Influence of Thermal Nonequilibrium on Recombination, Space Charge, and Transport Phenomena in Bipolar Semiconductors

Rodriguez, Chetzyl I. Ballardo; Filali, B. El; Titov, O. Yu.; Gurevich, Yu. G.

doi:10.1007/s10765-020-02647-2

Cited by 9 publications

(7 citation statements)

References 36 publications

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“…where μ 0 n and μ 0 p are chemical potential for electros and holes in equilibrium, α n and α p are the Seebeck coefficients. We considered that 9) and ( 10), we used [32] δμ…”

Section: General Equations For Charge Transport Phenomenamentioning

confidence: 99%

“…Here R is the recombination rate. Assuming, for simplicity, that interband recombination takes place, we get [32]…”

Section: General Equations For Charge Transport Phenomenamentioning

confidence: 99%

“…First, it itself depends on the nonequilibrium temperature, changing the concentration of current carriers. [32] Second, additional heat release (absorption) is associated with non-radiative recombination, which changes the Joule heating. [33] In recent years, a new class of materials, graphene, has attracted great interest.…”

Section: Introductionmentioning

confidence: 99%

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Joule Heating and Nonlinear Charge Transport in Bipolar Semiconductors

Filali

Titov

Rodriguez

et al. 2022

Physica Status Solidi (b)

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Joule heating of a homogeneous bipolar semiconductor leads to the appearance of nonequilibrium spatially inhomogeneous current carriers. Both energetic and concentration nonequilibrium states arise. Temperature and concentration gradients at the boundaries always have opposite signs. The concentration will become lower in heated regions, while it will become higher in less heated ones. Moreover, the spatial distributions of concentrations have one minimum in thin samples and two minimums and one maximum in thick samples. As a result, the current–voltage characteristic can take superlinear and sublinear forms.

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“…where μ 0 n and μ 0 p are chemical potential for electros and holes in equilibrium, α n and α p are the Seebeck coefficients. We considered that 9) and ( 10), we used [32] δμ…”

Section: General Equations For Charge Transport Phenomenamentioning

confidence: 99%

“…Here R is the recombination rate. Assuming, for simplicity, that interband recombination takes place, we get [32]…”

Section: General Equations For Charge Transport Phenomenamentioning

confidence: 99%

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Joule Heating and Nonlinear Charge Transport in Bipolar Semiconductors

Filali

Titov

Rodriguez

et al. 2022

Physica Status Solidi (b)

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“…Los dispositivos semiconductores son la base de la electrónica actual, por lo que es de suma importancia comprender todos los fenómenos que ocurren en dichos dispositivos. Para comprender los fenómenos físicos asociados con el flujo de corriente eléctrica y térmica en una estructura semiconductora, es muy importante comprender el establecimiento del equilibrio termodinámico en ella [1][2][3][4][5][6][7], en especial en las estructuras metal-semiconductor pues son el tipo de contactos que aparecen en los dispositivos referidos [1,2]. Sin embargo, en la literatura actual no hay una descripción detallada de dicho fenómeno en dichas estructuras siendo esa la motivación principal del presente artículo.…”

Section: Introductionunclassified

“…Sin embargo, en la literatura actual no hay una descripción detallada de dicho fenómeno en dichas estructuras siendo esa la motivación principal del presente artículo. En equilibrio termodinámico, en los materiales semiconductores, la relación entre la carga y campo eléctrico está dada por la ecuación de Poisson, y asociada a la solución de dicha ecuación aparece el radio de Debye (r D ) para dichos materiales [5][6][7]. A su vez, el radio de Debye nos permite establecer si un material presenta el fenómeno de cuasineutralidad cuando se cumple la relación r 2 D L 2 donde L es la longitud del material [8][9][10][11].…”

Section: Introductionunclassified

Estructura metal-semiconductor-metal en equilibrio

2020

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En este artículo se analiza el comportamiento de los portadores de carga eléctrica (electrones y huecos) en un material semiconductor con contactos metálicos bajo la condición de equilibrio termodinámico. Se obtuvieron expresiones para las concentraciones de los electrones y huecos, así como para el Radio de Debye (r D) tanto en el caso general bipolar, como para los casos particulares de materiales tipo n, p e intrínseco. Con base a las expresiones anteriores se analiza el caso cuando aparece el fenómeno de cuasineutralidad en un material semiconductor. Descriptores: Portadores de carga; contacto metal-semiconductor; cuasineutralidad. This article analyzes the behavior of electric charge carriers (electrons and holes) in a semiconductor material with metal contacts under the thermodynamic equilibrium condition. Expressions were obtained for the concentrations of the electrons and holes, as well as for the Debye Radius (r D) both in the general bipolar case, and in the particular cases of n, p and intrinsic type materials. Based on the previous expressions, the case is analyzed when the quasi-neutrality phenomenon appears in a semiconductor material.

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