Microscopic Study of Two Band Superconductivity in Magnesium Diboride Superconductor (MgB2)

American Journal of Physics and Applications Pub Date : 2021-04-26 DOI:10.11648/J.AJPA.20210902.11

B. K. Sahoo, B. Mishra, Subhalaxmi Das, S. K. Barik, P. Patnaik, Ruchi Bhuyan, B. Panda

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Abstract

We formulate a Model Hamiltonian of two band superconductivity for Magnesium Diboride superconductors (MgB2). It is a conventional BCS type metallic superconductor which has the highest critical temperature Tc=39K. It is assumed that the superconductivity in MgB2 arises due to metallic nature of the 2D sheets. From band structure calculations, it is observed that two types of bands i.e. σ and π bands are located at Fermi surface. Here, we consider phonon mediated superconductivity in which σ band is dominant over π band i.e. σ band is more coupled to a superconductor with much higher coupling. We consider a model Hamiltonian with mean field approach and solve this by calculating equations of motion of Green functions for a single particle. We determine the quasi-particle energy from the poles of the Green functions. We derive the single particle correlation functions and determine the two SC order parameters for both σ and π band. Here, the two SC order parameters for the bands are solved self- consistently and numerically. The conduction bandwidth (W) is considered as W=8t0, where t0 is the hopping integral. To make all the physical quantities dimensionless, we divide 2t0 in each of the physical quantities. We then calculate the gap ratio 2∆(0)/KBTc for both the bands. It is seen form our theoretical model that the two bands of MgB2 superconductors have two different SC gaps with the same critical temperature. We also observe the variation of dispersion curves of quasi-particles for different temperature parameters for both σ and π band.

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二硼化镁超导体(MgB2)双带超导性的微观研究

我们建立了二硼化镁超导体(MgB2)双带超导的哈密顿量模型。它是一种传统的BCS型金属超导体，最高临界温度Tc=39K。假定MgB2中的超导性是由于二维薄片的金属性质引起的。从能带结构计算中发现，在费米表面存在两种能带，即σ能带和π能带。这里，我们考虑声子介导的超导，其中σ带优于π带，即σ带与高耦合的超导体耦合度更高。我们用平均场方法考虑一个模型哈密顿量，并通过计算单个粒子的格林函数运动方程来求解它。我们从格林函数的极点确定准粒子能量。我们推导了单粒子相关函数，并确定了σ和π波段的两个SC阶参数。在这里，两个波段的SC阶参数是自一致的和数值解。考虑导通带宽(W)为W=8t0，其中t0为跳频积分。为了使所有物理量无量纲化，我们在每个物理量中除以20。然后我们计算两个波段的间隙比2∆(0)/KBTc。从我们的理论模型可以看出，在相同的临界温度下，MgB2超导体的两个能带有两个不同的SC间隙。我们还观察了准粒子在σ和π波段不同温度参数下色散曲线的变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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American Journal of Physics and Applications

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