[1] SUN Chen, LI Chuan-hao, SHI Rui-ying, et al. A study of influences of metal nanoparticles on absorbing efficiency of organic cells［J］. Acta Photonica sinica, 2012, 41(11): 1335-1341.

[2] SUN G, KHURGIN J B. Origin of giant difference between fluorescence, resonance, and nonresonance Raman scattering enhancement by surface plasmons［J］. Physical Review A , 2012, 85(6): 0634101-0634108

[3] ATWATER H A, POLMAN A. Plasmonics for improved photovoltaic devices［J］.Natrue Materials, 2010, 9(3): 205-213.

[4] ALEXANDRE A, LEI D Y. Plasmonic light-harvesting devices over the whole visible spectrum［J］. Nano Letter, 2010, 10(7): 2574-2579.

[5] TUERSUN P, HAN X E.Optimal design of gold nanoshells for optical imaging and photothermal therapy［J］. Optik, 2014, 125(14): 3702-3706.

[6] CAI Ceng, HUANG Zhu-qing, CAO Xiao-ling, et al. Application of laser backscattering method in wet steam measurement［J］. Laser Technology, 2014, 38(3): 398-401.

[7] GOVYADINOV A A, PANASYUK G Y, SCHOTLAND J C, et al. Theoretical and numerical investigation of the size-dependent optical effects in metal nanoparticles［J］. Physical Review B, 2011, 84(15): 155461 1-12.

[8] YANG Yi-feng, YANG Hui, ZHENG Gang, et al. Backscattering spectroscopy for sizing shperical sub-micron paticales［J］. Acta Photonica Sinica, 2011, 40(11): 1652-1656.

[9] GUO Yong-cai, ZHANG Xiao-ming. Modeling and simulation of light scattering information of blood cell in fluid flow［J］. Laser Technology, 2013, 37(4): 487-492.

[10] BANSAL A, SEKHON J S, VERMA S S. Scattering efficiency and LSPR tunability of bimetallic Ag,Au, and Cu nanoparticles［J］. Plasmonics, 2014, 9(1): 143-150 .

[11] ZHOU J, LU Z, ZHU X, et al. NIR photothermal therapy using polyaniline nanoparticles［J］. Biomaterials, 2013, 34(37): 9584-9592.

[12] KIRUI D K, KRISHNAN S, STRICKLAND A D, et al. PAA-derived gold nanorods for cellular targeting and photothermal therapy［J］. Macromolecular Bioscience, 2011, 11(6): 779-88.

[13] LI J L, GU M. Gold-nanoparticle-enhanced cancer photothermal therapy［J］. IEEE Journal of Selected Topics in Quantum Electronics, 2010, 16(4): 989-996.

[14] BOHREN C F, HUFFMAN D R. Absorption and scattering of light by small particles［M］. Wiley, 1983.

[15] MOROZ A. Electron mean-free path in metal-coated nanowires［J］. Journal of the Optical Society of America B, 2011, 28(5): 1130-1138.

[16] CORONADO E A, SCHATZ G C. Surface plasmon broadening for arbitrary shape nanoparticles: A geometrical probability approach［J］. Journal of Chemical Physics, 2003, 119(7): 3926-3934.

[17] YESHCHENKO O A, BONDARCHUK I S, GURIN V S, et al. Temperature dependence of the surface plasmon resonance in gold nanoparticles［J］. Surface Science, 2013, 608(5): 275-281.

[18] YESHCHENKO O A. Temperature effects on the surface plasmon resonance in copper nanoparticles［J］. Ukrainian Journal of Physics, 2013, 58(3): 251.

[19] YESHCHENKO O A, DMITRUK I M, ALEXEENKO A A, et al. Size and temperature effects on the surface plasmon resonance in silver nanoparticles［J］. Plasmonics, 2012, 7(3): 685-694.

[20] KITTEL C. Introduction to solid state physics［M］.Willey, New York, 2005.

[21] RAKIC A D, DJURISIC A B, ELAZAR J M, et al. Optical properties of metallic films for vertical-cavity optoelectronic devices［J］. Applied Optics, 1998, 37(22): 5271-5283.

[22] ASHCROFT N W, MERMIN N D . Solid state physics［M］. Orlando: Harcourt, 1976.

[23] CHEN Y J, LEE M C, WANG C M. Dielectric function dependence on temperature for Au and Ag［J］. Japanese Journal of Applied Physics, 2014, 53(8S2): 1-3.

[24] JOHNSON P B. Optical constants of the noble metals［J］. Physical Review B, 1972, 6(12): 4370-4379.

[25] THORMHLEN I, STRAUB J, GRIGULL U. Refractive index of water and its dependence on wavelength, temperature, and density［J］. Journal of Physical & Chemical Reference Data, 1985, 14(4): 933-945.