个人信息
个人简介
高雷,研究员、博导,教授二级岗。19712月出生,江苏新沂人。现为教育部物理学类专业教学指导委员会委员、江苏省物理学会常务理事、苏州市物理学会理事长、苏州城市学院党委常委、副院长。曾获江苏省普通高校“青蓝工程”中青年学术带头人培养人选、江苏省“333高层次人才培养工程”第三层次培养人选、江苏省青蓝工程创新团队负责人和苏州大学东吴学者等。2020年获苏州大学优秀共产党员和苏州大学“我最喜爱的老师”。
研究领域

1、非局域和磁光等离子体材料的研究

2、石墨烯和等离子体材料的光学非线性研究

3、纳米流体的热导率和热迁移性质的研究

基本信息
头像




高雷

职称:教授

院部/部门:物理科学与技术学院

学历:理学博士

学位:博士研究生

毕业学校:苏州大学

毕业专业:凝聚态物理

联系方式

通讯地址:

邮政编码:

电子邮箱:leigao@suda.edu.cn

联系电话:051267870386

传真号码:

办公地点:

科学研究

5年来,主持国家级自然科学基金3项,省部级自然科学基金2项,校级科研项目2项。在特异材料的光学与电磁性质、纳米流体传热特性研究方面取得一批重要的的基础研究成果。先后获第二批江苏省普通高校“青蓝工程”中青年学术带头人培养人选、江苏省“333高层次人才培养工程”第三层次培养人选、苏州大学东吴学者计划等。培养期间已在Phys. Rev. Lett. B(E)等国际SCI源核心期刊发表和接受论文30余篇(其中1区论文3篇,2区论文20)

(1)具有负折射率的复合材料的光学与电磁性质研究,国家自然科学基金(2003-2005),经费19

(2)左手复合材料的次波成像和非线性物理性质,国家自然科学基金(2007-2008,经费20

(3)科技部973计划“新型人工电磁介质”子课题(2007-2009),经费30

(4)特异电磁颗粒的异常散射和非线性物性研究,国家自然科学基金(2011-2013),经费36

(5)元激发近场耦合和人工微结构中光学效应的调控,国家重大研究计划-量子调控973子课题(2012-2016),经费60

(6)特异电磁材料体系的非局域和非线性效应研究,国家自然科学基金面上项目(2014-2017),经费80

(7)江苏省自然科学基金(2016-2019),经费10

(8)江苏省青蓝工程创新团队,(2016-2019),经费30

(9)石墨烯等离激元体系光学双稳、调制不稳定性和二次谐波效应的研究,国家自然科学基金面上项目(2018-2021),经费61万

(10)*******,FW10802320 GF(2020-2022),经费80

(11)深亚波长下非线性等离激元体系的时空演化动力学,国家自然科学基金重大培育项目(2021-2023),经费80万


科研团队

目前本课题成员

博士生:

王成琳(硕博连读,2017级)

葛文宣(硕博连读,2019级)

Ogundare Rasheed Toyin(博士留学生,2019级)

硕士生:

李儒道(2019级)

叶煌炜(2019级)

张成雅(2020级)

时建中(2020级)

于乃夫(2020级)

杨明亮(2021级)



近期课题组已毕业研究生就业情况:

已毕业博士:

倪亚贤(2012届,现就职于苏州大学,副教授)

高东梁(2013届,现就职于苏州大学,副教授)

黄艳艳(2013届,现就职于南通大学,副教授)

傅怀梁(2013届,现就职于南通大学,教务处教学实践科科长)

王婷婷(2014届,现就职于American Institutes for Research,数据分析师)
 坚(
2014届,就职苏州科技大学,副教授)

 2015届,现就职于江南大学,副教授)

陈鸿莉(2017届,现就职于南通大学,副教授)

於文静(2018届,就职江苏理工学院,讲师)

马普娟(2019届,就职山东师范大学,讲师

孔凡军(2020届,就职常熟理工学院,讲师

已毕业硕士:

顾利萍(2004届,现就职于常熟理工学院电信学院,副教授)

唐超军(2005届,现就职于浙江工业大学理学院,副教授)

 波(2005届,现就职于江苏理工学院数理学院)

 煜(2006届,现就职于苏州科技大学数学科学学院党政办)

王漱明(2006届,现就职于南京大学物理学院,副教授)

周晓锋(2006届,现就职于河海大学理学院,副教授)

史丽弘(2007届,现就职于江南大学理学院)

 灵(2008届,现就职于杭州钤韬知识产权代理事务所)

董文婷(2009届,现就职于南京博兰得电子科技有限公司)

金宇闻(2010届,现就职于安波福电气系统有限公司)

 彬(2010届,现就职于嘉善法兰克尼亚电磁兼容有限公司)

刘仁明(2011届,现就职于淮阴师范学院招就处)

孙婷婷(2011届,现就职于上海来学网教育科技有限公司)

陈久恺(2016届,现就职苏州驿力机车科技股份有限公司)

 2017届,现就职于苏州大学物理学院,科研秘书)

 2018届,现就职于苏州星海中学,物理教师)

 2018届,就职于南京市河西中学,物理教师)

 然(2019届,现就职于苏州大学出版社

侯校冉(2019届,现就职于沙溪高级中学,物理教师

刘彬彬(2019届,现就职于太仓高级中学,物理教师

 琴(2018届,现就职于苏州工业园区星港学校,物理教师

陈志鹏(2018届,现就职于常熟理工学院,辅导员



论文

已在Phys. Rev. Lett. Nature Commun. Light Sci. & Appl.等国际SCI源核心期刊发表论文200篇左右,发表教学研究论文5篇,出版编著1部。

代表性著作:

李振亚、高雷、孙华著, 《异质复合介质的电磁性质》,北京大学出版社(2012).


