Effects of Nonparabolicity on Electron Thermopower of Size-Quantized Semiconductor Films

doi:10.1088/0256-307X/32/7/077204

Chin. Phys. Lett.

2015, Vol. 32

Issue (07): 077204 DOI: 10.1088/0256-307X/32/7/077204

CONDENSED MATTER: ELECTRONIC STRUCTURE, ELECTRICAL, MAGNETIC, AND OPTICAL PROPERTIES

Effects of Nonparabolicity on Electron Thermopower of Size-Quantized Semiconductor Films

BAHSHELI Guliyev¹, AKBAR Barati Chiyaneh^2**, NOVRUZ Bashirov³, GENBER Kerimli⁴

¹Baku State University, Department of Physics, Baku, Azerbaijan
²Yüzüncü Y?l University, Department of Mathematics, Van 65080, Turkey
³Yüzüncü Y?l University, Health Occupation High School, Van 65080, Turkey
⁴I?d?r University, Departments of Electrical and Electronic Engineering, I?d?r, Turkey

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BAHSHELI Guliyev, AKBAR Barati Chiyaneh, NOVRUZ Bashirov et al 2015 Chin. Phys. Lett. 32 077204

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Abstract Effects of nonparabolicity of energy band on thermopower, in-plane effective mass and Fermi energy are investigated in size-quantized semiconductor films in a strong while non-quantized magnetic field. We obtain the expressions of these quantities as functions of thickness, concentration and nonparabolicity parameter. The influence of nonparabolicity is studied for degenerate and non-degenerate electron gases, and it is shown that nonparabolicity changes the character of thickness and the concentration dependence of thermopower, in-plane effective mass and Fermi energy. Moreover, the magnitudes of these quantities significantly increase with respect to the nonparabolicity parameter in the case of strong nonparabolicity in nano-films. The concentration dependence is also studied, and it is shown that thermopower increases when the concentration decreases. These results are in agreement with the experimental data.

Received: 02 February 2015 Published: 30 July 2015

PACS:	72.20.Pa	(Thermoelectric and thermomagnetic effects)
	72.15.Jf	(Thermoelectric and thermomagnetic effects)
	73.21.Fg	(Quantum wells)
	73.61.Ey	(III-V semiconductors)

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https://cpl.iphy.ac.cn/10.1088/0256-307X/32/7/077204 OR https://cpl.iphy.ac.cn/Y2015/V32/I07/077204

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	BAHSHELI Guliyev
	AKBAR Barati Chiyaneh
	NOVRUZ Bashirov
	GENBER Kerimli

[1] Askerov B M 1994 Electron Transport Phenomena in Semiconductors (Singapore: World Scientific Publishing)
[2] Anselm A I 1981 Introduction to Semiconductor Theory (Moscow: MIR Publisher)
[3] Ekenberg U 1989 Phys. Rev. B 40 7714
[4] Haunt S, Mandray A and Etyenne B 1992 Phys. Rev. B 46 2613
[5] Warburton R J, Michels J G, Nicolas R J, Haris J J and Faxon C T 1992 Phys. Rev. B 46 13394
[6] Guliyev B I and Eminbeyli R F 2008 Physica B 403 1751
[7] Guliyev B I and Kerimli G 2012 Mod. Phys. Lett. B 26 1250198
[8] Freik D M, Yurchyshyn I K, Potyak V Y and Chobaniuk V M 2014 Ukr. J. Phys. 59 No 2
[9] Rogacheva E I, Lyubchenko S G, Meriuts A V, Yanenko P A, Men'shov Y V and Dresselhaus M S 2007 Semiconducting Lead Chalcogenides (New York: Plenum) p 156
[10] Dmytro M F, Igor K Y, Vasyl V B, Lidiya T H and Yuriy V L Nanomaterials: Applications and Properties (NAP-201), Vol 1 Part I
[11] Martin J, Wang L, Chen L D and Nolas G S 2009 Phys. Rev. B 79 115311
[12] Nate M, Eugene E H, Gregor K, Chad G, James S S, William J S, Michael E H, Kin M Y and Joel W A 2011 Phys. Rev. B 84 075315
[13] Freik D M, Yurchyshyn I K, Potyak V Y and Lysiuk Y V 2011 Semiconduct. Phys. Quantum Electron. Optoelectron. 14 344
[14] Patil, S S and Pawar P H 2012 Chalcogenide Lett. 9 133

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