Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-27T01:08:46.280Z Has data issue: false hasContentIssue false

The Physical Essence of Mono-dispersed Nanometer Particle Surface Energy by Boundary bond Interaction

Published online by Cambridge University Press:  10 April 2013

Lihong Su*
Affiliation:
Depart. of applying chemistry, Northwestern Polytechnical University, Xi’an, China, 710072
Xiaowei Yin
Affiliation:
Science and Technology on Thermostructure Composite Materials Laboratory, Northwestern Polytechnical University, Xi’an, China, 710072
Caixia Wan
Affiliation:
Depart. of applying chemistry, Northwestern Polytechnical University, Xi’an, China, 710072
Shengru Qiao
Affiliation:
Science and Technology on Thermostructure Composite Materials Laboratory, Northwestern Polytechnical University, Xi’an, China, 710072
*
*Corresponding Author: Lihong.Su, Email: [email protected]
Get access

Abstract

The surface energy quantifies the disruption of intermolecular bond that occurs when a surface is created. The paper discusses critical size dc of mono-dispersed nanometer particle by analyzing the change of interfacial surface energy. The traditional theory neglects that the mono-dispersed nanometer particle has quantum standing wave in its internal structure with a size below critical dc. During the preparation of mono-dispersed nanometer powder, the large surface energy is formed ont only by cutting surface bond but also by forming quantum standing wave that opposites to interfacial edge unsaturated bond on the nanometer partcile surface atom. The preparation process of nanometer material needs more energy than the size surpass dc material. The new theory can explain why the melting point of nanometer powder decreases and other phenomina of nanometer material.

Type
Articles
Copyright
Copyright © Materials Research Society 2013

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Pauling, Linus, The principles determining the structure of complex ionic crystal. J. AM. Chem.Soc, 1929, 51(4) 10101026 CrossRefGoogle Scholar
Su, Lihong. Symmetrical Appearance of nanometer material related to the surface bond quantum tunneling[OL].http://www.paperp.edu.cn, 2011,10 Google Scholar
Greenwood, NN, Earnshaw, A. Chemistry of the elements [M]. Butterworth-Heineman Ltd.1984 Google Scholar
Mullins, W. J.Appl Phys, 1956,27:900 CrossRefGoogle Scholar
Shankar, R. Principle of Quantum Mechanics[M], Second edition, 2007.Google Scholar
Oxtoby, DW. Chemistry: Science of Change[M].second edition. Saunders College Publishing, 1994 Google Scholar
Guang, WJ.Sun, R. Tao, J. Coordination-dependant surface atomic contraction in nanocrystal revealed by coherent diffraction. Nature material, 2008,7,308313 Google Scholar
Su, Lihong., et al. .Co3O4 mono-dispersed nanometer particles solubility in high-purity water[J]. MicrO & Nano Letter, 2009,4:4852 Google Scholar
Pospiech, J., Wiencek, K., Morawiec, A. et al. .The grain boundary contrasting by crystallographic orintation differences method[J]. Praktische Metallographie. 2002,39:126139 Google Scholar
Rafel, Tadmor Line energy and the relation between advancing receding and Young contact angles. Langmuir, 2004, 20:76597662 Google Scholar
Morawiec A.cta Material. Method to calculate the grain boundary energy distribution over the space of macroscopic boundary parameters from the geometry of triple junctions[J]. Acta Material, 2000,48, 3525–3532 CrossRefGoogle Scholar
Nakada, Kyoko, et al. . Edge state in graphene ribbons: Nnaometer size effect and edge shape dependence [J]. Phys.Rev. 1996, B54, 1795417961 CrossRefGoogle Scholar
Roseenhain, W, Ewen, D. J Inst Met, 1912,8:149152 Google Scholar
Wood ruff, DP. et al. . The Chemical Physics of solid surfaces[J]. 2002,10:120123 Google Scholar
Nomura K.Macdonald AH. Quantum transport of massless Dirac-Fermions in graphene http://arxiv.org/abs/cond-mat/0606589, 2006 CrossRefGoogle Scholar
Ziegler, K. Delocalization of 2D Dirac Fermins: the role of a broken symmetry[J]. Phys.Rev.Lett. 1998, 80:31133116 CrossRefGoogle Scholar
Liu, X-D, Fedkiw, RP, Kang, M. A boundary condition capturing method for Poisson’s equation on irregular domains. Journal of Computational Physics 2000; 160:151178.CrossRefGoogle Scholar
Planck, M. The Theory of Heat radiation. Blakiston Philadelphia. 1914.Google Scholar
Jura, George, Pitzer, Kenneth S.. The Specific Heat of Small Particles at Low Temperatures. J. Am. Chem. Soc., 1952, 74 (23), pp 60306032 CrossRefGoogle Scholar
Novotny, V..Meincke, P. P. M..Watson, J. H. P. Effect of Size and Surface on the Specific Heat of Small Lead Particles. Phys. Rev. Lett. 28, 901903 (1972)CrossRefGoogle Scholar
Comsa, G.H., Heitkamp, D., Räde, H.S.. Effect of size on the vibrational specific heat of ultrafine palladium particles. Solid State Communications Volume 24, Issue 8, November 1977, Pages 547550 CrossRefGoogle Scholar
Zhang, Hengzhong, Banfield, Jillian F.. A model for exploring particle size and temperature dependence of excess heat capacities of nanocrystalline substances Nanostructured Materials Volume 10, Issue 2, February 1998, Pages 185194 Google Scholar
Zallen, R (1983) The Physics of Amorphous Solids (New York: Wiley Interscience) pp. 20.CrossRefGoogle Scholar