2017
DOI: 10.1515/acv-2015-0009
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𝒜$\mathcal{A}$-quasiconvexity at the boundary and weak lower semicontinuity of integral functionals

Abstract: We state necessary and su cient conditions for weak lower semicontinuity of integral functionals of the form u → ∫ Ω h (x, u(x)) dx, where h is continuous and possesses a positively p-homogeneous recession function, p > , and u ∈ L p (Ω; ℝ m ) lives in the kernel of a constant-rank rst-order di erential operator A which admits an extension property. In the special case A = curl, apart from the quasiconvexity of the integrand, the recession function's quasiconvexity at the boundary in the sense of Ball and Mars… Show more

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Cited by 10 publications
(14 citation statements)
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“…where the deformation gradient outside is defined by (12) using the extensionỹ on c which is fixed, and J = det F. Following [39,Chapter 8], we note that the last term in (23) is independent of the choice of the fictitious 'deformation'ỹ since it can be transformed into the vacuum energy…”
Section: The Total Energymentioning
confidence: 99%
See 3 more Smart Citations
“…where the deformation gradient outside is defined by (12) using the extensionỹ on c which is fixed, and J = det F. Following [39,Chapter 8], we note that the last term in (23) is independent of the choice of the fictitious 'deformation'ỹ since it can be transformed into the vacuum energy…”
Section: The Total Energymentioning
confidence: 99%
“…Closely related is the compensated compactness theory [9,10]. The reader is referred to [11][12][13] for more recent developments and additional literature. This section discusses these notions from a general point of view; the specialization to electro-magneto-elastic materials is the subject of the succeeding sections.…”
Section: A-quasiconvexity: the General Casementioning
confidence: 99%
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“…Remark 3. Lemma 2.2 essentially requires ω to be an A -free extension domain in the sense of [17,Definition 4.3]. The example of the differential operator associated with the Cauchy-Riemann equations (d = m = 2, C ∼ = R 2 ) makes clear that an extension operator as in Lemma 2.2 may not always exist; for more details see [17,Section 4.2].…”
mentioning
confidence: 99%