梁二軍

梁二軍

梁二軍,男,研究生,鄭州大學教授、博士生導師,物理工程學院、光電信息科學研究所所長。

基本介紹

  • 中文名:梁二軍
  • 職業:教師
  • 畢業院校:河南大學
  • 學位/學歷:研究生
  • 職務:鄭州大學光電信息科學研究所所長
人物經歷,研究方向,學術成果,科研項目,獲獎記錄,代表論文,出版專著,專利,

人物經歷

1982.7-1985.8河南大學物理系助教;
1988.5-1992.9鄭州大學分析測試中心講師;
1992.10-1993.9德國維爾茨堡大學國家公派訪問學者;
1996.5-至今 鄭州大學物理工程學院講師、教授(1988-)、博士生導師(2001-);
2002.11-2003.10 葡萄牙米尼奧大學物理中心訪問學者。
1978.10-1982.6河南大學物理系學習,獲理學學士學位;
1985.9-1988.4 華中科技大學物理系凝聚態物理專業研究生,獲理學碩士學位;
1992.10-1996.3德國維爾茨堡大學物理化學研究所攻讀博士研究生,獲理學博士學位。

研究方向

負熱膨脹材料物理及套用;表面等離激元光子學;電磁波(光學)與信息傳輸.
(1)負熱膨脹材料物理及套用:該方向主要開展負熱膨脹材料的熱縮機制、負熱膨脹材料的性能調控、新型負熱膨脹材料的設計及功能化、具有一定物理性能的可控膨脹及零膨脹複合材料設計等研究。
(2)表面等離激元光子學:該方向主要開展新型電磁超介質(metamaterial)的設計和電磁回響特性及基於電磁超介質的器件設計等研究,包括負折射、局域電磁場增強、完美吸收、電磁感應透明、Fano共振型電磁超介質及其在非線性光學中的套用等。
(3)電磁波(光)與信息傳輸:該方向主要基於光學原理與CCD/CMOS、空間光調製器、DMD等數位化技術結合,開展3D數字成像技術的物理基礎及成像系統的研究。包括計算成像技術、菲涅耳非相干全息成像技術、單像素成像技術和WI-FI定位與成像技術等。

學術成果

在OpticsExpress、Plasmonics、J.PowerSources、Phys.Rev.E、J.Phys.Chem.C、Phys.Chem.Chem.Phys.等國際國內重要刊物發表論文100餘篇,獲國家發明專利9項、實用新型專利2項。

科研項目

(1)主持:國家自然科學基金面上項目(編號11574276):一類新型負熱膨脹功能化合物的熱縮機制、光學和電學性質研究(2016.01.01-2019.12.31).
(2)主持:國家自然科學基金面上項目(編號10974183);:基於metamaterial電磁回響的高電磁場增強、高穩定性和高重現性表面增強拉曼散射襯底研究(2010.01.01-2012.12.31).
(3)主持:鄭州市科技創新團隊項目(112PCXTD337):雷射技術及其產業化關鍵技術研究(2011.01.01-2015.06.30).
(4)主持:教育部博士點博導類基金(20114101110003):基於metamaterial表面等離激元耦合的完美吸收與電磁場增強效應(2012.01.01-2014.12.31).
(5)共同主持:軍口863項目(編號XXXXXX):XX太赫茲XX技術研究(2007.07.01-2010.06.30).
(6)主持:河南省重大科技攻關項目(編號321000600):雷射表面強化及刻槽關鍵技術研究與產業化(2005.01.01-2007.12.31).
(7)主持:河南省傑出人才創新基金(編號0121001200):金屬表面大面積雷射強化與改性的若干關鍵技術研究(2001.01.01-2004.12.31).
(8)主持:河南省高校創新人才培養對象基金(編號1999-125):輕多金屬摻雜碳納米管的製備與性能研究(2000.01.01-2004.12.31).

獲獎記錄

(1)大型模切輥的雷射表面硬化技術,河南省教育廳科技成果二等獎(200403517).
(2)塑膠擠出機換網器表面雷射強化技術,河南省教育廳科技成果二等獎(9412004Y0344).

