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教师简介
唐超军

学校教师主页介绍


    唐超军,安徽阜阳人,博士(后),副教授,硕士生导师。

 

       一、 教育背景与工作经历

1998.09-2002.06,安庆师范大学物理系,学士。

2002.09-2005.06,苏州大学物理系,硕士(导师: 高  雷 教授)。

2005.09-2010.06,南京大学物理系,博士(导师: 王振林 教授)。

2010.06-2012.06, 南京大学微结构国家实验室,博士后(导师:王振林 教授)。

2012.06----至今,浙江工业大学理学院,专任物理教师。


二、 主要研究领域

人工超构材料(metamaterials)的设计、制备和奇异电磁性 质;金属微纳结构中表面等离激元(surface plasmons)共振在表面增强拉曼散射(SERS)、传感、光催化、太阳能等方面的应用。

 

三、 主持项目

(1) 金属纳米结构中表面等离激元的Fano共振(No.11104136),国家自然科学基金委,青年基金项目,2012.01-2014.12,项目负责人。 30万

(2) 超构材料中光频磁场增强及表面增强拉曼散射(No.LY14A040004),浙江省自然科学基金委,面上项目,2014.01-2016.12,项目负责人。 8.5万

(3) 超薄类金刚石薄膜包覆金属微纳结构的奇异表面等离激元特性引发的表面增强拉曼(No.11104135),国家自然科学基金委,青年基金项目,2012.01-2014.12,第二参与人。 26万

(4) 超薄ta-C薄膜包覆Ag-Bowtie结构及其表面增强拉曼散射研究 (No.LY15A040005),浙江省自然科学基金委,面上项目,2015.01-2017.12,第二参与人。8

(5) 金属Bowtie结构耦合电场强度的调控及表面增强拉曼散射研究(No.11574270),国家自然科学基金委,面上项目,2016.01-2019.12,第二参与人。86.8万

 

四、 论文著作

目前为止,在国际知名期刊,已发表SCI论文60余篇,论文被引用800余次,其中他引600余次,最近两年发表的论文如下:

[1] J. Chen*, H. Nie, C. Peng, S. B. Qi, C. J. Tang*, Y. Zhang, L. H. Wang, and G. S. Park*, Enhancing the Magnetic Plasmon Resonance of 3D Optical Metamaterials via Strong Coupling for High-Sensitivity Sensing, J. Lightwave Technol. 36(16), 3481-3485(2018).

[2] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, J. Yuan, H. Tang, X. Q. Zhu, Metal-Substrate-Enhanced Magnetic Dipole Resonance in Metamaterials for High-Performance Refractive Index Sensing, Opt. Mater. Express 8(7), 2008-2016 (2018).

[3] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, L. Zheng, and S. Wang, Tri-Band Absorption Enhancement in Monolayer Graphene in the Visible Spectrum due to Multiple Plasmon Resonances in Metal-Insulator-Metal Nanostructure, Appl. Phys. Express 11(7), 072201 (2018).

[4] J. Chen*, H. Nie, T. Q. Zha, P. Mao, C. J. Tang*, X. Y. Shen, and G. S. Park*, Optical Magnetic Field Enhancement by Strong Coupling in Metamaterials, J. Lightwave Technol. 36(13), 2791-2795 (2018).

[5] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, H. Tang, X. Q. Zhu, and G. S. Park, Multiband and Broadband Absorption Enhancement of Monolayer Graphene at Optical Frequencies from Multiple Magnetic Dipole Resonances in Metamaterials, Nanoscale Res. Lett. 13, 153 (2018).

[6] J. Chen*, Q. Zhang, C. Peng, C. J. Tang*, X. Y. Shen, L. C. Deng, and G. S. Park*, Optical Cavity-Enhanced Localized Surface Plasmon Resonance for High-Quality Sensing, IEEE Photonic. Tech. L. 30(8), 728-731 (2018).

[7] B. Yan#, K. Li#, P. Gu, Z. Li, C. J. Tang, F. X. Liu*, P. Zhan*, C. H. Sui, and Z. L. Wang, Thermal Stability of Ultrathin and High Dielectric ta-C Films Coated with Ag Nanostructures for SERS, J. Raman Spectrosc. 49(3), 431-437 (2018).

[8] J. Chen*, J. Yuan, Q. Zhang, H. M. Ge, C. J. Tang*, Y. Liu, and B. N. Guo, Dielectric Waveguide-Enhanced Localized Surface Plasmon Resonance Refractive Index Sensing, Opt. Mater. Express 8(2), 342-347 (2018).

[9] B. Liu#, C. J. Tang#, *, J. Chen#, *, M. W. Zhu, M. X. Pei, and X. Q. Zhu, Electrically Tunable Fano Resonance from the Coupling between Interband Transition in Monolayer Graphene and Magnetic Dipole in Metamaterials, Sci. Rep. 7, 17117 (2017).

