eprintid: 2045
rev_number: 7
eprint_status: archive
userid: 56
dir: disk0/00/00/20/45
datestamp: 2013-12-04 15:37:00
lastmod: 2014-10-09 09:20:24
status_changed: 2013-12-04 15:37:00
type: article
metadata_visibility: no_search
creators_name: Sapora, Alberto
creators_name: Paggi, Marco
creators_id: 
creators_id: marco.paggi@imtlucca.it
title: A coupled cohesive zone model for transient analysis of thermoelastic interface debonding
ispublished: pub
subjects: TJ
divisions: CSA
full_text_status: none
keywords: Thermoelasticity; Interface debonding; Cohesive zone model; Photovoltaics
note: Published online: 9 October 2013
abstract: A coupled cohesive zone model based on an analogy between fracture and contact mechanics is proposed to investigate debonding phenomena at imperfect interfaces due to thermomechanical loading and thermal fields in bodies with cohesive cracks. Traction-displacement and heat flux–temperature relations are theoretically derived and numerically implemented in the finite element method. In the proposed formulation, the interface conductivity is a function of the normal gap, generalizing the Kapitza constant resistance model to partial decohesion effects. The case of a centered interface in a bimaterial component subjected to thermal loads is used as a test problem. The analysis focuses on the time evolution of the displacement and temperature fields during the transient regime before debonding, an issue not yet investigated in the literature. The solution of the nonlinear numerical problem is gained via an implicit scheme both in space and in time. The proposed model is finally applied to a case study in photovoltaics where the evolution of the thermoelastic fields inside a defective solar cell is predicted.
date: 2013
date_type: published
publication: Computational Mechanics
publisher: Springer 
pagerange: 1-13
id_number: 10.1007/s00466-013-0934-8
refereed: TRUE
issn: 0178-7675
official_url: http://dx.doi.org/10.1007/s00466-013-0934-8
citation:   Sapora, Alberto and Paggi, Marco  A coupled cohesive zone model for transient analysis of thermoelastic interface debonding.  Computational Mechanics.  pp. 1-13.  ISSN 0178-7675      (2013)