代表論文

[1] Jinna He, Pei Ding, Junqiao Wang, Chunzhen Fan and Erjun Liang*, Ultranarrow band perfect absorbers based on plasmonic analog of electromagnetically induced absorption, OPTICS EXPRESS, 2015: 23(5), 6083-6091.
[2] Shuangmei Zhu, Chunzhen Fan, Junqiao Wanga, Jinna He, Erjun Liang*, Mingju Chao, Realization of high sensitive SERS substrates with onepot fabrication of Ag–Fe3O4 nanocomposites, Journal of Colloid and Interface Science 438 (2015) 116–121.
[3] J. N. He, J. Q. Wang, P. Ding, C. Z. Fan, L. R. Arnaut, E. J Liang*, Optical Switching Based on Polarization Tunable PlasmonInduced Transparency in Disk/Rod Hybrid Metasurfaces, Plasmonics, 2015: 10(5),1115-1121.
[4] Jinna He, Junqiao Wang, Pei Ding, Chunzhen Fan and Erjun Liang*, Gain-assisted plasmon induced transparency in T-shaped metamaterials for slow light, J. Opt. 17 (2015) 055002.
[5] Y. G. Cheng, X. S. Liu, H. J. Chen, M. J. Chao and E. J. Liang*, In situ investigation of the surface morphology evolution of the bulk ceramic Y2Mo3O12 during crystal water release, Phys.Chem.Chem.Phys., 2015, 17, 10363-10368.
[6] J. N. He, P. Ding, J. Q. Wang, C. Z. Fan, E. J. Liang*, Double Fano-type resonances in heptamer-hole array transmission spectra with high refractive index sensing, J. Mod. Opt. 2015: 62(15)1241-1247.
[7] Yanchao Mao, Dalong Geng, Erjun Liang, Xudong Wang, Single-electrode triboelectric nanogenerator for scavenging friction energy from rolling tires, Nano Energy (2015) 15, 227–234.
[8] Xiansheng Liu, Junqiao Wang, Chunzhen Fan, Rui Shang, Fuxing Cheng, Baohe Yuan, Wenbo Song, Yongguang Cheng, Erjun Liang*, and Mingju Chao, Control of Reaction Pathways for Rapid Synthesis of Negative Thermal Expansion Ceramic Zr2P2WO12 with Uniform Microstructure, Int. J. Appl. Ceram. Technol., 2015:12, E28-E33.
[9] Y. M. Liu, Y. Jia∗, Q Sun, E. J. Liang, Mechanism of negative thermal expansion in LaC2 from first-principles prediction, Physics Letters A, 2015, 379: 54–59.
[10] X. Xiao, W. J. Zhou, X. S. Liu, M. J. Chao, Y. C. Li, N. Zhang, Y. M. Liu, Y. X. Li, D. S. Feng. E. J. Liang, Electrical properties of Al-ZrMgMo3O12 with controllable thermal expansion, Ceramic International, 2015: 41(2), 2361-2366.
[11] N. Zhang, W. J. Zhou, M. J. Chao, Y. C. Mao, J. Guo, Y. X. Li, D. S. Feng, E. J. Liang, Negative thermal expansion, optical and electrical properties of HfMnMo2PO12-delta, Ceramic International, 2015: 41(10), 15170-15175.
[12] P. Ding, J. N. He, J. Q. Wang, C. Z. Fan, E. J. Liang, Electromagnetically induced transparency in all-dielectric metamaterial-waveguide system, Appl. Opt. 2015: 54(12), 3708-3714.
[13] J. Q. Wang, K. J. Mu, F. Y. Ma, H. P. Zang, C. Z. Fan, J. N. He, E. J. Liang, P. Ding, Optical refractive nanosensor with planar resonators metamaterial, OPTICS COMMUNICATIONS, 2015: 338, 399-405.
[14] Xiansheng Liu, Yongguang Cheng, Erjun Liang*, Mingju Chao, Interaction of crystal water with the building block in Y2Mo3O12 and the effect of Ce3+ doping, Phys. Chem. Chem. Phys., 2014:16, 12848-12857.
[15] Lei Wang, Peng-Fei Yuan, Fei Wang, Qiang Sun, Zheng-Xiao Guo, Er-Jun Liang*, Yu Jia*, First-principles investigation of negative thermal expansion in II-VI semiconductors, Materials Chemistry and Physics 148 (2014) 214-222.
[16] L. Wang, P. F. Yuan, F. Wang, Q. Sun, E. J. Liang, Yu Jia∗, Zheng-Xiao Guo*, Negative thermal expansion in TiF3 from the first-principles prediction, Physics Letters A, 2014, 378: 2906–2909.
[17] L. Wang, P. F. Yuan, F. Wang, E. J. Liang, Q. Sun, Z. X. Guo*, Y. Jia*, First-principles study of tetragonal PbTiO3: Phonon and thermal expansion, Mate. Res. Bull., 2014, 59: 509-513.
