Multiscale modeling of fluctuations in stochastic elliptic pde models of nanosensors

Clemens Heitzinger; Christian Ringhofer

doi:10.4310/CMS.2014.v12.n3.a1

Multiscale modeling of fluctuations in stochastic elliptic pde models of nanosensors

Clemens Heitzinger, Christian Ringhofer

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

In this work, the multiscale problem of modeling fluctuations in boundary layers in stochastic elliptic partial differential equations is solved by homogenization. A homogenized equation for the covariance of the solution of stochastic elliptic PDEs is derived. In addition to the homogenized equation, a rate for the covariance and variance as the cell size tends to zero is given. For the homogenized problem, an existence and uniqueness result and further properties are shown. The multiscale problem stems from the modeling of the electrostatics in nanoscale field-effect sensors, where the fluctuations arise from random charge concentrations in the cells of a boundary layer. Finally, numerical results and a numerical verification are presented.

Original language	English (US)
Pages (from-to)	401-421
Number of pages	21
Journal	Communications in Mathematical Sciences
Volume	12
Issue number	3
DOIs	https://doi.org/10.4310/CMS.2014.v12.n3.a1
State	Published - 2014

Keywords

Biofet.
Field-effect sensor
Homogenization
Limiting problem
Multiscale problem
Nanowire
Rate
Stochastic elliptic partial differential equation

ASJC Scopus subject areas

General Mathematics
Applied Mathematics

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10.4310/CMS.2014.v12.n3.a1

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abstract = "In this work, the multiscale problem of modeling fluctuations in boundary layers in stochastic elliptic partial differential equations is solved by homogenization. A homogenized equation for the covariance of the solution of stochastic elliptic PDEs is derived. In addition to the homogenized equation, a rate for the covariance and variance as the cell size tends to zero is given. For the homogenized problem, an existence and uniqueness result and further properties are shown. The multiscale problem stems from the modeling of the electrostatics in nanoscale field-effect sensors, where the fluctuations arise from random charge concentrations in the cells of a boundary layer. Finally, numerical results and a numerical verification are presented.",

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AU - Ringhofer, Christian

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AB - In this work, the multiscale problem of modeling fluctuations in boundary layers in stochastic elliptic partial differential equations is solved by homogenization. A homogenized equation for the covariance of the solution of stochastic elliptic PDEs is derived. In addition to the homogenized equation, a rate for the covariance and variance as the cell size tends to zero is given. For the homogenized problem, an existence and uniqueness result and further properties are shown. The multiscale problem stems from the modeling of the electrostatics in nanoscale field-effect sensors, where the fluctuations arise from random charge concentrations in the cells of a boundary layer. Finally, numerical results and a numerical verification are presented.

KW - Biofet.

KW - Field-effect sensor

KW - Homogenization

KW - Limiting problem

KW - Multiscale problem

KW - Nanowire

KW - Rate

KW - Stochastic elliptic partial differential equation

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Multiscale modeling of fluctuations in stochastic elliptic pde models of nanosensors

Abstract

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