出版论文:

2021

180. Q. Zhang, D. L. Gao*, and L. Gao, Tunable spin Hall shift of light from graphene-wrapped spheres, Optics Express, 29(7), 9816-9825(2021).

179. O.R. Toyin, W. X. Ge, and L. Gao*, Photonic Thermal Rectification with Composite Metamaterials, Chinese Physics Letters, 38(1), 016801 (2021).


2020

178. S. Zhu, Y. Y. Cao, Y. Y. Fu, X. C. Li, L. Gao, H. Y. Chen, and Y. D. Xu*, Switchable bifunctional metasurfaces: nearly perfect retroreflection and absorption at the terahertz regime, Optics Letters, 45(14), 3989-3992 (2020).

177. S. Zhu, Y. Y. Cao, Y. Y. Fu, L. Gao, X. C. Li, H. Y.  Chen, and Y. D. Xu*, 3D broadband waveguide cloak and light squeezing in terahertz regime, Optics Letter, 45(3), 652-655(2020).

176.  S. B. Zhang, Y. D. Xu*, H. Y. Chen, Y. Y. Cao, L. Gao, H. Huang, H. Y. Zhou, and X. Ou, Photonic hyperinterfaces for light manipulations, Optica, 7(6), 687-693 (2020).

175. Y. Q. Wang, H. Hu, Q. Zhang, D. L. Gao*, and L. Gao, Topologically-tuned spin Hall shift around Fano resonance, Optics Express, 28(15), 21641-21649 (2020).

174. P. J. Ma, L. Gao, P. Ginzburg, R. E. Noskov, Nonlinear Nanophotonic Circuitry: Tristable and Astable Multivibrators and Chaos Generator, Laser & Photonics Reviews, 14(3), 1900304 (2020).

173. Y. L.  Liu, S. Zhu, Q. J. Zhou, Y. Y. Cao, Y. Y. Fu*, L. Gao, H. Y. Chen, and Y. D.  Xu, Enhanced third-harmonic generation induced by nonlinear field resonances in plasmonic-graphene metasurfaces, Optics Express, 28(9), 13234-13242 (2020).

172. X. C. Jiang, Y. W. Zhou, D. L. Gao, Y. Huang*, and L. Gao*, Realizing optical bistability and tristability in plasmonic coated nanoparticles with radial-anisotropy and Kerr-nonlinearity, Optics Express, 28(12), 17384-17394 (2020).

171. H. L.  Chen*, L. Gao, C. G. Zhong, G. Q.  Yuan, Y. Y. Huang, Z. W.  Yu, M. Cao, and M. Wang, Optical pulling force on nonlinear nanoparticles with gain,AIP Advances, 10(1), 015131 (2020).


2019

170. B. B. Liu, P. J. Ma, W. J. Yu, Y. D. Xu*, and L. Gao, Tunable Bistability in the Goos–Hänchen Effect with Nonlinear Graphene, Chinese Physics Letters, 36(6), 064202 (2019).

169. F. J. Kong, J. Wang, Z. S. Han, B. Qian*, S. Tao, H. M. Luo*, and L. Gao, Lithium storage mechanisms of CdSe nanoparticles with carbon modification for advanced lithium ion batteries, CHEMICAL COMMUNICATIONS, 55(20), 2996-2999 (2019).

168. X. R. Hou, L. D. Gao, and L. Gao*,  Graphene-tuned optical manipulation on microparticle by Bessel beam, AIP Advances, 9(3), 035154 (2019).

167. Y. Y. Fu, C. Shen, Y. Y. Cao, L. Gao, H. Y. Chen, C. T. Chan, S. A. Cummer*,  and Y. D. Xu, Reversal of transmission and reflection based on acoustic metagratings with integer parity design, Nature Communications, 10(1), 2326 (2019).

166. Z. P. Chen, W. J. Yu, and L. Gao, Coherent perfect absorption in nonlocal particle composite medium, Acta Physica Sinica, 68(5), 051101 (2019). 

165. Y. Y. Cao, Y. Y. Fu, Q. J. Zhou, L. Gao, H. Y. Chen, and Y. D. Xu*,  Giant Goos-Hanchen shift induced by bounded states in optical PT-symmetric bilayer structures, Optics Express 27(6), 7857-7867 (2019).

164. Y. Y. Cao, Y. Y. Fu, Q. J. Zhou, X. Ou, L. Gao*, H. Y. Chen*, and Y. D. Xu,  Mechanism Behind Angularly Asymmetric Diffraction in Phase-Gradient Metasurfaces, Physical Review Applied 12(2), 024006 (2019).

163. R. Shi, D. L. Gao*, H. Hu, Y. Q. Wang, and L.Gao*, Enhanced broadband spin Hall effects by core-shell nanoparticles, Optics Express27 (4), 4808-4817 (2019).


2018
162. H. Zhou,D. L. Gao, and L. Gao, Tunability of Multipolar Plasmon Resonances andFano Resonances in Bimetallic Nanoshells, Plasmonics13(2), 623-630 (2018).

