Induced Thermal Transport in the Toda Lattice Using Localized Passive Control

First International Conference on Industrial and Information Systems Pub Date : 2006-08-01 DOI:10.1109/ICIIS.2006.365638

R. Palamakumbura, D. H. S. Maithripala, M. Holtz, J. Berg, W. Dayawansa

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引用次数: 4

Abstract

Thermal behavior at the nanoscale presents both formidable challenges and tremendous opportunities. Theoretical treatment at this scale differs fundamentally from macroscopic analysis, because thermal energy may take a variety of forms at the crystal lattice level, with distinctly different consequences for dissipation. These dynamical behaviors have the potential to greatly enhance control of heat transport and, for example, mitigate the effects of local heating. To a surprising degree, simple lattice models display many of the salient phenomena observed in epitaxial crystal layers. The Toda lattice is a completely integrable, anharmonic, discrete particle model, incorporating only nearest-neighbor interactions. In this paper, we employ the Toda lattice, originally developed as a model of thermal transport in crystals, to develop ideas for applying control theory to such systems. As a first result, we show that localized feedback of a small number of integrals of motion can be used to convert slow phonon modes, associated with limited heat transfer, into fast phonons modes, thereby reducing local heating. We present simulations to validate the approach

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利用局域被动控制的Toda晶格中的诱导热输运

纳米尺度的热行为既有巨大的挑战，也有巨大的机遇。这一尺度下的理论处理与宏观分析有着根本的不同，因为热能在晶格水平上可以采取多种形式，对耗散的影响也截然不同。这些动力学行为有可能极大地增强对热传输的控制，例如，减轻局部加热的影响。令人惊讶的是，简单的晶格模型显示了许多在外延晶体层中观察到的显著现象。Toda晶格是一个完全可积的、非调和的、离散的粒子模型，只包含最近邻的相互作用。在本文中，我们采用Toda晶格，最初是作为晶体中的热输运模型开发的，以开发将控制理论应用于此类系统的想法。作为第一个结果，我们证明了少量运动积分的局部反馈可以用于将与有限传热相关的慢声子模式转换为快速声子模式，从而减少局部加热。我们给出了仿真来验证该方法

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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First International Conference on Industrial and Information Systems

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