[18] L. J. Fu, M. J. Chao∗, H. Chen, X. S. Liu, Y. M. Liu, J. M. Yu, E. J. Liang, Y. C. Li, X. Xiao, Negative thermal expansion property of Er0.7Sr0.3NiO3−δ, Physics Letters A, 2014, 378: 1909–1912.
[19] Y. C. Mao, W. Li, P. Liu, J. C., E. J. Liang*, Topotactic transformation to mesoporous Co3O4 nanosheet photocathode for visible-light-driven direct photoelectrochemical hydrogen generation, Materials Letters, 2014, 134: 276–280.
[20] S. M. Zhu; C. Z. Fan, J. Q. Wang, J. N. He, E. J. Liang*, M.J. Chao, Surface enhanced Raman scattering of 4-aminothiophenol sandwiched between Ag nanocubes and smooth Pt substrate: The effect of the thickness of Pt film, J. Appl. Phys. 2014, 116(4): 044312.
[21] G. W. Cai, P. Ding, J. Q. Wang and E. J. Liang*, Wide-band perfect optical absorption and photo-thermal effect for three-tier nanogate, Modern Physics Letters B, Vol. 28, No. 16 (2014) 1450135.
[22] Yanchao Mao, Wei Li, Peng Liu, Jian Chen, Erjun Liang*,Topotactic transformation to mesoporous Co3O4 nanosheet photocathode for visible-light-driven direct photoelectrochemical hydrogengeneration, Materials Letters, 134(2014)276–280.
[23] Wenbo Song, Baohe Yuan Xiansheng Liu, Zhiyuan Li, Junqiao Wang and Erjun Liang*, Tuning the monoclinic-to-orthorhombic phase transition temperature of Fe2Mo3O12 by substitutional co-incorporation of Zr4+ and Mg2+, J. Mat. Res., 2014 ,29 (7 ):855.
[24] Shuangmei Zhu, Chunzhen Fan, Junqiao Wang, Jinna He, Erjun Liang*, Surface-enhanced Raman scattering of 4-mercaptobenzoic acid and hemoglobin adsorbed on self-assembled Ag monolayer films with different shapes, Appl. Phys. A (2014) 117:1075–1083.
[25] B. H. Yuan, H. L. Yuan, W. B. Song, X. S. Liu, Y. G. Cheng M.J. Chao, E. J. Liang*, High Solubility of Hetero-Valence Ion (Cu2+) for Reducing Phase Transition and Thermal Expansion of ZrV1.6P0.4O7, CHIN. PHYS. LETT. Vol. 31, No. 7 (2014) 076501.
[26] W. B. Song, J. Q. Wang, Z. Y. Li, X. S. Liu, B. H. Yuan, E. J. Liang*, Phase transition and thermal expansion property of Cr2−xZr0.5xMg0.5xMo3O12 solid solution, Chin. Phys. B Vol. 23, No. 6 (2014) 066501.
[27] Baohe Yuan, Xiansheng Liu, Wenbo Song, Yongguang Cheng, Erjun Liang*, Mingju Chao, High solubility of Fe3+for Zr4+in ZrV1.6P0.4O7with small amount of FeV0.8P0.2O4for low thermal expansion, Physics Letters A, 2014:378(45),3397-3401.
[28] X.S. Liu,F.Li,W.B.Song,B.H.Yuan,Y.G.Cheng,E.J.Liangn, M.J.Chao, Control of reaction processes for rapid synthesis of low-thermal-expansion Ca1-xSrxZr4P6O24 ceramics, Ceramics International, 40(2014)6013–6020.
[29] Fang Li, Xiansheng Liu,Wenbo Song, Baohe Yuan,Yongguang Cheng, Huanli Yuan, ,Fuxing Cheng, Mingju Chao,Erjun Liang*, Phase transition, crystal water and low thermal expansion behavior of Al2-2x(ZrMg)xW3O12 n(H2O), Journal ofSolidStateChemistry218(2014)15–22.
[30] Y. Liang*,H. Z. Xing,M. J. Chao, E. J. Liang,Syntheses of negative thermal expansion materials Sc2(MO4)3 (M = W, Mo) with a CO2 laser and their Raman spectra, Acta Physica Sinica, 2014, 63(24): 248106.
[31] P. Ding, G. W. Cai, J. Q. Wang, J. N. He, C. Z. Fan,X. M. Liu,E. J. Liang,Low-threshold resonance amplification of out-of-plane lattice plasmons in active plasmonic nanoparticle arrays,J. Opt. 2014, 16: 065003.
[32] Junqiao Wang, Chunzhen Fan, Jinna He, Pei Ding, Erjun Liang*,and Qianzhong Xue, Double Fano resonances due to interplay of electric and magnetic plasmon modes in planar plasmonic structure with high sensing sensitivity, OPTICS EXPRESS, 2013 / Vol. 21, No. 2, 2236-2244.