[10] B. Liu#, C. J. Tang#, *, J. Chen#, *, Z. D. Yan, M. W. Zhu, Y. X. Sui, and H. Tang, The Coupling Effects of Surface Plasmon Polaritons and Magnetic Dipole Resonances in Metamaterials, Nanoscale Res. Lett. 12, 586 (2017).

[11] J. Chen*, W. F. Fan, P. Mao, C. J. Tang*, Y. J. Liu, Y. Ying, and L. B. Zhang, Tailoring Plasmon Lifetime in Suspended Nanoantenna Arrays for High-Performance Plasmon Sensing, Plasmonics 12(3), 529-534 (2017).

[12] B. Liu#, C. J. Tang#, *, J. Chen*, Q. G. Wang, M. X. Pei, and H. Tang, Dual-Band Light Absorption Enhancement of Monolayer Graphene from Surface Plasmon Polaritons and Magnetic Dipole Resonances in Metamaterials, Opt. Express 25(10), 12061-12068 (2017).

[13] P. W. Wang#, N. B. Chen#, C. J. Tang*, J. Chen*, F. X. Liu, S. Q. Sheng, B. Yan, and C. H. Sui, Engineering the Complex-Valued Constitutive Parameters of Metamaterials for Perfect Absorption, Nanoscale Res. Lett. 12, 276 (2017).

[14] C. J. Tang#, B. Yan#, Q. G. Wang#, J. Chen#, *, Z. D. Yan, F. X. Liu*, N. B. Chen, and C. H. Sui, Toroidal Dipolar Excitation in Metamaterials Consisting of Metal Nanodisks and a Dielectric Spacer on Metal Substrate, Sci. Rep. 7, 582 (2017).

[15] J. Chen*, W. F. Fan, T. Zhang, C. J. Tang*, X. Y. Chen, J. J. Wu, D. Y. Li, and Y. Ying, Engineering the Magnetic Plasmon Resonances of Metamaterials for High-Quality Sensing, Opt. Express 25(4), 3675-3681 (2017).

[16] J. Chen*, T. Q. Zha, T. Zhang, C. J. Tang*, W. F. Fan, Y. Yu, Y. J. Liu, and L. B. Zhang, Enhanced Magnetic Fields at Optical Frequency by Diffraction Coupling of Magnetic Resonances in Lifted Metamaterials, J. Lightwave Technol. 35(1), 71-74 (2017).


教师简介
唐超军

学校教师主页介绍


    唐超军,安徽阜阳人,博士(后),副教授,硕士生导师。

 

       一、 教育背景与工作经历

1998.09-2002.06,安庆师范大学物理系,学士。

2002.09-2005.06,苏州大学物理系,硕士(导师: 高  雷 教授)。

2005.09-2010.06,南京大学物理系,博士(导师: 王振林 教授)。

2010.06-2012.06, 南京大学微结构国家实验室,博士后(导师:王振林 教授)。

2012.06----至今,浙江工业大学理学院,专任物理教师。


二、 主要研究领域

人工超构材料(metamaterials)的设计、制备和奇异电磁性 质;金属微纳结构中表面等离激元(surface plasmons)共振在表面增强拉曼散射(SERS)、传感、光催化、太阳能等方面的应用。

 

三、 主持项目

(1) 金属纳米结构中表面等离激元的Fano共振(No.11104136),国家自然科学基金委,青年基金项目,2012.01-2014.12,项目负责人。 30万

(2) 超构材料中光频磁场增强及表面增强拉曼散射(No.LY14A040004),浙江省自然科学基金委,面上项目,2014.01-2016.12,项目负责人。 8.5万

(3) 超薄类金刚石薄膜包覆金属微纳结构的奇异表面等离激元特性引发的表面增强拉曼(No.11104135),国家自然科学基金委,青年基金项目,2012.01-2014.12,第二参与人。 26万

(4) 超薄ta-C薄膜包覆Ag-Bowtie结构及其表面增强拉曼散射研究 (No.LY15A040005),浙江省自然科学基金委,面上项目,2015.01-2017.12,第二参与人。8

(5) 金属Bowtie结构耦合电场强度的调控及表面增强拉曼散射研究(No.11574270),国家自然科学基金委,面上项目,2016.01-2019.12,第二参与人。86.8万

 

四、 论文著作

目前为止,在国际知名期刊,已发表SCI论文60余篇,论文被引用800余次,其中他引600余次,最近两年发表的论文如下:

[1] J. Chen*, H. Nie, C. Peng, S. B. Qi, C. J. Tang*, Y. Zhang, L. H. Wang, and G. S. Park*, Enhancing the Magnetic Plasmon Resonance of 3D Optical Metamaterials via Strong Coupling for High-Sensitivity Sensing, J. Lightwave Technol. 36(16), 3481-3485(2018).

