α(shape), birth of one universal parameter?

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NETL
NSTL
Trans Tech Publications Ltd

外文摘要：The description of different effects observed in nature by only one general equation is the "Holy Grail" for all physicists. This goal has been achieved for characteristic temperatures through a top-down approach (studying size effects from macroscopic laws) and is presented in this chapter. Here, we show the general equation based on the surface area to volume ratio of nanostructures and statistics (Fermi-Dirac or Bose-Einstein) followed by the particles involved in the investigated phenomena. From the distinction between fermions and bosons, so-called particles which follow a Fermi-Dirac or a Bose-Einstein statistics respectively, this equation indicates the universal behaviour of size and shape effects on different material properties like melting, ferromagnetism, vibration and superconduction. The same shape parameter used in this universal equation can be used to determine the melting enthalpy, the phase diagrams of alloys, the energy bandgap and also the creep behavior of nanomaterials. Theoretical predictions show satisfactory agreement with experimental data taken from literature.

外文关键词：

size effectshape effectmelting temperaturephase diagramsegregationmelting enthalpyenergy bandgapDebye temperatureCurie temperaturesuperconductive temperaturediffusioncreepactivation energyThornton & Hoffman's criterionresidual stressnanomaterialnanostructurenanoparticlenanowirenanofilm

作者：

GUISBIERS Gregory

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作者单位：

UCL, Institute of Mechanics, Materials and Civil Engineering, 2 Place Sainte Barbe, 1348 Louvain-La-Neuve, Belgium

出版年：

2010

DOI：

10.4028/www.scientific.net/KEM.444.69

Key engineering materials

ISSN：1013-9826

年,卷(期)：2010.444

参考文献量36