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Main Authors: Ávalos, Gerardo Gómez, Rivera, Jaime Muñoz, Ochoa, Elena Ochoa
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.01964
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author Ávalos, Gerardo Gómez
Rivera, Jaime Muñoz
Ochoa, Elena Ochoa
author_facet Ávalos, Gerardo Gómez
Rivera, Jaime Muñoz
Ochoa, Elena Ochoa
contents We investigate the impact of dissipative dynamic boundary conditions applied at one end of a beam, analyzing their influence on model stability within the Euler-Bernoulli framework. Our primary finding is that hybrid dissipation does not alter the decay characteristics of the original model. We examine two scenarios: first, when hybrid dissipation is the sole dissipative mechanism, and second, when it complements other dissipative mechanisms. In the first case, we demonstrate that hybrid dissipation fails to induce exponential decay, instead producing a slow decay rate of $t^{-1/2}$ for large $t$. In the second case, when acting as a complementary mechanism, hybrid dissipation neither enhances nor diminishes the decay behavior of the original model.
format Preprint
id arxiv_https___arxiv_org_abs_2512_01964
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Absence of Exponential Stability and Polynomial Stabilization in a Class of Beam Models with Tip Rotary Inertia
Ávalos, Gerardo Gómez
Rivera, Jaime Muñoz
Ochoa, Elena Ochoa
Analysis of PDEs
35B40, 74K10, 35B35
G.0
We investigate the impact of dissipative dynamic boundary conditions applied at one end of a beam, analyzing their influence on model stability within the Euler-Bernoulli framework. Our primary finding is that hybrid dissipation does not alter the decay characteristics of the original model. We examine two scenarios: first, when hybrid dissipation is the sole dissipative mechanism, and second, when it complements other dissipative mechanisms. In the first case, we demonstrate that hybrid dissipation fails to induce exponential decay, instead producing a slow decay rate of $t^{-1/2}$ for large $t$. In the second case, when acting as a complementary mechanism, hybrid dissipation neither enhances nor diminishes the decay behavior of the original model.
title Absence of Exponential Stability and Polynomial Stabilization in a Class of Beam Models with Tip Rotary Inertia
topic Analysis of PDEs
35B40, 74K10, 35B35
G.0
url https://arxiv.org/abs/2512.01964