[33] Xian-Sheng Liu, Fu-Xing Cheng, Jun-Qiao Wang, Wen-Bo Song, Bao-He Yuan, Er-Jun Liang*, The control of thermal expansion and impedance of Al–Zr2(WO4)(PO4)2 nano-cermets for near-zero-strain Al alloy and fine electrical components, Journal of Alloys and Compounds 553 (2013) 1–7.
[34] Jinna He, Chunzhen Fan, Junqiao Wang, Pei Ding, Genwang Cai, Yongguang Cheng, Shuangmei Zhu and Erjun Liang*, A giant localized field enhancement and high sensitivity in an asymmetric ring by exhibiting Fano resonance, J. Opt. 15 (2013) 025007.
[35] Xian-Sheng Liu, Bao-He Yuan, Jun-Qiao Wang, Wen-Bo Song, Fu-Xing Cheng, Er-Jun Liang*, Ming-Ju Chao, Synthesis, thermal expansion and optical properties of (1-x)NaAl(MoO4)2–xNaEr(MoO4)2 ceramics, Journal of Alloys and Compounds, 564 (2013) 63–70.
[36] Xiansheng Liu, Junqiao Wang, Erjun Liang∗, Weifeng Zhang, Enhancing mechanism of visible-light absorption for photovoltaic response and photoluminescence of Zn2SnO4with high solubility of Bi3+, Applied Surface Science, 2013: 280:556-563.
[37] W. B. Song, E. J. Liang*, X. S. Liu, Z. Y. Li, B. H. Yuan, J. Q. Wang, A Negative Thermal Expansion Material of ZrMgMo3O12, Chin. Phys. Lett., 2013, 30(12):126502.
[38] Junqiao Wang, Baohe Yuan, Chunzhen Fan, Jinna He, Pei Ding, Qianzhong Xue, and Erjun Liang, A novel planar metamaterial design for electromagnetically induced transparency and slow light, OPTICS EXPRESS 2013 Vol. 21, No. 21, 25159 -25166.
[39] Junqiao Wang, Xiaomin Liu, Lei Li, Jinna He, Chunzhen Fan, Yongzhi Tian, Pei Ding, Dongxia Chen, Qianzhong Xue and Erjun Liang, Huge electric field enhancement and highly sensitive sensing based on the Fano resonance effect in an asymmetric nanorod pair, J. Opt. 15 (2013) 105003.
[40] Shuangmei ZHU, Chunzhen FAN, Junqiao WANG, Jinna HE, and Erjun LIANG*, Self-Assembled Ag Nanoparticles for Surface Enhanced Raman Scattering, OPTICAL REVIEW Vol. 20, No. 5 (2013) 361–366.
[41] R. Shang, Q.L. Hu, X.S.Liu, E.J.Liang*, B.Yuan, M.J.Chao, Effect of MgO and PVA on the Synthesis and Properties of Negative Thermal Expansion Ceramics of Zr2(WO4)(PO4)2, International Journal of Applied Ceramic Technology, 2013: 10, 849-856.
[42] J. Zhang, Yuan Chao, J, Q, Wang, E. J. Liang*, M. J. Chao, Oxygen ion conductivity of La0.8Sr0.2Ga0.83Mg0.17-xCoxO3-d synthesized by laser rapid solidification, Chin. Phys. B, 2013, 22: 087201.
[43] C. Z. Fan, J. Q. Wang, S. M. Zhu, J. N. He, P. Ding, E. J. Liang, Optical properties in one-dimensional graded soft photonic crystals with ferrofluids , J.Opt. 2013, 15(5): 055103.
[44] C. Z. Fan, J. Q. Wang, J. N. He, P. Ding, E. J. Liang. Theoretical study on the photonic band gap in one-dimensional photonic crystals with graded multilayer structure, Chin. Phys. B, 2013, 22: 074211.
[45] C. Z. Fan, J. Q. Wang, Y. G. Cheng, E. J. Liang, J. P. Huang, Electric field distribution around the chain of composite nanoparticles in ferrofluids, Chin. Phys. B, 2013, 22: 084703.
[46] C. Z. Fan, E. J. Liang, J. P. Huang, Optical properties of one-dimensional soft photonic crystals with ferrofluids, FRONTIERS OF PHYSICS, 2013, 8(1): 1-19.
[47] D. C. Li, J. M. Yu, M. J. Chao*, M. Y. Li, H. E. J. Liang, Effects of synthesis condition and atomic group on conductivity of V2O5-doped ceria-based ceramics, Ionics, 2013, 19(9): 1291-1295.
[48] L. Wang, P. F. Yuan, F Wang, Q. Sun, E. J. Liang, Yu Jia*, Zheng-xiao Guo*, Negative Thermal Expansion correlated with Polyhedral Movement and Distortion in Orthorhombic Y2Mo3O12: A First-principles, Materials Research Bulletin. 2013, 48: 2724-2729.
