)
[53] Y. Y. Sun#, J. P. Xia#, H. X. Sun*, S. Q. Yuan, Y. Ge, and X. J. Liu*. Dual-band Fano resonance of low-frequency sound based on artificial Mie resonances. Advanced Science, 2019, 6: **. (1区Top期刊, IF: 15.80)
[52] Y. Wang#, J. P. Xia#, H. X. Sun*, S. Q. Yuan, Y. Ge, Q. R. Si, Y. Y. Guan, and X. J. Liu*. Multifunctional asymmetric sound manipulations by a passive phased array prism. Physical Review Applied, 2019, 12: 024033.
[51] Y. Ge, H. X. Sun*, S. Q. Yuan, and Y. Lai*. Switchable omnidirectional acoustic insulation through open window structures with ultrathin metasurfaces. Physical Review Materials, 2019, 3: 065203.
[50] J. Qian, H. X. Sun*, S. Q. Yuan, and X. J. Liu*. Enhanced directional acoustic emission based on anisotropic metamaterials. Applied Physics Letters, 2019, 114: 013506. (Top期刊)
[49] Y. Wang#, J. P. Xia#, H. X. Sun*, S. Q. Yuan, and X. J. Liu*. Binary-phase acoustic passive logic gates. Scientific Reports, 2019, 9: 8355.
[48] J. Qian#, Y. Wang#, S. Q. Yuan, H. X. Sun*, and X. J. Liu*. Reflected acoustic wavefront manipulation by an ultrathin metasurface based on three-dimensional generalized Snell’s law. Applied Physics Express, 2019, 12: 094001.
[47] D. Jia, H. X. Sun*, S. Q. Yuan, C. Zhang, and X. J. Liu*. Pseudospin- dependent acoustic topological insulator by airborne sonic crystals with a triangular lattice. Applied Physics Express, 2019, 12: 044003.
[46] W. T. Gao#, J. P. Xia#, H. X. Sun*, S. Q. Yuan, Y. Ge, and X. J. Liu*. Acoustic energy harvesting for low-frequency airborne sound based on compound Mie resonances. Applied Physics Express, 2019, 12: 044002.
[45] H. X. Sun*, A. R. Hou, J. Qian, Y. Ge*, S. Q. Yuan, Y. J. Guan, Q. R. Si, and X. J. Liu*. Broadband acoustic converging and asymmetric converging based on thermoacoustic phased arrays. Journal of Applied Physics, 2019, 125: 024504.
[44] D. Jia, Y. Ge, S. Q. Yuan, and H. X. Sun*. Dual-band acoustic topological insulator based on honeycomb lattice sonic crystal. Acta Physica Sinica, 2019, 68: 224301. (Invited paper)

★2018年度SCI收录论文：
[43] J. P. Xia#, D. Jia#, H. X. Sun*, S. Q. Yuan*, Y. Ge, Q. R. Si, and X. J. Liu*. Programmable coding acoustic topological insulator. Advanced Materials, 2018, 30: **. (1区Top期刊, IF: 25.81)
[42] J. P. Xia, X. T. Zhang, H. X. Sun*, S. Q. Yuan*, J. Qian, and Y. Ge. Broadband tunable acoustic asymmetric focusing lens from dual-layer metasurfaces. Physical Review Applied, 2018, 10: 014016.
[41] D. Jia, H. X. Sun*, J. P. Xia, S. Q. Yuan, X. J. Liu*, and C. Zhang. Acoustic topological insulator by honeycomb sonic crystals with direct and indirect band gaps. New Journal of Physics, 2018, 20: 093027
[40] Y. Ge, H. X. Sun*, S. Q. Yuan, and Y. Lai *. Broadband unidirectional and omnidirectional bidirectional acoustic insulation through an open window structure with a metasurface of ultrathin hooklike meta-atoms. Applied Physics Letters, 2018, 112: 243502. (Top期刊)
[39] H. X. Sun#, J. H. Chen #, Y. Ge*, S. Q. Yuan, and X. J. Liu*. Broadband and flexible acoustic focusing by metafiber bundles. Journal of Physics D: Applied Physics, 2018, 51: 245102.
[38] A. R. Hou#, W. T. Gao#, J. Qian#, H. X. Sun*, Y. Ge*, S. Q. Yuan, Q. R. Si, and X. J. Liu. Thermoacoustic-reflected focusing lens based on acoustic Bessel-like beam with phase manipulation. Chinese Physics B, 2018, 27: 124301.