161. W. J.Yu, H. Sun, and L. Gao, Enhanced normal-incidence Goos-Hanchen effectsinduced by magnetic surface plasmons in magneto-optical metamaterials,Opt Express26(4), 3956-3973 (2018).

160. W. J.Yu, P. J. Ma, H. Sun, L. Gao, and R. E. Noskov, Optical tristability andultrafast Fano switching in nonlinear magnetoplasmonic nanoparticles,Phys Rev B97(7), 075436 (2018).

159. H.Markovich, D. Filonov, I. Shishkin, and P. Ginzburg, Bifocal Fresnel LensBased on the Polarization-Sensitive Metasurface, Ieee T Antenn Propag66(5), 2650-2654 (2018).

158. P. Ma,L. Gao, P. Ginzburg, and R. E. Noskov, Ultrafast cryptography withindefinitely switchable optical nanoantennas, Light Sci App l 7(77 (2018).

157. D. Gao,R. Shi, A. E. Miroshnichenko, and L. Gao, Enhanced Spin Hall E?ect ofLight in Spheres with Dual Symmetry, Laser & Photonics Review12(11), 1800130 (2018).

156. D.Filonov, A. Shmidt, A. Boag, and P. Ginzburg, Artificial localized magnonresonances in subwavelength meta-particles, Appl Phys Lett113(12), 123505 (2018).

2017
155. K.Zhang, Y. Huang, Andrey E. Miroshnichenko, and L. Gao, Tunable OpticalBistability and Tristability in Nonlinear GrapheneWrapped Nanospheres,JOURNAL OF PHYSICAL CHEMISTRY C121((2017).

154. K.Zhang, and L. Gao, Optical bistability in graphene-wrapped dielectricnanowires, Opt Express25(12),13747-13759 (2017).

153. W. Yu, H. Sun,and L. Gao, Magnetic control of Goos-Hanchen shifts in ayttrium-iron-garnet film, Sci Rep7(45866(2017).

152. P. Ma, and L. Gao, Large and tunable lateral shifts in one-dimensional PT-symmetriclayered structures, Opt Express 25(9),9676-9688 (2017).

151. V. Kozlov,D. Filonov, Y. Yankelevich, and R. Ginzburg, Micro-Doppler frequency combgeneration by rotating wire scatterers, J Quant Spectrosc Ra 190(7-12 (2017).

150. Y. Huang,Y. M. Wu, and L. Gao, Bistable near field and bistable transmittance in2D composite slab consisting of nonlocal core-Kerr shell inclusions, Opt Express25(2), 1062-1072 (2017).

149. Y. Huang,Y. M. Wu, and L. Gao, Nonlocality-Broaden Optical Bistability in aNonlinear Plasmonic Core?Shell Cylinder, JOURNAL OF PHYSICAL CHEMISTRY C121((2017).

148. D. L. Gao,R. Shi, Y. Huang, and L. Gao, Fano-enhanced pulling and pushing opticalforce on active plasmonic nanoparticles, Physical Review A96(4) (2017).

147. T. J. Cui,S. Liu, and L. Zhang, Information metamaterials and metasurfaces, JMater Chem C5(15), 3644-3668(2017).

146. J. F.Cheng, L. Zhou, Z. Wen, Q. Yan, Q. Han, and L. Gao, The enhancedspin-polarized transport behaviors through cobalt benzene-porphyrin-benzenemolecular junctions: the effect of functional groups, J Phys CondensMatter 29(17), 175201 (2017).

145. X. Bian,D. L. Gao, and L. Gao, Tailoring optical pulling force on gain coatednanoparticles with nonlocal effective medium theory, Opt Express25(20), 24566-24578 (2017).

2016
144. W. J. Yu,H. Sun, and L. Gao, Optical bistability in core-shell magnetoplasmonicnanoparticles with magnetocontrollability, Opt Express24(19), 22272-22281 (2016).

143. P. J. Ma,D. L. Gao, Y. X. Ni, and L. Gao, Enhancement of Optical Nonlinearity byCore-Shell Bimetallic Nanostructures, Plasmonics11(1), 183-187 (2016).

142. A. V.Krasavin, P. Ginzburg, G. A. Wurtz, and A. V. Zayats, Nonlocality-drivensupercontinuum white light generation in plasmonic nanostructures, NatCommun7(11497 (2016).

141. Y. Huang,A. E. Miroshnichenko, and L. Gao, Low-threshold optical bistability ofgraphene-wrapped dielectric composite, Sci Rep6(23354 (2016).

140. Y. Huang,and L. Gao, Tunable Fano resonances and enhanced optical bistability incomposites of coated cylinders due to nonlocality, Phys Rev B93(23), 235439 (2016).

139. D. S.Filonov, A. S. Shalin, I. Iorsh, P. A. Belov, and P. Ginzburg, Controllingelectromagnetic scattering with wire metamaterial resonators, J Opt SocAm A Opt Image Sci Vis33(10),1910-1916 (2016).

138. D.Filonov, Y. Kramer, V. Kozlov, B. A. Malomed, and P. Ginzburg, Resonantmeta-atoms with nonlinearities on demand, Appl Phys Lett109(11), 111904 (2016).

