Peng, Rui; Zhou, Maolin

Author(s)

Peng, Rui

Zhou, Maolin

Publication Date

2018

Abstract

In this article, we study, as the coefficient s → ∞, the asymptotic behavior of the principal eigenvalue of the eigenvalue problem −φ"(x)−2sm′(x)φ′(x)+c(x)φ(x)=λsφ(x), 0 < x < 1, complemented by a general boundary condition. This problem is relevant to nonlinear propagation phenomena in reaction-diffusion equations. The main point is that the advection (or drift) term m allows natural degeneracy. For instance, m can be constant on [a, b] ⊂ [0, 1]. Depending on the behavior of m near the neighbourhood of the endpoints a and b, the limiting value could be the principal eigenvalue of −φ"(x)+c(x)φ(x)=λφ(x), a < x < b, coupled with Dirichlet or Newmann boundary condition at a and b. A complete understanding of the limiting behavior of the principal eigenvalue and its eigenfunction is obtained, and new fundamental effects of large degenerate advection and boundary conditions on the principal eigenvalue and the principal eigenfunction are revealed. In one space dimension, the results in the existing literature are substantially improved.

Citation

Indiana University Mathematics Journal, 67(6), p. 2523-2568

ISSN

1943-5258

0022-2518

1943-5266

Link

https://hdl.handle.net/1959.11/28574

Publisher

Indiana University, Department of Mathematics

Title

Effects of Large Degenerate Advection and Boundary Conditions on the Principal Eigenvalue and its Eigenfunction of A Linear Second-Order Elliptic Operator

Type of document

Journal Article

Entity Type

Publication

Author(s)	Peng, Rui Zhou, Maolin
Publication Date	2018
Abstract	<p>In this article, we study, as the coefficient s → ∞, the asymptotic behavior of the principal eigenvalue of the eigenvalue problem </p><p> −φ"(x)−2sm′(x)φ′(x)+c(x)φ(x)=λsφ(x), 0 < x < 1, </p><p> complemented by a general boundary condition. This problem is relevant to nonlinear propagation phenomena in reaction-diffusion equations. The main point is that the advection (or drift) term m allows natural degeneracy. For instance, m can be constant on [a, b] ⊂ [0, 1]. Depending on the behavior of m near the neighbourhood of the endpoints a and b, the limiting value could be the principal eigenvalue of </p><p> −φ"(x)+c(x)φ(x)=λφ(x), a < x < b, </p><p> coupled with Dirichlet or Newmann boundary condition at a and b. A complete understanding of the limiting behavior of the principal eigenvalue and its eigenfunction is obtained, and new fundamental effects of large degenerate advection and boundary conditions on the principal eigenvalue and the principal eigenfunction are revealed. In one space dimension, the results in the existing literature are substantially improved.</p>
Citation	Indiana University Mathematics Journal, 67(6), p. 2523-2568
ISSN	1943-5258 0022-2518 1943-5266
Link	https://hdl.handle.net/1959.11/28574
Publisher	Indiana University, Department of Mathematics
Title	Effects of Large Degenerate Advection and Boundary Conditions on the Principal Eigenvalue and its Eigenfunction of A Linear Second-Order Elliptic Operator
Type of document	Journal Article
Entity Type	Publication

Effects of Large Degenerate Advection and Boundary Conditions on the Principal Eigenvalue and its Eigenfunction of A Linear Second-Order Elliptic Operator

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