★2017年度SCI收录论文：
[37] C. Y. Zuo #, J. P. Xia#, H. X. Sun*, Y. Ge, S. Q. Yuan, and X. J. Liu*. Broadband acoustic logic gates in a circular waveguide with multiple ports. Applied Physics Letters, 2017, 111: 243501.(Top期刊)
[36] J. P. Xia, H. X. Sun*, and S. Q. Yuan*. Modulating sound with acoustic metafiber bundles. Scientific Reports, 2017, 7: 8151.
[35] C. Liu #, J. P. Xia#, H. X. Sun*, and S. Q. Yuan*. Thermoacoustic focusing lens by symmetric Airy beams with phase manipulations. Journal of Physics D: Applied Physics, 2017, 50: 505101.
[34] H. X. Sun*, Y. L. Huang, J. P. Xia, and S. Q. Yuan*. Asymmetric acoustic convergence in a metal plate with binary wave-path slits. Journal of Physics D: Applied Physics, 2017, 50: 35LT02.
[33] Y. J. Guan, H. X. Sun*, J. P. Xia, and S. Q. Yuan*. Broadband asymmetric acoustic transmission in a single medium by an array of heat sources. Journal of Physics D: Applied Physics, 2017, 50: 165102.
[32] J. Qian#, J. P. Xia#, H. X. Sun*, S. Q. Yuan*, Y. Ge, and X. Z. Yu. Broadband acoustic focusing by cavity structures with phase manipulations. Journal of Applied Physics, 2017, 122: 244501 (JAP封面，Featured article).
[31] Y. Ge, H. X. Sun*, S. Q. Yuan*, and J. P. Xia. Asymmetric acoustic transmission in an open channel based on multiple scattering mechanism. Applied Physics A, 2017, 123: 328.
[30] J. Qian#, B. Y. Liu #, H. X. Sun*, S. Q. Yuan*, and X. Z. Yu. Broadband acoustic focusing by symmetric Airy beams with phased arrays comprised of different numbers of cavity structures. Chinese Physics B, 2017, 26: 114304.
[29] D. Jia, H. X. Sun*, S. Q. Yuan*, and Y. Ge. Ultra-broadband asymmetric acoustic transmission with single transmitted beam. Chinese Physics B, 2017, 26: 024302.
[28] H. X. Sun*, X. Fang, Y. Ge, X. D. Ren, and S. Q. Yuan*. Acoustic focusing lens with near-zero refractive index based on coiling-up space structure. Acta Physica Sinica, 2017, 66: 244301 (Editor's suggestion).
[27] C. Liu, H. X. Sun*, S. Q. Yuan*, J. P. Xia, and J. Qian. Acoustic focusing by thermoacoustic phased array. Acta Physica Sinica, 2017, 66: 154302.

