Surface energy for nanowire

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Annals of Mathematics and Physics volume5-issue2 articles
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Submitted: March 11, 2022
Published: Jul 8, 2022
DOI: 10.17352/amp.000043
Keywords:
Gibbs–Tolman–Koenig–Buff theory, Tolman length, Van der Waals theory

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Serghei A Baranov*
Institute of Applied Physics, str. Academiei 5, Chisinau, MD-2028, Republic of Moldova

Abstract

The theory of surface phenomena in the production of micro-and nanocylinder for important cases is considered. Analytical solution to Gibbs–Tolman–Koenig–Buff equation for nanowire surface is given. Analytical solutions to equations for case the cylindrical surface for the linear and nonlinear Van der Waals theory are analyzed. But for a nonlinear theory, this correspondence is absent.

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Article Details

Baranov, S. A. (2022). Surface energy for nanowire. Annals of Mathematics and Physics, 5(2), 081–085. https://doi.org/10.17352/amp.000043
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Copyright (c) 2022 Baranov SA.

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Baranov SA, Larin VS, Torcunov AV. Technology, Preparation and Properties of the Cast Glass-Coated Magnetic Microwires. Crystals. 7: 136.

Ono S, Kondo S. Molecular Theory of Surface Tension in Liquids, in Structure of Liquids, series Encyclopedia of Physics, Springer, Berlin, Heidelberg. 1960; 3/10: 134–280.

Rowlinson JS, Widom B. Molecular Theory of Capillarity, Oxford University Press, Oxford, 1989.

Jaycock MJ, Parfitt GD. Chemistry of Interfaces, Halstead Press, John Wiley & Sons, New York, 1981.

Rusanov AI, Prokhorov VA. Interfacial Tensiometry, Elsevier. Amsterdam. 1996.

Tolman RCJ. The Effect of Droplet Size on Surface Tension. Chem Phys. 1949; 17 (3): 333.

Rekhviashvili SSh, Kishtikova EV. Tech Phys. 2011; 56(1): 143.

Rekhviashvili SSh. Colloid J. (2020); 82(3): 342.

Sokurov AA, Vestnik Kraunc, Ser. Fiz.-Mat. Nauk. 2018; 23(3): 140.

Rekhviashvili SSh, Sokurov AA. Turk J Phys. 2018; 42: 699.

Rekhviashvili SSh. Razmernye iavlenia v fizike kondensirovannogo sostoianiia I nanotehnologiah. Nalchik 2014; 250.

Bykov TV, Zeng XC. J Chem Phys. 2001; 105 (47): 11586.

Bykov TV, Shchekin AK. Inorg Mater. (Transl of Neorg Mater). 1999; 35: 641.

Hadjiagapiou IA. J Phys: Condens Matter. 1995; 7: 547.

Kalikmanov VI. J Chem Phys. 2004; 121: 8916.

Schmelzer JWP, Ropke G, Priezzhev VB. Nucleation Theory and Applications, JINR Publishing House, Dubna. 1999.

Schmelzer JWP, Baidakov VG, Boltachev GSh. J Chem Phys. 2003;119: 6166.

Baidakov VG, Boltachev GSh. Phys Rev 1997; E 59(1): 5648.

Baidakov VG, Boltachev GSh. Phys Rev E. 1999; 59: 469.

Baidakov VG, Protsenko SP, Chernykh GG, Boltachev GSh. Phys Rev E. 2002; 65: 047601.

Vov PEL, Svetukhin VV. Phys Stat Sol. 2015; 57: 1213.

Baranov SA. In Handbook of Nanoelectrochemistry: Electrochemical Synthesis Methods, Properties and Characterization Techniques, Springer, International Publishing, Switzerland. 2015; 1057–1069.

Baranov SA, Rekhviashvili SSh, Sokurov AA. Surf Eng Appl Electrochem. 2019; 55(3): 286.

Baranov SA. Surf Eng Appl Electrochem. 53(2): 124.

Baranov SA. Mold J Phys Sci. 2020; 19(1–2): 182.

Baranov SA. Mold J Phys Sci. 2021; 20(1–2):44.

Baranov SA. J Anal Tech Res. 2021; 3(2): 28.

Baranov SA. J Anal Tech Res. 2021; 3(2): 39.