137. T. J. Cui,S. Liu, and L. L. Li, Information entropy of coding metasurface,Light Sci Appl5(11), e16172 (2016).

136. J. F.Cheng, Q. Yan, L. Zhou, Q. Han, and L. Gao, The electron and spinpolarized transport in wide-voltage-ranges through colbaltporphyrin-basedmolecular junctions, J Chem Phys144(8),084707 (2016).

135. H. L.Chen, D. L. Gao, and L. Gao, Effective nonlinear optical properties andoptical bistability in composite media containing spherical particles withdifferent sizes, Opt Express24(5),5334-5345 (2016).

134.H. Chen,Y. Zhang, B. Zhang, and L. Gao, Optical bistability in anonlinear-shell-coated metallic nanoparticle, Sci Rep6(21741 (2016).


2015
133. D.L.Gao, L. Gao, A. Novitsky, H. Chen, and B. Luk'yanchuk,Topological effectsin anisotropy-induced nano-fano resonance of a cylinder, Opt. Lett.40,4162-4165 (2015).

132. D.L.Gao, A. Novitsky, T. Zhang, F. C. Cheong, L. Gao, C. T. Lim, B.Luk'yanchuk, andC.-W. Qiu, Unveiling the correlation between non-diffracting tractor beamand its singularity in Poynting vector,Laser Photon. Rev. 9, 75-82 (2015).

131. P.Ma, D. L. Gao*, Y. Ni, and L. Gao*, Enhancement of Optical Nonlinearityby Core-Shell Bimetallic Nanostructures, Plasmonics (2015) DOI10.1007/s11468-015-0036-x.

2014及之前
130.Y.Huang and L. Gao, “Superscattering of light from core-shell nonlocal plasmonicnanoparticles”, J. Phys. Chem. C (accepted)

129. J.F.Cheng, L.P. zhou, M. Liu, Q, Yan, Q. Han, and L. Gao, “Tip-contact relatedlow-bias negative differential resistance and rectifying effects inbenzene-porphyrin-benzene molecular juctions”, J. Chem. Phys. 141, 174304(2014).

128. Y.X. Ni, J.K.Chen, and L. Gao, “Anomalous optical forces on the anisotropic Rayleigh particles”,Opt. Express 2227355 (2014)

127D.L. Gao, A. Novitsky, T.H. Zhang, F.C.Cheong, L. Gao, C.T. Lim, B. Lukyanchuk, and C.W. Qiu, “Unveiling thecorrelation between non-diffracting tractor beam and its singularity inPoynting vector”, Laser Photon. Review (accepted)

126. Y. Huang, Z. W.Yu, and L. Gao, “Tunable spin-dependent splitting of light beam in a chiralmetamaterial slab”, J. Opt. 16, 075103 (2014).

125. T.T. Wang, J.Luo, L. Gao, P. Xu, and Y. Lai, “Equivalent perfect magnetic conductor based onepsilon-near-zero media”, Appl. Phys. Lett. 104, 211904 (2014).

124. Y. Huang, X.Bian, Y.X. Ni, and L. Gao, “Nonlocal surface Plasmon amplification bystimulated emission of radiation”, Phys. Rev. A 89, 053824 (2014).

123. J. Sun, Y. Huang,and L. Gao, “Nonlocal composite media in calculations of the Casimir force”,Phys. Rev. A 89, 012805 (2014).

122. H.L. Fu, Y.Huang, and L. Gao, “Photophoresis of spherical particles with interfacialthermal resistantce in micor-nano fluids”, Phys. Lett. A 377, 2815 (2013).

121. H.L. Chen and L.Gao, “Tunablity of the unconventional Fano resonances in coated nanowires withradial anisotropy”, Opt. Express 21, 23619 (2013).

120. Y. Huang and L.Gao, “Equivanlent permittivity and permeability and multiple Fano resonancesfor nonlocal metallic nanowires”, J. Phys. Chem. C 117, 19203 (2013).

119. J. Sun, X.K. Hua,A.V. Goncharenko, and L. Gao, “Casimir force between composite materialscontaining nonspherical particles”, Phys. Rev. A 87, 042509 (2013).

118. Y.X. Ni, L. Gao,A.E. Miroshnichenko, and C.W. Qiu, “controlling light scattering andpolarization by spherical particles with radial anisotropy”, Opt. Express 21,8091 (2013).

117. D.L. Gao, C.W.Qiu, L. Gao, T.J. Cui,and S. Zhang, “Macroscopic broadband optical escalatorwith force-loaded transformation optics”, Opt. Express 21m 796 (2013).

116. H.L. Fu and L.Gao, “Effect of interfacial nanolayer on thermophoresis in nanofluids”, Int. J.Thermal Sci. 61, 61 (2012).

115. H.L. Chen and L.Gao, “Anomalous electromagneticscattering from radially anisotropic nanowires”, Phys. Rev. A 86,033825(2012).

114. J. Sun, X.K. Hua,and L. Gao, “Repulsive and attractive Casimir forces between magnetodielectricslabs”, Solid State Commun. 152, 1666 (2012).

113. Y.X. Ni, L. Gao,A.E. Miroshnichenko, and C.W. Qiu, “Non-Rayleigh scattering behavior foranisotropic Rayleigh particles”, Opt. Express 37, 3390 (2012).

112. Y.Y. Huang, B.Zhao, and L. Gao, “GH shift of the reflectd wave through an anisotropicmetamaterials containing metal/dielectric nanocomposites”, J. Opt. Soc. Am. A29, 1436 (2012).