★2016年度SCI收录论文：
[26] Y. L. Huang, H. X. Sun*, J. P. Xia, S. Q. Yuan*, and X. L. Ding. Multi-band asymmetric acoustic transmission in a bended waveguide with multiple mechanisms. Applied Physics Letters, 2016, 109: 013501. (Top期刊)
[25] Y. Ge, H. X. Sun*, C. Liu, J. Qian, S. Q. Yuan*, J. P. Xia, Y. J. Guan, and S. Y. Zhang. Acoustic focusing by an array of heat sources in air. Applied Physics Express, 2016, 9: 066701.
[24] J. P. Xia, H. X. Sun*, Q. Cheng, Z. Xu, H. Chen, S. Q. Yuan*, S. Y. Zhang, Y. Ge, and Y. J. Guan. Theoretical and experimental verification of acoustic focusing in metal cylinder structure. Applied Physics Express, 2016, 9: 057301.
[23] H. X. Sun*, S. Y. Zhang*, S. Q. Yuan*, and J. P. Xia. Experimental verification of manipulating propagation directions of transmitted waves in asymmetric acoustic transmission. Applied Physics A, 2016, 122: 328.
[22] Y. Ge, H. X. Sun*, S. S. Liu, S. Q. Yuan*, J. P. Xia, Y. J. Guan, and S. Y. Zhang. Extraordinary acoustic transmission through annuluses in air and its applications in acoustic beam splitter and concentrator. Review of Scientific Instruments, 2016, 87: 1734-1736.
[21] H. X. Sun*, S. Y. Zhang*, and S. Q. Yuan. Control of pass-bands in asymmetric acoustic transmission. Chinese Physics B, 2016, 25: 124313.(Invited paper)
[20] Y. J. Guan, H. X. Sun*, S. S. Liu, S. Q. Yuan*, J. P. Xia, and Y. Ge. Acoustic focusing through two layer annuluses in air. Chinese Physics B, 2016, 25: 104302.
[19] Y. J. Guan, H. X. Sun*, S. Q. Yuan, S. Y. Zhang, and Y. Ge. Laser-generated Rayleigh waves propagating in transparent viscoelastic adhesive coating/metal substrate systems. International Journal of Thermophysics, 2016, 37: 101.
[18] H. X. Sun*, S. Y. Zhang, S. Q. Yuan, Y. J. Guan, and Y. Ge. Laser-generated Lamb waves propagation in multilayered plates composed of viscoelastic fiber-reinforced composite materials. International Journal of Thermophysics, 2016, 37: 68.
[17] C. Liu, H. X. Sun*, S. Q. Yuan*, and J. P. Xia. Broadband acoustic focusing effect based on temperature gradient distribution. Acta Physica Sinica, 2016, 65: 044303.
[16] Y. J. Guan, H. X. Sun*, S. Q. Yuan *, Y. Ge, and J. P. Xia. Propagation characteristics of laser-generated surface acoustic waves in composite plate with gradient changes of near-surface viscous moduli. Acta Physica Sinica, 2016, 65: 224201.

★2015年度SCI收录论文：
[15] J. P. Xia and H. X. Sun*. Acoustic focusing by metal circular ring structure. Applied Physics Letters, 2015, 106: 063505. (Top期刊)
[14] H. X. Sun*, S. Q. Yuan*, and S. Y. Zhang, Asymmetric acoustic transmission in multiple frequency bands. Applied Physics Letters, 2015, 107: 213505. (Top期刊)
[13] J. P. Xia, H. X. Sun*, S. Q. Yuan*, and S. Y. Zhang. Extraordinary acoustic transmission based on source pattern enhancement and reconstruction by metal cylinder structure. Applied Physics Express, 2015, 8: 104301.
[12] H. X. Sun* and S. Y. Zhang*. Laser-generated leaky Rayleigh waves at fluid-coating-substrate interfaces. International Journal of Thermophysics, 2015, 36: 1244-1251.
[11] H. X. Sun*, S. Y. Zhang*, and J. P. Xia. Propagation characteristics of laser-generated Rayleigh waves in coating-substrate structures with anisotropic and viscoelastic properties. International Journal of Thermophysics, 2015, 36: 1156–1163.