[2] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, J. Yuan, H. Tang, X. Q. Zhu, Metal-Substrate-Enhanced Magnetic Dipole Resonance in Metamaterials for High-Performance Refractive Index Sensing, Opt. Mater. Express 8(7), 2008-2016 (2018).

[3] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, L. Zheng, and S. Wang, Tri-Band Absorption Enhancement in Monolayer Graphene in the Visible Spectrum due to Multiple Plasmon Resonances in Metal-Insulator-Metal Nanostructure, Appl. Phys. Express 11(7), 072201 (2018).

[4] J. Chen*, H. Nie, T. Q. Zha, P. Mao, C. J. Tang*, X. Y. Shen, and G. S. Park*, Optical Magnetic Field Enhancement by Strong Coupling in Metamaterials, J. Lightwave Technol. 36(13), 2791-2795 (2018).

[5] B. Liu#, C. J. Tang#, *, J. Chen#, *, N. Y. Xie, H. Tang, X. Q. Zhu, and G. S. Park, Multiband and Broadband Absorption Enhancement of Monolayer Graphene at Optical Frequencies from Multiple Magnetic Dipole Resonances in Metamaterials, Nanoscale Res. Lett. 13, 153 (2018).

[6] J. Chen*, Q. Zhang, C. Peng, C. J. Tang*, X. Y. Shen, L. C. Deng, and G. S. Park*, Optical Cavity-Enhanced Localized Surface Plasmon Resonance for High-Quality Sensing, IEEE Photonic. Tech. L. 30(8), 728-731 (2018).

[7] B. Yan#, K. Li#, P. Gu, Z. Li, C. J. Tang, F. X. Liu*, P. Zhan*, C. H. Sui, and Z. L. Wang, Thermal Stability of Ultrathin and High Dielectric ta-C Films Coated with Ag Nanostructures for SERS, J. Raman Spectrosc. 49(3), 431-437 (2018).

[8] J. Chen*, J. Yuan, Q. Zhang, H. M. Ge, C. J. Tang*, Y. Liu, and B. N. Guo, Dielectric Waveguide-Enhanced Localized Surface Plasmon Resonance Refractive Index Sensing, Opt. Mater. Express 8(2), 342-347 (2018).

[9] B. Liu#, C. J. Tang#, *, J. Chen#, *, M. W. Zhu, M. X. Pei, and X. Q. Zhu, Electrically Tunable Fano Resonance from the Coupling between Interband Transition in Monolayer Graphene and Magnetic Dipole in Metamaterials, Sci. Rep. 7, 17117 (2017).

[10] B. Liu#, C. J. Tang#, *, J. Chen#, *, Z. D. Yan, M. W. Zhu, Y. X. Sui, and H. Tang, The Coupling Effects of Surface Plasmon Polaritons and Magnetic Dipole Resonances in Metamaterials, Nanoscale Res. Lett. 12, 586 (2017).

[11] J. Chen*, W. F. Fan, P. Mao, C. J. Tang*, Y. J. Liu, Y. Ying, and L. B. Zhang, Tailoring Plasmon Lifetime in Suspended Nanoantenna Arrays for High-Performance Plasmon Sensing, Plasmonics 12(3), 529-534 (2017).

[12] B. Liu#, C. J. Tang#, *, J. Chen*, Q. G. Wang, M. X. Pei, and H. Tang, Dual-Band Light Absorption Enhancement of Monolayer Graphene from Surface Plasmon Polaritons and Magnetic Dipole Resonances in Metamaterials, Opt. Express 25(10), 12061-12068 (2017).

[13] P. W. Wang#, N. B. Chen#, C. J. Tang*, J. Chen*, F. X. Liu, S. Q. Sheng, B. Yan, and C. H. Sui, Engineering the Complex-Valued Constitutive Parameters of Metamaterials for Perfect Absorption, Nanoscale Res. Lett. 12, 276 (2017).

[14] C. J. Tang#, B. Yan#, Q. G. Wang#, J. Chen#, *, Z. D. Yan, F. X. Liu*, N. B. Chen, and C. H. Sui, Toroidal Dipolar Excitation in Metamaterials Consisting of Metal Nanodisks and a Dielectric Spacer on Metal Substrate, Sci. Rep. 7, 582 (2017).

[15] J. Chen*, W. F. Fan, T. Zhang, C. J. Tang*, X. Y. Chen, J. J. Wu, D. Y. Li, and Y. Ying, Engineering the Magnetic Plasmon Resonances of Metamaterials for High-Quality Sensing, Opt. Express 25(4), 3675-3681 (2017).

[16] J. Chen*, T. Q. Zha, T. Zhang, C. J. Tang*, W. F. Fan, Y. Yu, Y. J. Liu, and L. B. Zhang, Enhanced Magnetic Fields at Optical Frequency by Diffraction Coupling of Magnetic Resonances in Lifted Metamaterials, J. Lightwave Technol. 35(1), 71-74 (2017).