111. J. Luo, P. Xu. L.Gao, Y. Lai, and H.Y. Chen, “Manipulate the transmission using index-near zeroor epsilon-near-zero metamaterials with coated defects”, Plasmonics 7, 353(2012).

110. J. Luo, P. Xu,H.Y. Chen, B. Hou, L. Gao, and Y. Lai, “Realizing almost perfect bendingwaveguides with anisotropic epsilon-near-zero metamaterials”, Appl. Phys. Let.100, 221903 (2012).

109. J. Luo, P. Xu,and L. Gao, “Electrically controllable unidirectional transmission in aheterostructure composed of a photonic crystal and a deformable liquiddroplet”, Solid State Commun. 152, 577 (2012).

108. Y. Huang and L.Gao, “Nonlocal effects on surface enhanced Raman scattering from bimetalliccoated nanoparticles”, PIER 133, 581 (2012).

107. J. Luo, P. Xu,and L. Gao, “Directive emission based on one-dimensional metalheterostructures”, J. Opt. Soc. Am. B 29, 35 (2012).

106. Y.D. Yin, L. Gao,and C.W. Qiu, “Electromagnetic theory of tunable SERS manipulated withspherical anisotropy in coated nanoparticles”, J. Phys. Chem. C 115 8893 (2011)

105. D.L. Gao, L. Gao,and C.W. Qiu, “Birefringence-induced polarization-independent and nearlyall-angle transparency through a metallic film”, EPL 95, 34004 (2011)

104.Y.D. Xu, S.W. Du, and L. Gao et al. “Overlappedillusion optics: a perfect lens brings a brighter feature” NewJ. Phys.13023010 (2011)

103.Y.X. Ni, D.L. Gao, Z.F. Sang, and L. Gao. “Influence ofspherical anisotropy on the optical properties of plasmon resonant metallicnanoparticles” Appl. Phys. A 102 (3), 673-679 (2011)

102. Y.D. Xu, L. Gao, and H.Y. Chen, “Cloak an illusion” Frontiers of Physics in China6 (1),61-64 (2011)

101. Y.Y. Huang, W.T. Dong, and L. Gao, Large positive andnegative lateral shifts near pseudo-Brewster dip on reflection from a chiralmetamaterial slab”, Opt. Express,19 (2),1310-1323 (2011)

100. H.L. Fu and L. Gao,”Theoryfor anisotropic thermal conductivity of magnetic nanofluids”, Phys. Lett. A377, 3588 (2011).

99. J. Luo, P. Xu, T.T. Sun, andL. Gao, “Tunable beam splitting and negative refraction in heterostructure withmetamaterial”, Appl. Phys. A 104, 1137 (2011).

98. T.T. sun, J. Luo, P. Xu, andL. Gao, “Independently tunable transmission-type magneto-optical isolatorsbased on multilayers containing magnetic materials”, Phys. Lett. A 375, 2185(2011).

97. J. Luo, P. Xu, and L. Gao, “Controllableswitching behavior of optical Tamm state based on nematic liquid crystal”,Solid State Commun. 151, 993 (2011).

96. Y.Gao, J.P. Huang, Y.M. Liu, L. Gao, K.W. Yu, and X. Zhang, “Optical negativerefraction in ferrofluids with magnetocontrollability”, Phys. Rev. Lett. 104,034501 (2010).

95. Y.X.Ni, L. Gao, and C.W. Qiu, “Achieving invisibility of homogeneous cylindricallyanisotropiccylinders”, Plasmonics 5,251 (2010).

94. C.W.Qiu, L. Gao, J.D. Joannopoulos, and M. Soljacic, “light scattering fromanisotropic particles: propagation, localization , and nonlinearity”, Laser& Photon. Rev. 4, 268 (2010).

93. Y.W.Jin, D.L. Gao, and L. Gao, “Plasmonics resonant light scattering by a cylinderwith radial anisotropy”, Prog. Electromagnetic Research, PIER 106, 335 (2010).

92. C.W.Qiu, A. Novitsky, and L. Gao, “Inverse design mechanism of cylindrical cloakswithout knowledge of the required coordinate transformation”, J. Opt. Soc. Am.A 27, 1079 (2010).

91. D.L.Gao and L. Gao, “Goos-Hanchen shift of the reflection from nonlinearnanocomposites with electric field tunability”, Appl. Phys. Lett. 97, 041903(2010).

90. B.Zhao and L. Gao, “Temperature dependent Goos-Hanchen shift on the interface ofmetal/dielectric composites”, Opt. Express 17, 21433 (2009).

89. Y.Y.Huang and L. Gao, “Effective negative refraction in anisotropic layeredcomposites”, J. Appl. Phys. 105, 013512 (2009).

88. D.L.Gao and L. Gao, “Tunable lateral shift through nonlinear composites ofnonspherical particles”, Prog. Electromagnetic Research, PIER 99, 273 (2009).

87. W.T.Dong, L. Gao, and C.W. Qiu, “Goos-Hanchen shift at the surface of chiralnegative refractive media”, Prog. Electromagnetic Research, PIER 90, 255(2009).

86. X.P.Miao, L. Gao, and P. Xu, “Faraday magneto-optical rotation in compositionallygraded films”, J. Appl. Phys. 103, 023512 (2008).

85. X.F.Zhou and L. Gao, “Thermal conductivity of nanofluids: Effects of gradednanolayers and mutual interation”, J. Appl. Phys. 103, 083503 (2008).