[49] Lei Wang, Peng-Fei Yuan, Fei Wang, Qiang Sun, Er-Jun Liang*, Yu Jia*, Theoretical study of negative thermal expansion mechanism of ZnF2, Materials Research Bulletin. 2012: 47(5), 1113-1118.
[50] Q. J. Li, B. H. Yuan, W. B Song, E. J. Liang*, B. Yuan. Phase transition, hygroscopicity and thermal expansion properties of Yb2-xAlxMo3O12, Chin. Phys. B, 2012, 21 (4): 046501.
[51] D. C. Li, M. J. Chao*, J. M. Yu, M. Y. Li, J. J. Zhang, E. J. Liang, Enhanced density and conductivity of Ce0.82La0.18O2-δceramics for solid oxide fuel cell interlayer using V2O5 as sintering additive, Materials Letters, 2012, 86: 171-173.
[52] J. J. Zhang, M. J. Chao*, E. J. Liang, M. Y. Li, Synthesis and dielectric properties of textured SrBi2Nb2O9 ceramics via laser rapid solidification, J. Alloys & Compounds, 2012, 521: 150-154.
[53] W. G. Chen, P. F. Yuan, S. Zhang, Q. Sun, E. J. Liang, J. Yu*, Electronic properties of anatase TiO2 doped by lanthanides: A DFT plus U study, PHYSICA B-CONDENSED MATTER, 2012, 407(6): 1138-1043.
[54] H. L. Yuan, B. H. Yuan, F. Li, E. J. Liang*, Phase transition and thermal expansion properties of ZrV2-xPxO7, Acta Physica Sinica, 2012, 61(22): 226502.
[55] J. N. He, G. W. Cai, P. Ding, C. Z. Fan, E. J. Liang*, Surface plasmons coupling for local field enhancement in nanoring arrays on a metallic film, Physics Express,2012,2:10.
[56] J. Zhang, E. J. Liang*, Q. Sun, Y. Jia, Oxygen vacancy formation and migration in Sr- and Mg-doped LaGaO3: A density functional theory study, Chinese Phys. B 2012:21 (4): 047201.
[57] D. Y. Xie, Z. H. Wang, X. S. Liu, W. B. Song, B. H. Yuan, E. J. Liang*, Rapid synthesis of low thermal expansion materials of Ca1-xSrxZr4P6O24, Ceram. Int. 2012: 38(5):3807-3013.
[58] J. Q. Wang, C. Z. Fan, P. Ding, J. N. He, Y.G.Cheng, W. Q. Hu, G. W. Cai, E. J. Liang, Q. Z. Xue, Tunable broad-band perfect absorber by exciting of multiple plasmon resonances at optical frequency, OPTICS EXPRESS 2012 Vol. 20, No. 14, 14871-14878.
[59] Jinna He, Chunzhen Fan, Junqiao Wang, Yongguang Cheng, Pei Ding, Erjun Liang*, Plasmonic Nanostructure for Enhanced Light Absorption in Ultrathin Silicon Solar Cells, Advances in Opto Electronics, 2012(1), 592754.
[60] Z. Y. Li, W. B. Song, E. J. Liang*, Structures, Phase Transition, and Crystal Water of Fe2-xYxMo3O12, J. Phys. Chem. C, 2011: 115(36), 17806-17811.
[61] P. Ding, E. J. Liang, W.Q. Hu, G.W. Cai, Q. Z. Xue, Tunable plasmonic properties and giant field enhancement in asymmetric double split ring arrays, Photonics and Nanostructures - Fundamentals and Applications, 2011, 9:42-48.
[62] P. Ding, E. J. Liang, G W Cai, W Q Hu, C Z Fan, Q Z Xue, Dual-band perfect absorption and field enhancement by interaction between localized and propagating surface plasmons in optical metamaterials, J. Opt. 2011, 13: 075005.
[63] C. Z, Fan, E. J. Liang, J. P. Huang, Optical properties in the soft photonic crystals based on ferrofluids, J. Phys. D: Appl. Phys. 2011, 44: 325003.
[64] P. Ding, Q. Zhou, W. Q. Hu, G. W. Cai, E. J. Liang*,Selectable electromagnetic response modes and negative refraction in rectangular dielectric metamaterials, Acta Physica. Sinica, 2011, 60(5): 054102.
[65] Z. P. Wang, W. B. Song, Y. Zhao, Y. J. Jiang, E. J. Liang*,Raman spectroscopic study on the structure and phase transition of A2(MoO4)3 (A= Al, Cr, Fe),光散射學報,2011, 23(3):250-256.
[66] J. Zhang, E. J. Liang*, X. H. Zhang, Rapid synthesis of La0.9Sr0.1Ga0.8Mg0.2O3−δ electrolyte by a CO2 laser and its electric properties for intermediate temperature solid state oxide fuel cells, J. Power Sources, 2010: 195, 6758-6763.
