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随着碳富勒烯和碳纳米管的发现,具有类似层状结构的纳米颗粒MoS2,由于片层状平面结构的不稳定,易形成封闭多面体笼状结构和管状结构.综述了过渡族金属硫化物MS2(M=W,Mo,Nb,Ta,Zr,Ti,Re,Hf)纳米管的合成方法、微观结构、生长机制及其潜在的性能和应用.

参考文献

[1] Kroto H W;Heath J R;Brien S C O et al.C60:Buckministerfullerene[J].Nature,1985,318:162.
[2] Iijima S .Helical microtubes of graphitic carbon[J].Nature,1991,354:56.
[3] Tenne R;Margulis L;Genut M et al.Polyhedral and cylindrical structures of WS2[J].Nature,1992,360:444.
[4] Zak A;feldman Y;lyakhovi V et al.Artificial lamellar mesostructrues to WS2 nanotubes[J].Journal of the American Chemical Society,2002,124(17):4747.
[5] Rosen Y;Feld Hacohen Y;Grunbaum E;Tenne R et al.Synthesis of individual single-walled carbon nanotubes on patterned silicon wafers[J].Nature,1998,395:336.
[6] Kasuga T.;Hoson A.;Sekino T.;Niihara K.;Hiramatsu M. .Formation of titanium oxide nanotube[J].Langmuir: The ACS Journal of Surfaces and Colloids,1998(12):3160-3163.
[7] Manashi Nath;C.N.Rao .MoSe_2 and WSe_2 nanotubes and related structures[J].Chemical communications,2001(21):2236-2237.
[8] Zhang M;Bando Y;Wada K .Silicon dioxide nanotubes prepated by anodic alumina as templates[J].Journal of Materials Research,2000,15(01):387.
[9] Rapoport L;Vovsky M L;Tenne R .Friction and wear of bronze power composites including fullerene-like WS2 nanoparticles[J].Wear,2001,24(01):149.
[10] Margulis L;Salitra G;Tenne R et al.Nested fullerene-like structures[J].Nature,1993,365:113.
[11] Feldman Y;Wasserman E;Srolovitz DJ;Tenne R .HIGH-RATE, GAS-PHASE GROWTH OF MOS2 NESTED INORGANIC FULLERENES AND NANOTUBES[J].Science,1995(5195):222-225.
[12] Nath M.;Rao CNR.;Govindaraj A. .Simple synthesis of MoS2 and WS2 nanotubes[J].Advanced Materials,2001(4):283-286.
[13] Remskar M;Mrzel A;Skraba Z et al.Metal-alloyed NbS2 nanotubes synthesized by the self-assem of nanoparticles[J].Science,2001,292:479.
[14] Nath M;Rao C N R .New metal disulfide nanotubes[J].American Chemical Society,2001,123:4841.
[15] Nath M.;Rao CNR. .Nanotubes of the disulfides of groups 4 and 5 metals[J].Pure and Applied Chemistry,2002(9):1545-1552.
[16] Chen J;Tao Z L;Li S L .Advances in the synthesis of inorganic nanotubes and fullerene-like nanoparticles Angew[J].Angewandte Chemie International Edition,2003,42:2147.
[17] Chen J;Li S L;Tao Z L et al.Titanium disulfide nanotubes as hydrogen-storage materials[J].American Chemical Society,2003,125:5284.
[18] Jun Chen;Suo-Long Li;Zhang-Liang Tao;Feng Gao .Low-temperature synthesis of titanium disulfide nanotubes[J].Chemical communications,2003(8):980-981.
[19] Coleman K S;Sloan J;Hanson N A et al.The formation of ReS2 inorganic fullerene-like structures containing Re4 parallelogram units and metal-metal bonds[J].American Chemical Society,2002,124:11580.
[20] Brorson M;Hansen T W;Jacobsen C J H .Rhenium(Ⅳ)sulfide nanotubes[J].American Chemical Society,2002,124:11582.
[21] Reshef Tenne .Inorganic Nanotubes and Fullerene-Like Materials[J].Chemistry: A European journal,2002(23):5297-5304.
[22] Benavente E;Santa Ana M A;Mendixabal F et al.Intercalation chemistry of molybdenum disulfide[J].Coordination Chemistry Reviews,2002,22(01):87.
[23] 袁求理,聂秋林,李国华.过渡金属硫化物类富勒烯的研究[J].杭州电子工业学院学报,2004(01):20-24.
[24] Feldman Y;Frey GL;Homyonfer M;Lyakhovitskaya V;Margulis L;Cohen .BULK SYNTHESIS OF INORGANIC FULLERENE-LIKE MS(2) (M=MO, W) FROM THE RESPECTIVE TRIOXIDES AND THE REACTION MECHANISM[J].Journal of the American Chemical Society,1996(23):5362-5367.
[25] Liao HW.;Zhang SY.;Qian YT.;Wang YF. .A solution low-temperature route to MoS2 fiber[J].Chemistry of Materials,2001(1):6-8.
[26] Rapoport L.;Homyonfer M.;Cohen H.;Sloan J.;Hutchison J.L.;Tenne R.;Feldman Y. .Inorganic fullerene-like material as additives to lubricants: Structure-function relationship[J].Wear: an International Journal on the Science and Technology of Friction, Lubrication and Wear,1999(2):975-982.
[27] Chhowalla M;Amaratunga G A J .Thin films of fullerenelike MoS2 nanoparticles with ultra-low friction and wear[J].NATURE,2000,407:164.
[28] Li C S;Yan K H.[A].,2004
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