84. W.T.Dong and L. Gao, “Negative refraction in chiral composite materials”, J. Appl.Phys. 104, 023537 (2008).

83. L.Gao, T.H. Fung, K.W. Yu, and C.W. Qiu, “Electromagnetic transparency by coatedspheres with radial anisotropy”, Phys. Rev. E 78, 046609 (2008).

82. C.W.Qiu and L. Gao, “Resonant light scattering by small coated nonmagnetic spheres:magnetic resonances, negative refraction, and prediction”, J. Opt. Soc. Am. B25, 1728 (2008).

81.L.H. Shi and L. Gao, “Subwavelength imagingfrom a multilayered structure containing interleaved nonsphericalmetal-dielectric composites”, Phys. Rev. B 77, 195121 (2008).

80.L.H. Shi, S.M. Wang, C.J. Tang, and L. Gao, “Omnidirectionalsurface guided modes from one-dimensional photonic crystal formed bysingle-negative materials”, J.M.M.M. 311, 609 (2007).

79. L.H. Shi, L. Gao, S.L. He, and B.W. Li, “Superlensfrom metal/dielectric composites of nonsphericalparticles”, Phys. Rev. B 76, 045116 (2007).

78.L. Gao, Y. Huang, and C. Tang, “Surfacepolaritons and transmission in multi-layerstructures containing anisotropic left-handed materials”, Appl. Phys. A87, 199 (2007).

77.L. Gao, and X.P. Yu, “Second and thirdharmonic generations for a nondilute suspension of coated particles with radialdielectric anisotropy”, Eur. Phys. J. B 55, 402 (2007).

76. L. Gao, X.F. Zhou, and Y.L. Ding, “Effective thermaland electrical conductivity of carbon nanotubecomposites”, Chem. Phys. Lett. 434 297 (2007).

75. Y. Ma and L. Gao, “Subluminal and superluminal pulsepropagation in inhomogeneous media of nonspherical particles”, Phys. Lett. A355 413 2006.

74. X.F. Zhou and L. Gao, “Effectivethermal conductivity in nanofluids of nonspherical particles with interfacialthermal resistance: Differential effectivemedium theory” , J. Appl. Phys. 100, 024913(2006).

73.S.M. Wang andL. Gao, “Nonlinear responses of the periodic structure composed of singlenegative materials”, Opt. Commun. 267, 197 (2006).

72. X.P. Yu and L. Gao, “Nonlinear dielectric responsesin partially resonant composites withradial dielectric anisotropy”, Phys. Lett. A 359, 516 (2006).

71. L. Gao, “Decreased group velocity in compositionallygraded films”, Phys. Rev. E73, 036602(2006)

70. S.M. Wang, C.J. Tang, T. Pan and L. Gao, “Nonlinearresponses in the defect structures containing single negative materials”, Phys.Lett. A348, 424 (2006).

69.S.M. Wang, C.J. Tang, T. Pan and L. Gao, “Effectivelynegatively refractive material made of negative-permittivity and negativepermeability bilayer”, Phys. Lett. A 351, 391 (2006).

68. L. Gao and X.F. Zhou, “Differential effective mediumtheory forthermal conductivity innanofluids”, Phys. Lett. A 348, 355 (2006).

67. L. Gao, C.J. Tang and S.M. Wang, “Photonic Band Gapfrom a Stack of Single-negative Materials”, J.M.M.M. 301, 371 (2006).

66. B. Liu, L. Gao and K.W. Yu, “Effective nonlinearoptical properties in compositionally graded films: Analytical and numericalcalculations”, Phys. Rev. B 72, 214208 (2005).

65. S.M. Wang, C.J. Tang, T. Pan and L. Gao, “Nonlinearresponses in the defect structures containing single negative materials”, Phys.Lett. A (in press) 2005

64. S.M. WangandL. Gao, “Omnidirectional reflection from the one-dimensional photonic crystalcontaining anisotropic left-handed material”, Eur. Phys. J. B 48, 29 (2005).

63. L.P. Gu and L. Gao, “Optical bistability of anondilute suspension of nonlinear coated particles”, Physica B368, 279 (2005).

62. B. Liu and L. Gao, “Second and third harmonicgenerations in random composite of spheroidal particles”, Phys. Sta. Sol. B242, 1307 (2005).

61.T. Pan, C.J. Tang, L. Gao and Z.Y. Li, “Opticalbistability of nonlinear multilayer structure containing left-handed material”,Phys. Lett. A 337, 473 (2005).

60. L. Gao and K.W. Yu, “Second and third-harmonicgenerations in random composites of graded spherical particles”, Phys. Rev. B72, 075111 (2005).

59. L.P. Gu and L. Gao, “Higher-order nonlinearresponses in weakly nonlinear composite materials within the effective mediumapproximation”, Acta Physica Sinica 54, 987 (2005).

58.L. Gao and Y. Ma, “Enhanced group velocity incomposite media with shape or shape distribution”, J. Phys. A: Math. Gen. 38,7765 (2005).

57.L. Gao, “Optical nonlinearity enhancement ofcompositionally graded films”, Eur. Phys. J. B 44, 481 (2005).

56.L. Gao, “Second and third harmonic generations incompositionally graded films”, Phys. Rev. E 76, 067601 (2005).