[67] E.J. Liang*, Negative Thermal Expansion Materials and Their Applications: A Survey of Recent Patents, Recent Patents on Materials Science, 2010, 3(2), 106-128.
[68] S. M. Zhu, J. Q. Li, J. H. Pang, H. S. Zhang, E. J. Liang, Stability of multi-wall carbon nanotubes in air, New Carbon Mat. 2010: 25(4)308-312
[69] P. Ding, E. J. Liang*, L. Zhang, Q. Zhou, Y. X. Yuan, Antisymmetric resonant mode and negative refraction in double-ring resonators under normal-to-plane incidence, PHYSICAL REVIEW E, 2009, 79(1): 016604.
[70] Weiqin Hu; Erjun Liang*, Pei Ding, Genwang Cai, Qianzhong Xue,Surface plasmon resonance and field enhancement in #-shaped gold wires metamaterial,Optics Express, 17(24), pp 21843-21849, 2009.
[71] P. Ding, E. J. Liang*, W. Q. Hu, Q. Zhou, L. Zhang, Y. X. Yuan, Q. Z. Xue, SPP-associated dual left-handed bands and field enhancement in metal-dielectric-metal metamaterial perforated by asymmetric cross hole arrays, Optics Express, 2009; 17: 2198-2206.
[72] P. Ding, E. J. Liang*, W. Q. Hu, L. Zhang, Q. Zhou, Numerical simulations of terahertz double negative metamaterial with isotropic-like fishnet structure, Photonics and Nanostructures - Fundamentals and Applications, 2009: 7(2) 92-100.
[73] E.J. Liang*, H. L. Huo, Z. Wang, M. J. Chao, J. P. Wang, Rapid synthesis of A2(MoO4)3 (A=Y3+ and La3+ ) with a CO2 laser, Solid State Sciences, 2009:11, 139-143.
[74] C. Yuan, Y. Liang, E. J. Liang*, Terahertz time-domain spectroscopy and optical properties of AM2O8 (A=Zr, Hf and M=W, Mo), J. Quantitative Spectroscopy and Radiative Transfer, 2009:110,384-388.
[75] Y. Chao, Y. Liang, Junping Wang, E.J.Liang*, Rapid Synthesis and Raman Spectra of Negative Thermal Expansion Material Yttrium Tungstate, J. Chin. Ceram. Soc. 2009:37, 726.
[76] E. J. Liang*, H. Huo, J. Wang, M. J. Chao. Effect of water species on the phonon modes in orthorhombic Y2(MoO4)3 revealed by Raman spectroscopy, J. Phys. Chem. C, 2008:112, 6577-6581.
[77] E. J. Liang*, Yuan Liang, Yan Zhao, Jie Liu, Yijian Jiang, Low-Frequency Phonon Modes and Negative Thermal Expansion in A(MO4)2 (A = Zr, Hf and M = W, Mo) by Raman and Terahertz Time-Domain Spectroscopy, J. Phys. Chem. A, 2008:112,12582-12567.
[78] E.J. Liang*, J. P. Wang, E. M. Xu, Z. Y. Du, M. J. Chao, Synthesis of hafnium tungstate by a CO2 laser and its microstructure and Raman spectroscopic study, J. Raman Spectrosc. 2008:39, 887-892.
[79] P. Ding, E. J. Liang*, Y. Jia, Z.Y. Du, Electronic structure, bonding and phonon modes in the negative thermal expansion (NTE) materials of Cd(CN)2 and Zn(CN)2, J. Physics: Condenced matter, 2008: 20, 275224.
[80] M. J. Chao, W. L. Wang, E. J. Liang, D. X. Ouyang, Microstructure and wear resistance of TaC reinforced Ni-based coating by laser cladding, Surface & Coating Techn. 2008: 202(10), 1918-1922.
[81] D. S. Wang, E. J. Liang*, M. J. Chao, B. Yuan, Investigation on the microstructure and cracking susceptibility of laser-clad V2O5/NiCrBSiC Coatings, Surface & Coating Techn. 2008: 202(8), 1371-1378.
[82] E.J. Liang*, T. A. Wu, B. Yuan, M.J. Chao,W. F. Zhang, Synthesis, microstructure and phase control of zirconium tungstate with a CO2 laser, J. of Physics D:Applied Physics, 2007:40, 3219-3223.
[83] E.J. Liang*, S. H. Wang, T. A. Wu, M.J. Chao, B. Yuan, W. F. Zhang, Raman spectroscopic study on structure, phase transition and restoration of zirconium tungstate blocks synthesized with a CO2 laser, J. Raman Spectrosc. 2007:38, 1186-1192.
[84] M. J. Chao, X. Niu, B. Yuan, E. J. Liang, D. S. Wang, Preparation and characterization of in situ synthesized B4C particulate reinforced nickel composite coatings by laser cladding, SURFACE & COATINGS TECHNOLOGY, 2006: 201(3-4), 1102-1108.
