[1] [1] W. S. Sheldrick, M. Wachhold. Chalcogenido metalates of the Heavier Group 14 and 15 elements[J]. Coordination Chemistry Reviews, 1998, 176(1): 211~322

[2] [2] W. S. Sheldrick, M. Wachhold. Solvothermal synthesis of solid-state chalcogenido metalates[J]. Angew Chem. Int. Ed, 1997, 36(3): 206~224

[3] [3] M. G. Kanatzidis. Molten alkali-metal polychalcogenides as reagents and solvents for the aynthesis of new chalcogenide materials[J]. Chem Mater, 1990, 2(4): 353~363

[4] [4] J. B. Parise, Y. Ko. Materials consisting of two interwoven4-connected networks: Hydrothermal synthesis and structure of [Sn5S9O2] [HN(CH3)3]2[J]. Chem. Mater., 1994, 6(6): 718~720

[5] [5] E. Makovicky. Crystal structures of sulfides and other chaleogenides[J]. Sulfide Mineralolgy and Geochemistry, 2006, 61(1): 7~125

[6] [6] K. Mitchell, J. A. Ibers. Rare-earth transition-metal chaleogenides[J]. Chem. Rev., 2002, 102(6): 1929~1952

[7] [7] U. Chandra, G. Parthasarathy, P. Sharma. Synthetic cubanite CuFe2S3: pressure-induced transformation to isocubanite[J]. Canadian Mineralogist, 2010, 48(5): 1137~1147

[8] [8] P. Vaqueiro, I. Szkoda, R. D. Sanze et al.. Ternary erbium chromium sulfides: structural relationships magnetic properties[J]. Inorganic Chemistry, 2009, 48(4): 1284~1292

[9] [9] M. Kockerling, E. Canadell. Electronic structures of M21S8 (M=Nb,Zr) and (M,M′)21S8(M,M′=Hf,Ti; Nb,Ta) phases and reasons for variations in the rental site occupations[J]. Inorganic Chemistry, 2000, 39(26): 6145~6145

[10] [10] S. Nagat, T. Atake. Survey of chalcogenide supereonduetors[J]. J. Thermal Analysis and Calorimetry, 1999, 57(3): 807~821

[11] [11] G. Ferey. Supertetrahedra in sulfides: matter against mathematical series[J]. Angew Chem. Int. Ed., 2003, 42(23): 2576～2579

[12] [12] N. Zheng, X. Bu, B. Wang et al.. Microporous and photoluminescent chalcogenide zeolite analogs[J]. Seience, 2002, 298(5602): 2366～2369

[13] [13] Bai Xuefeng, Shan Wenyan. Preparation and application of multi-metal sulfide photocatalysts[J]. Chemistry and Adhesion, 2009, 31(5): 35~38

[14] [14] Xu Lei, Xia Haiping, Hu Minjie. Nano-copper sulfide for absorbing near infrared light[J]. Acta Optica Sinica, 2013, 33(1): 0116001

[15] [15] Zhang Yongcai, Hu Xiaoya, Qiao Tao. Shape controlled synthesis of CuS nanaocrystallites via facile hydrothermal route[J]. Solid State Commun., 2004, 132: 779~782

[16] [16] Ga Lei, Wang Enbo, Lian Suoyuan et al.. Microemulsion-dircted synthesis of different CuS nanocrystals[J]. Solid State Commun., 2004, 130: 309~312

[17] [17] X. H. Zhang, D. W. Jing, M. C. Liu et al.. Efficient photocatalytic H2 production under visible light irradiation over Ni doped Cd1-xZnxS microsphere photocatalysts[J]. Catal Commun, 2008, 9(8): 1720~1724

[18] [18] C. J. Xing, Y. J. Zhang, W. Yan et al.. Band structure-controlled solution of Cd1-xZnxS photocatalyst for hydrogen production by water splitting[J]. Int. J. hydrogen Energy, 2006, 31(14): 2018~2024

[19] [19] A. R. Loukanov, C. D. Dushkin, P. I. Papazova et al.. Photoluminesence depending on the ZnS shell thiekness of CdS/ZnS core-shell semiconductor nanoparticles[J]. Colloids and Surfaces A: Physico chemical and Engineering Aspects, 2004, 245: 9~14

[20] [20] Qiu Yang, Xia Haiping. Preparation of nano-hydroxyapatite by novel ultrasonic atomization precipitation method[J]. Journal Material Engineering, 2008, 10: 324～327

[21] [21] Hu Yuan, Xia Haiping, Zhang Li. Emission properties of eu-doped nano-Lu3Al5O12 powders by ultrasonic atomization and co-precipitation method[J]. Acta Photonica Sinica, 2011, 40(11): 1646~1651

[22] [22] Yu Zhaonian. Anti-corrosion Coating and Coating[M]. Beijing: Chemical Industry Press, 2002. 190～202

[23] [23] Yao Chen, Zhao Shilin, Miu Guoyuan. Characteristics of transparent heat insulation nanocomposite coatings and its application[J]. Pant & Coatings Ind., 2007, 37(1): 29～32