Homogenization of non-local energies on disconnected sets (2405.09677v1)
Abstract: We consider the problem of the homogenization of non-local quadratic energies defined on $\delta$-periodic disconnected sets defined by a double integral, depending on a kernel concentrated at scale $\varepsilon$. For kernels with unbounded support we show that we may have three regimes: (i) $\varepsilon<!<\delta$, for which the $\Gamma$-limit even in the strong topology of $L2$ is $0$; (ii) $\frac\varepsilon\delta\to\kappa$, in which the energies are coercive with respect to a convergence of interpolated functions, and the limit is governed by a non-local homogenization formula parameterized by $\kappa$; (iii) $\delta<!<\varepsilon$, for which the $\Gamma$-limit is computed with respect to a coarse-grained convergence and exhibits a separation-of-scales effect; namely, it is the same as the one obtained by formally first letting $\delta\to 0$ (which turns out to be a pointwise weak limit, thanks to an iterated use of Jensen's inequality), and then, noting that the outcome is a nonlocal energy studied by Bourgain, Brezis and Mironescu, letting $\varepsilon\to0$. A slightly more complex description is necessary for case (ii) if the kernel is compactly supported.
- An extension theorem from connected sets, and homogenization in general periodic domains. Nonlinear Analysis, 18:481–496, 1992.
- A Variational Theory of Convolution-Type Functionals. Springer Nature, 2023.
- H. Attouch. Variational Convergence for Functions and Operators. Pitman, Boston, 1984.
- Hyperelasticity as a ΓΓ\Gammaroman_Γ-limit of peridynamics when the horizon goes to zero. Calc. Var. Partial Differential Equations, 54(2):1643–1670, 2015.
- Another look at Sobolev spaces. In Optimal control and partial differential equations, pages 439–455. IOS, Amsterdam, 2001.
- A. Braides. ΓΓ\Gammaroman_Γ-convergence for Beginners, volume 22 of Oxford Lecture Series in Mathematics and its Applications. Oxford University Press, Oxford, 2002.
- A. Braides and A. Defranceschi. Homogenization of Multiple Integrals, volume 12 of Oxford Lecture Series in Mathematics and its Applications. Oxford University Press, Oxford, 1998.
- Homogenization by blow-up. Applicable Anal., 87:1341–1356, 2008.
- A. Braides and A. Piatnitski. Homogenization of quadratic convolution energies in periodically perforated domains. Adv. Calc. Var., 15(3):351–368, 2022.
- G. Dal Maso. An Introduction to ΓΓ\Gammaroman_Γ-convergence. Birkhäuser, Boston, 1993.
- I. Fonseca and S. Müller. Quasiconvex integrands and lower semicontinuity in L1superscript𝐿1L^{1}italic_L start_POSTSUPERSCRIPT 1 end_POSTSUPERSCRIPT. SIAM J. Math. Anal., 23:1081–1098, 1992.
- H. W. Kuhn. Some combinatorial lemmas in topology. IBM Journal of Research and Development, 4(5):518–524, 1960.
- G. Leoni. A First Course in Fractional Sobolev Spaces, volume 229 of Graduate Studies in Mathematics. American Mathematical Society, Providence, RI, 2023.
- T. Mengesha and Q. Du. On the variational limit of a class of nonlocal functionals related to peridynamics. Nonlinearity, 28(11):3999–4035, 2015.
- A. C. Ponce. A new approach to Sobolev spaces and connections to ΓΓ\Gammaroman_Γ-convergence. Calc. Var. Partial Differential Equations, 19(3):229–255, 2004.
- M. Solci. Nonlocal-interaction vortices. SIAM J. Math. Anal., 56(3):3430–3451, 2024.
- V. V. Zhikov. Connectedness and homogenization. Examples of fractal conductivity. Sbornik: Mathematics, 187(8):1109, 1996.