[85] P. Ding, E. J. Liang*, M. J. Chao, X. Y. Guo, J. W. Zhang, Synthesis, Characterization and Low Field Emission of CNx Nanotubes, PHYSICA E-LOW-DIMENSIONAL SYSTEMS & NANOSTRUCTURES, 2005: 25(4), 654-659.
[87] E. J. Liang*, P. Ding, H. R. Zhang, X. Y, Guo, Z. L. Du, Synthesis and correlation study on the morphology and Raman spectra of CNx Nanotubes by thermal decomposition of ferrocene/ethylenediamine, DIAMOND AND RELATED MATERIALS, 2004: 13(1), 69-73.
[88] M. J. Chao, E. J. Liang*, Effect of TiO2-doping on the microstructure and the wear properties of laser-clad nickel-based coatings, SURFACE & COATINGS TECHNOLOGY, 2004:179(2-3), 265-271.
[89] E. J. Liang, J. W. Zhang, J. Leme, C. Moura, L. Cunha, Raman analysis of Si-C-N films grown by reactive sputtering, THIN SOLID FILMS, 2004: 469, 410-415.
[90] J. X. Ma, Y. Jia, Y. L. Song, E. J. Liang, L. K. Wu, F. Wang, X. C. Wang, X. Hu, The geometric and electronic properties of the PbS, PbSe and PbTe (001) surfaces, SURFACE SCIENCE, 2004: 551(1-2), 91-98.
[91] E. J. Liang, Y. H. Yang, W. Kiefer, Surface-enhanced Raman spectra of fulvic and humic acids adsorbed on copper electrodes, Spectroscopic Letters,1999:32(4),689-701.
[92] B. H. Loo, Y. G. Lee, E. J. Liang, W. Kiefer, Surface-enhanced Raman scattering from ferrocyanide and ferricyanide ions adsorbed on silver and copper colloids, CHEMICAL PHYSICS LETTERS, 1998: 297(1-2), 83-89.
[93] J. M. Hu, E. J. Liang, F. Duschek, W. Kiefer, Resonance Raman spectroscopic study of free brilirubin and brilirubin complexes with copper(Ⅱ),silver(Ⅰ)and gold(Ⅲ), Spectrochimica Acta,Part A, 1997: 53(9),1431-1438.
[94] E. J. Liang, X. L. Ye, W. Kiefer, Surface-enhanced Raman spectroscopy of crystal violet in the presence of halide and halite ions with near-infrared wavelength excitation, JOURNAL OF PHYSICAL CHEMISTRY A, 1997: 101(40), 7330-7335.
[95] E. J. Liang, X. L. Ye, W. Kiefer, Interaction of halide and halite ions with colloidal silver and their influence on surface-enhanced Raman scattering of pyridine with near-infrared excitation, Vibrational Spectroscopy, 1997, 15(1)69-78.
[96] E. J. Liang, Y. H. Yang, W. Kiefer, Surface-enhanced Raman spectroscopy of fulvic and humic substances on silver nitrate modified Fe-C-Cr-Ni surface, J. Environmental Sci.& Health, A, 1996, 31(10):2477-2486.
[97] E. J. Liang, W. Kiefer, Chemical effect of SERS with near-infrared excitation, JOURNAL OF RAMAN SPECTROSCOPY, 1996, 27(12): 879-885.
[98] E.J. Liang, C. Engert, W. Kiefer, Surface-enhanced Raman scattering of halide ions, pyridine and crystal violet on colloidal silver with near-infrared excitation: low wavenumber vibrational modes,Vibrational Spectroscopy, 1995, 8(3):435-444.
[99] E. J. Liang, A Weippert,J. M. Funk,A. Materny,W. Kiefer, Experimental observation of surface-enhanced coherent anti-Stokes Raman scattering, Chem. Phys. Lett. 1994, 227, (1-2):115-120.
[100] E. J. Liang, D. Göttges, W. Kiefer, Surface enhanced resonance Raman spectroscopy of flavins on silver nitrate-modified Cu and Fe as well as Cu-Zn-Pb and Fe-C-Cr-Ni surfaces, Appl. Spectrosc. 1994, 48(9):1088-1094.
[101] E. J. Liang, C. Engert, W. Kiefer, Surface-enhanced Raman scattering of pyridine in silver colloids excited in the near-infrared region, JOURNAL OF RAMAN SPECTROSCOPY, 1993, 24(11): 775-779.
[102] E. J. Liang, C. Engert, W. Kiefer, Surface-enhanced Raman spectroscopy of p-aminobenzoic acid with excitation in the visible and near-infrared spectral region, Vibrational spectroscopy, 1993, 6(1):79-85.

