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Main Authors: Tang, Aijie, Liu, Junjie, Liu, Xia, Liu, Mingchao, Wei, Xiaoding, Yang, Qingsheng
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.19987
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author Tang, Aijie
Liu, Junjie
Liu, Xia
Liu, Mingchao
Wei, Xiaoding
Yang, Qingsheng
author_facet Tang, Aijie
Liu, Junjie
Liu, Xia
Liu, Mingchao
Wei, Xiaoding
Yang, Qingsheng
contents Designing materials that can effectively and repeatedly absorb energy from unpredictable directions represents a grand challenge in modern engineering, crucial for applications from vehicle crashworthiness systems to personal protective equipment. While bistable structures offer a promising pathway towards reusable energy absorbers, their functionality is almost universally constrained to a single loading axis, rendering them vulnerable and ineffective against off axis or oblique impacts. Here, we report the discovery and harnessing of eversion buckling, a distinct pitchfork bifurcation phenomenon in axisymmetric shells, to overcome this fundamental limitation. By strategically designing shell geometries to leverage this mechanism, we have engineered structural units with robust, inplane omnidirectional bistability. This property is characterized by a massive and rapid volumetric contraction upon snapping, which is key to its exceptional performance. When assembled, these structures exhibit an ideal, extended stress plateau, leading to a near perfect energy absorption efficiency dramatically outperforming typical energy absorbing materials. Furthermore, we demonstrate that the system's damping capacity far exceeds its constituent material, and highly tunable, spanning a sixfold range of loss factors which enables load adaptive properties. This design strategy, elucidates a clear mechanism rooted in enhanced friction and sequential stress release, paving the way for a new class of robust, reusable, and load adaptive energy absorbing systems.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19987
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Harnessing Eversion Buckling for Ideal Omnidirectional Energy Absorption
Tang, Aijie
Liu, Junjie
Liu, Xia
Liu, Mingchao
Wei, Xiaoding
Yang, Qingsheng
Mathematical Physics
Classical Physics
Designing materials that can effectively and repeatedly absorb energy from unpredictable directions represents a grand challenge in modern engineering, crucial for applications from vehicle crashworthiness systems to personal protective equipment. While bistable structures offer a promising pathway towards reusable energy absorbers, their functionality is almost universally constrained to a single loading axis, rendering them vulnerable and ineffective against off axis or oblique impacts. Here, we report the discovery and harnessing of eversion buckling, a distinct pitchfork bifurcation phenomenon in axisymmetric shells, to overcome this fundamental limitation. By strategically designing shell geometries to leverage this mechanism, we have engineered structural units with robust, inplane omnidirectional bistability. This property is characterized by a massive and rapid volumetric contraction upon snapping, which is key to its exceptional performance. When assembled, these structures exhibit an ideal, extended stress plateau, leading to a near perfect energy absorption efficiency dramatically outperforming typical energy absorbing materials. Furthermore, we demonstrate that the system's damping capacity far exceeds its constituent material, and highly tunable, spanning a sixfold range of loss factors which enables load adaptive properties. This design strategy, elucidates a clear mechanism rooted in enhanced friction and sequential stress release, paving the way for a new class of robust, reusable, and load adaptive energy absorbing systems.
title Harnessing Eversion Buckling for Ideal Omnidirectional Energy Absorption
topic Mathematical Physics
Classical Physics
url https://arxiv.org/abs/2512.19987