自形腔下的类氢等离子体

Q2 Physics and Astronomy Quantum Reports Pub Date : 2023-05-30 DOI:10.3390/quantum5020030

S. Chowdhury, Neetik Mukherjee, Amlan K. Roy

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引用次数: 1

摘要

在过去的几十年里，受限量子系统已经成为物理、化学和生物科学中一个相当重要的学科。在这样的压力条件下，它们表现出许多迷人而显著的物理和化学特性。在这里，我们通过使用两个等离子体模型来解决这种情况，即由Debye-Hückel势（DHP）和指数余弦屏蔽库仑势（ECSCP）模拟的弱耦合等离子体环境。另一方面，通过Woods-Saxon（WS）势实现了内面体约束。研究了任意状态下的临界屏蔽常数、偶极振子强度和极化率。基于香农熵的策略被用来研究相变。Z的增加导致更大的临界筛查。此外，一项详细的研究表明，在这种等离子体中至少存在一种束缚态。对一些低洼州进行了初步计算(ℓ=1−5），提供最优的、非均匀的径向离散化。

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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Hydrogen-like Plasmas under Endohedral Cavity

Over the past few decades, confined quantum systems have emerged to be a subject of considerable importance in physical, chemical and biological sciences. Under such stressed conditions, they display many fascinating and notable physical and chemical properties. Here we address this situation by using two plasma models, namely a weakly coupled plasma environment mimicked by a Debye-Hückel potential (DHP) and an exponential cosine screened Coulomb potential (ECSCP). On the other hand, the endohedral confinement is achieved via a Woods-Saxon (WS) potential. The critical screening constant, dipole oscillator strength (OS) and polarizability are investigated for an arbitrary state. A Shannon entropy-based strategy has been invoked to study the phase transition here. An increase in Z leads to larger critical screening. Moreover, a detailed investigation reveals that there exists at least one bound state in such plasmas. Pilot calculations are conducted for some low-lying states (ℓ=1−5) using a generalized pseudo spectral scheme, providing optimal, non-uniform radial discretization.

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