出版專著

E.J.Liang,J.Zhang,M.J.Chao,SynthesisofNovelMaterialsbyLaserRapidSolidification,Chapter15,pp.313-320,inHeatAnalysisandThermodynamicEffects,EdditedbyAmimulAhsan.Intech2011.

專利

[1]梁二軍,宋文博,劉獻省,饒鳳飛.一種負膨脹陶瓷ZrMgMo3O12的燒結合成方法(發明專利:ZL201110442763.8),授權日期:2014.02.
[2]梁二軍,劉獻省,成福興.一種熱膨脹係數可控的金屬基陶瓷材料Al-Zr2P2WO12的燒結合成方法(發明專利:ZL201110283736.0),授權日期:2013.01.
[3]梁二軍,胡慶倫,商瑞.一種負熱膨脹材料Zr2P2MO12的燒結合成方法(發明專利:ZL201010204460.8),授權日期:2012.07.
[4]梁二軍,袁斌,周鴻穎.負熱膨脹係數材料快速燒結合成方法,中國,(發明專利:ZL200610160031.9),授權日期:2009.10.
[5]梁二軍,王東升,晁明舉,袁斌,阮宜斌,吳天安.負熱膨脹係數材料雷射合成方法(發明專利:ZL200610107023.8),授權日期:2009.06.
[6]梁二軍,周鴻穎.負熱膨脹係數材料鎢酸鋯的合成方法(發明專利:ZL200610107012.X)授權日期:2008.10.
[7]梁二軍,胡偉琴丁佩,一種#字形納米電磁超介質表面增強拉曼散射襯底(發明專利:ZL200910066222.2),授權日期:2011.01.02.
[8]梁二軍,丁佩胡偉琴,一種不對稱雙劈裂環表面增強光譜襯底(發明專利:ZL200910066224.1),授權日期:2011.01.12.
[9]張鵬翔,梁二軍,祖恩東,郭洪,一種寶石礦物的拉曼識別法(發明專利:ZL01108444.8),授權日期:2004.03

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