★2009至2014年度SCI收录论文：
[10] H. X. Sun and S. Y. Zhang. Enhancement of asymmetric acoustic transmission. Applied Physics Letters, 2013, 102: 113511. (Top期刊)
[9] H. X. Sun, S. Y. Zhang, and X. J. Shui. A tunable acoustic diode made by a metal plate with periodical structure. Applied Physics Letters, 2012, 100(11): 103507. (Top期刊)
[8] H. X. Sun and S. Y. Zhang. Thermoviscoelastic excitation and propagation of Rayleigh waves in viscoelastic plates by a pulsed laser. International Journal of Thermophysics, 2013, 34: 1762–1768.
[7] H. X. Sun and S. Y. Zhang. Influences of elastic and viscous moduli on laser- generated Lamb waves in viscoelastic plates. International Journal of Thermophysics, 2013, 34: 1769–1776.
[6] H. X. Sun, S. Y. Zhang, and B. Q. Xu. Influence of viscoelastic property on laser- generated surface acoustic waves in coating–substrate systems. Journal of Applied Physics, 2011, 109: 073107.
[5] H. X. Sun, B. Q. Xu, H. Zhang, Q. Gao, and S. Y. Zhang. Influence of adhesive layer properties on laser-generated ultrasonic waves in thin bonded plates. Chinese Physics B, 2011, 20: 014302.
[4] H. X. Sun and S. Y. Zhang. Thermoviscoelastic finite element modeling of laser-generated ultrasound in viscoelastic plates. Journal of Applied Physics, 2010, 108: 123101.
[3] H. X. Sun, B. Q. Xu, G. D. Xu, and C. G. Xu. Study on laser-generated Lamb waves propagation in viscoelastic and anisotropic plate. Chinese Optics Letters, 2010, 8: 776-779.
[2] H. X. Sun, B. Q. Xu, and R. Z. Qian. Numerical simulation of laser-generated Lamb waves in viscoelastic materials by finite element method. Journal of Applied Physics, 2009, 106: 073108.
[1] H. X. Sun, B. Q. Xu, J. J. Wang, G. D. Xu, C. G. Xu, and F. Wang. Numerical simulation of laser-generated Rayleigh wave by finite element method on viscoelastic materials. Acta Physica Sinica, 2009, 58: 6344-6350.
★授权发明专利：
[2] 孙宏祥，袁寿其，夏建平. 一种基于金属板状复合结构的多频带声波非对称透射器件. 专利号：ZL. 7. X.
[1] 孙宏祥，袁寿其，夏建平. 一种方向可控的声增强透射器件. 专利号：ZL. 3.1.


★个人获奖：
2019年 江苏省科技进步一等奖
2019年 江苏省高校第十六届大学生物理创新竞赛优秀指导老师
2018年 江苏大学优秀教师
2018年 江苏省高校第十五届大学生物理创新竞赛优秀指导老师
2017年 全国大学生创新创业计划十周年“最佳导师奖”
2017年 江苏省高校“青蓝工程”优秀青年骨干教师
2017年 江苏省“六大人才高峰”高层次人才
2017年 镇江市十佳教师
2017年 江苏省高校第十四届大学生物理创新竞赛优秀指导老师
2017年 江苏大学新长征突击手
2017年 江苏大学教学成果一等奖 第3
2016年 江苏大学十佳青年教职工
2016年 江苏省高校第十三届大学生物理创新竞赛优秀指导老师
2016年 全国微课程(体系化)大赛二等奖
2016年 江苏省自然科学学术活动月优秀学术论文二等奖
2015年 江苏大学最受学生欢迎的十佳教师
2015年 江苏大学教学成果二等奖 第2
2015年 江苏省高校第十二届大学生物理创新竞赛优秀指导老师
2014年 江苏大学青年学术带头人培育人选
2014年 江苏大学教师教学竞赛一等奖
2013年 镇江市优秀科技论文(专著)二等奖
2012年 教育部博士研究生学术新人奖
2011年 镇江市优秀科技论文(专著)二等奖

★指导学生获奖：
2019年 指导学生获第十六届“挑战杯”全国大学生课外学术科技作品竞赛二等奖、省特等奖
2019年 指导学生获江苏省高校第十六届大学生物理创新竞赛一等奖3项
2019年 指导学生获江苏省普通高校本科优秀毕业论文二等奖
2018年 指导学生入选第十一届全国大创年会学术论文交流
2018年 指导学生获江苏省高校第十五届大学生物理创新竞赛一等奖
2018年 指导学生获江苏省普通高校本科优秀毕业论文一等奖
2018年 指导学生获江苏省大创年会优秀论文
2018年 指导学生获江苏省研究生学术创新论坛优秀论文二等奖
2017年 指导学生获第十五届“挑战杯”全国大学生课外学术科技作品竞赛二等奖、省一等奖
2017年 指导学生获江苏省高校第十四届大学生物理创新竞赛一、二等奖各1项
2017年 指导学生获江苏省普通高校本科优秀毕业论文一等奖
2017年 指导学生获西安-上海第五届声学学术交流会议优秀论文优秀报告
2016年 指导学生入选第九届全国大创年会学术论文交流
2016年 指导学生获江苏省高校第十三届大学生物理创新竞赛一等奖两项
2016年 指导学生获江苏省大创年会优秀论文
2015年 指导学生获第八届全国大创年会优秀学术论文
2015年 指导学生获江苏省高校第十二届大学生物理创新竞赛一等奖