55. L. Gao and X.P. Yu, “Optical bistability innonlinear mixtures of coated inclusions with dielectric anisotropy”, Phys.Lett. A 335, 457 (2005).

54. L. Gao and K.W. Yu,“Theory of nondegenerate nonlinear optical susceptibilities of gradedcomposites with high volume fractions”, Phys. Rev. E 71, 017601 (2005).

53. L. Gao, B. Liu and D.L. Yao, “Effective nonlinearresponse of random resistor networks with anomalous distribution ofconductances”, Solid State Commun. 132, 821 (2004).

52.B. Liu andLei Gao, “Numerical study of effective optical nonlinear properties incomposites with anomalous distribution”, Phys. Lett. A332, 147 (2004)

51.J.P. Huang,L. Gao, K.W. Yu, and G.Q. Gu, Nonlinear alternating current response of graded materials, Phys. Rev. E 69, 036605 (2004)

50.Y.Y. Huangand L. Gao, left-handedmaterial containing spherical and nonspherical metallic and magnetic particles, Phys. Lett. A 328, 225(2004)

49. L. Gao and Y.Y. Huang, Extinction properties of a coatedsphere containing a left-handed material, Opt. Commun. 239, 25 (2004)

48.L.P. Gu, L. Gaoand Z.Y. Li,spectral representation theory for higher-order nonlinear responsein random composites with arbitrary nonlinearityPhys. Stat. Solidi B 241, 1115(2004).

47.L. Gaospectral representation theory forhigher-order nonlinear response in random compositesPhys. Lett. A 322, 250 (2004).

46. L. GaoJ.P. Huang and K.W. YuEffective nonlinear optical properties of composite media of gradedinclusionsPhys. Rev. B69 075105(2004).

45.L. GaoL.P. Gu and Y.Y. HuangEffective medium approximation for optical bistabilityin nonlinear metal/dielectric composites Solid State Commun129, 593 (2004).

44.C.J. Tang andLei Gao, “Surface polaritons and imaging properties of a multi-layer structurecontaining negative refractive index materials”, J. Phys. Condens. Matter 16,4743 (2004).

43. L. Gao and C.J. Tang, “Near field imaging by amultilayer structure consisting of alternate right-handed and left-handedmaterials,” Phys. Lett. A 322, 390 (2004).

42.L.GaoJ.P. Huang and K.W. YuGiant enhancement of opticalnonlinearity in mixtures of graded particles with dielectric anisotropy Eur. Phys. Journ. B 36 475 (2003).

41.L. GaoL.P. Gu and Z.Y. Li Optical bistabilityand tristability in nonlinearmetal/dielectriccomposite media withnonspherical inclusionsPhys. Rev. E 68 066601(2003).

40L. GaoJ.P. Huangand K.W. YuTheory of acelectrokinetic behavior

of spheroidal cell suspensions with an intrinsic dispersionPhys. Rev. E 67021910 (2003).

39. L. Gao X.Q. Luo S.Q. Zhu and Bambi HuDispersive anomalous diffusivetransport in rachets with long-range correlated spatial disorderPhys. Rev. E 67 062104 (2003).

38. L. Gao and Y.Y. HuangEffective nonlinear optical properties of shape distributedcomposite media EuropeanPhys. Journ. B 33 165 (2003).

37. L. Gao and Z.Y. LiEffective medium approximation for two-component nonlinearcomposites with shape distribution J. Phys. Condens. Matter154397 (2003).

36. L. Gao Yanyan Huang and Z.Y. LiEffective medium approximation forstrongly nonlinear composite media with shape distribution Phys. Lett. A306 337 (2003).

35. L. GaoEffective medium approximation forweakly nonlinear metal/dielectric composites with shape distribution Phys. Lett. A 309, 407 (2003).

34. Y.Y. Huang and L. GaoNegative refractive index in composite media with metallic magneticinclusions Phys. Lett.A318 592 (2003).

33. L. Gao Optical bistability in compositemedia with nonlinear coated inclusions Phys. Lett. A 318119 (2003).

32.L. GaoEffective nonlinear response in random mxiture of coated granularcylindersPhys. StatusSolid B 236182 (2003).

31. L. GaoMaxwell-Garnett type approximationfor nonlinear composites with shape

distribution Phys. Lett. A309 435 (2003).

30. J.P. HuangL. Gao and Z.Y. LiAC response of ER fluid with aintrinsic dispersion” J. Appl. Phys. 93 2871 (2003).

29. L. Gao and Z.Y. LiEffect of Temperature on Nonlinear Optical Properties of CompositeMedia with Shape Distribution J. Appl. Phys.91 2045 (2002).

28. L. Gao and J.Z. GuEffective Dielectric Constant of a two Component Material with ShapeDistribution J. Phys. D:Applied Phys. 35267 (2002).

27. L. GaoJ.Z. Gu and Bambi HuDriven dynamics in an undampedFrenkel Kontorova model in the presence of a quasiperiodic potential and athermal bathPhys. Rev. B66064309 (2002).

26. J.Z. GuL. Gao and Bambi HuFluctuation of the strengthfunctionPhys. Rev.E66026208 (2002).

25. J. Z. GuL. Gao and Bambi HuFinite size effect on the strengthfunction in a random matrix analysisPhys. Rev. C 66 054312 (2002).

24. L. GaoK.W. YuZ.Y. Li and Bambi HuEffective nonlinear optical properties of metal-dielectric compositemedia with shape distributionPhys. Rev. E 64 036615 (2001).

