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Metal oxide nanostructures (CuO, Co3O4, ZnO and α-Fe2O3) have been successfully fabricated by a simple and efficient method: heating the appropriate metals in air at low temperatures ranging from 200 to 400℃. The chemical composition, morphology and crystallinity of the nanostructures have been characterized by micro-Raman spectroscopy, X-ray diffraction, scanning electron microscopy and transmission electron microscopy. Two mechanisms: vapor-solid and surface diffusion play dominant roles in the growth of metal oxide nanostructures starting with low melting point metals (Zn and Cu) and high melting point metals (Fe and Co), respectively. With sharp ends and large aspect ratio, the metal oxide nanostructures exhibit impressive field-induced electron emission properties, indicating their potentials as future electron source and displays. The water wettability and anti-wettability properties of iron oxide nanoflakes were also discussed in this work.

参考文献

[1] T.Grygar;P.Bezdicka;A.Domenech-Carbo;F.Marken L.Pikna G.Cepria .[J].Analyst,2002,127(08):1100.
[2] N.Mimura;I.Takahara;M.Saito;T.Hattori K.Ohkuma M.Ando .[J].Catalysis Today,1998,45:61.
[3] A.P.Caricato;Y.V.Kudryavtsev;G.Leggieri;A.Luches and S.A.Mulenko .[J].Journal of Physics D:Applied Physics,2007,40(16):4866.
[4] K.Hayashi;K.Iwasaki;H.Morii;B.Xia and K.Okuyama .[J].Journal of Nanoparticle Research,2001,3(2-3):149.
[5] C. V. Gopal Reddy;K. Kalyana Seela;S. V. Manorama .Preparation of γ-Fe_2O_3 by the hydrazine method Application as an alcohol sensor[J].International journal of inorganic materials,2000(4):301-307.
[6] Y.Y.Fu;J.Chen;H.Zhang .[J].Chemical Physics Letters,2001,350:491.
[7] Y.Y.Fu;R.M.Wang;J.Xu;J.Chen Y.Yan A.V.Narlikar H.Zhang .[J].Chemical Physics Letters,2003,379:373.
[8] Y.Y.Xu;X.F.Rui;Y.Y.Fu;H.Zhang .[J].Chemical Physics Letters,2005,410:36.
[9] X.G.Wen;S.H.Wang;Y.Ding;Z.L.Wang S.H.Yang .[J].Journal of Physical Chemistry B,2005,109(01):215.
[10] Y.L.Chueh;M.W.Lai;J.Q.Liang;L.J.Chou Z.L.Wang .[J].Advanced Functional Materials,2006,16(17):2243.
[11] C.H.Kim;H.J.Chun;D.S.Kim;S.Y.Kim J.Park J.Y.Moon G.Lee J.Yoon Y.Jo M.H.Jung S.I.Jung and C.J.Lee .[J].Applied Physics Letters,2006,89(22):223103.
[12] H.Srivastava;P.Tiwari;A.K.Srivastava;R.V.Nandedkax .[J].Journal of Applied Physics,2007,102(05):051303.
[13] U.P.Deshpande;T.Shripathi;D.Jain;A.V.Narlikar S.K.Deshpande Y.Y.Fu .[J].Journal of Applied Physics,2007,101(06):064304.
[14] Q.Han;Y.Y.Xu;Y.Y.Fu;H.Zhang R.M.Wang T.M.Wang Z.Y.Chen .[J].Chemical Physics Letters,2007,431(1-3):100.
[15] Q.Han;Z.H.Liu;Y.Y.Xu;Z.Y.Chen T.M.Wang H.Zhang .[J].Journal of Physical Chemistry C,2007,111(13):5034.
[16] T. I. Kamins;X. Li;R. Stanley Williams .Thermal stability of Ti-catalyzed Si nanowires[J].Applied physics letters,2003(2):263-265.
[17] C.X.Kan;G.H.Fu;W.P.Cai;C.C.Li;L.D.Zhang .Synthesis and thermal stability of gold nanowires within monolithic mesoporous silica[J].Applied physics, A. Materials science & processing,2004(8):1187-1191.
[18] A.L.Pan;S.Q.Wang;R.B.Liu;C.R.Li B.S.Zou .[J].Small,2005,1(11):1058.
[19] B.J.Inkson;G.Dehm;T.Wagner .[J].Journal of Microcirculation,2004,214:252.
[20] R.Zboril .[J].Chemistry of Materials,2004,14:969.
[21] D.L.A.deFaria;S.V.Silva;M.T.deOliveira .[J].Journal of Raman Spectroscopy,1997,28(11):873.
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