23. L. GaoZ.Y. Li and K.W. YuEnhancement of optical nonlinearity through shape distributionJ. Phys.: Condens. Matter 137271 (2001).

22. J.P. HuangL. Gao and Z.Y. LiOptical Response of Metal/Dielectric Composite ContainingInterfacial LayersCommun. Theor. Phys. 36251(2001).

21. L. GaoJ.T.K. WanK.W. Yu and Z.Y. LiForce between two spherical inclusions in a nonlinear host mediumPhys. Rev. E 616011 (2000).

20. L. GaoJ.T.K. WanK.W. Yu and Z.Y. Li Effect of interfacial property and particle size distribution onoptical nonlinearity in granular composite J. Appl. Phys. 881893(2000).

19. L. GaoJ.T.K. WanK.W. Yu and Z.Y. LiEffect nonlinear optical properties of fmetal/dielectric compositesof spheroidal particles J. Phys. Condens. Matter 126825(2000).

18. L. Gao and Z.Y. LiThird-order nonlinear optical response of metal/dielectric compositeJ. Appl. Phys. 87 1620 (2000).

17. L. Gao and Z.Y. LiCrossover exponents in percolatingnonlinear normal conductor/insulator random network Phys. Status Solidi(b)218519 (2000).

16. L. Gao and Z.Y. LiTemperature dependence ofnonlinear optical properties in metal/dielectriccomposites Phys.Status Solidi(b)218 571 (2000).

15. J. P. HuangL. Gao and Z. Y. LiTemperature Effect on Nonlinear OpticalResponse in Metal/Dielectric Composite with Interfacial LayerSolid State Commun. 115 347(2000).

14. Y. M. WuL. Gao and Z. Y. Lithe influence of Particle Shape onNonlinear Properties of Metal/Dielectric Composites Phys. StatusSolidi (b) 220997(2000).

13. L. GaoW.G. Lu and Z.Y. LiComment on crossover exponents in percolatingsuperconductor/nonlinear conductor mixtures’”Phys. Rev. B59 668 (1999).

12. L. Gao and Z.Y. LiCrossover exponents in percolating nonlinear normal conductor/insulator mixturePhysicaA271 238 (1999).

11. L. Gao and Z.Y. Li,Crossover Exponents insuperconductor-nonlinear normal conductor network below the percolationthresholdJ. Phys.Condens. Matter 118727 (1999).

10. L. GaoQ. Jiang and Z.Y. LiCritical behaviour of nonlinear properties in percolatingsuperconductor /nonlinear-normal conductor network , Commun. Theor. Phys. 32241 (1999).

9. L. Gao and Z.Y. LiEffective nonlinear response inmixed nonlinear inhomogeneous conductor composite Physica B 245103(1998).

8. L. Gao and Z.Y. LiCritical properties of nonlinearsusceptibility for weakly-nonlinear compositesJ. Phys. Condens. Matter 10 9723 (1998).

7. L. Gao and Z.Y. LiTemperature dependence ofnonlinear optical response in metal/dielectric composite media Solid State Commun. 107751 (1998).

6. L. Gao and Z.Y. LiNonlinear susceptibility ofstrongly nonlinear composites Commun.

Theor. Phys. 27 403 (1997).

5. L. Gao and Z.Y. LiEffective nonlinear conductivityof strongly nonlinear composites with H-S microgeometrySolid State Commun. 10229 (1997).

4X.Y. Liu L. Gao and Z. Y. LiEffective NonlinearSusceptibilities ofRandom Mixture of Coated Granular Cylinders Physica B 240378 (1997).

3. L. Gao and Z.Y. LiEffective response of a stronglynonlinear composite:comparison with variational approachPhys. Lett. A 222207 (1996).

2. L. Gao and Z.Y. LiSelf-consistent formalism for astrongly nonlinear composite: comparison with variational approach Phys. Lett. A 219324 (1996).

1. L. Gao and Z.Y. LiNonlinear thermal conductivity ofgranular composite mediumSolid

State Commun. 9653 (1996).




荣誉奖励
  • 1、金属颗粒复合介质的非线性光学 省科技进步二等奖,江苏省科技厅,2001
  • 2、第二期计划中青年学术带头人培养人选 江苏省高校“青蓝工程”,江苏省教育厅,2002
  • 3、省优秀博士学位论文,江苏省学位委员会,2004
  • 4、江苏省“333高层次人才培养工程”第三层次培养人选,江苏省人事厅,2007
  • 5、2020年获苏州大学优秀共产党员和苏州大学“我最喜爱的老师”
  • 6、主讲的研究生课程获得江苏省优秀研究生课程
  • 7、教研成果分获苏州市和校级教学成果二等奖和一等奖
  • 8、指导本科毕业论文获省优秀毕业论文三等奖2次
  • 9、指导学生获得江苏省高校大学生物理及实验科技作品竞赛特等奖
  • 10、两次获江苏省科技进步二等奖(排名第一和第二)
开授课程

1、承担本科生“量子力学”、“金融中的趣味物理”、“时间简史”等课程教学任务。

2、承担研究生“量子统计物理学”和“异质复合介质的电磁性质”等课程教学任务。


招生信息

欢迎对本人研究领域感兴趣的研究生加入课题组!

1、每年招收硕士研究生2-3

2、每年招收博士研究生1名。