Atomistic to continuum limits for computational materials science

Blanc, Xavier; Bris, Claude Le; Lions, Pierre-Louis

Blanc, Xavier ; Bris, Claude Le ; Lions, Pierre-Louis

ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 41 (2007), p. 391-426 / Harvested from Numdam

Access to full text
Full (PDF)
Full (DJVU)

Résumé

The present article is an overview of some mathematical results, which provide elements of rigorous basis for some multiscale computations in materials science. The emphasis is laid upon atomistic to continuum limits for crystalline materials. Various mathematical approaches are addressed. The setting is stationary. The relation to existing techniques used in the engineering literature is investigated.

Publié le : 2007-01-01

MR 2339634 | Zbl pre05252008 | 1 citation dans Numdam

DOI : https://doi.org/10.1051/m2an:2007018
Classification: 35-xx, 39-xx, 41-xx, 49-xx, 65-xx, 68-04, 73-xx

@article{M2AN_2007__41_2_391_0,
     author = {Blanc, Xavier and Bris, Claude Le and Lions, Pierre-Louis},
     title = {Atomistic to continuum limits for computational materials science},
     journal = {ESAIM: Mathematical Modelling and Numerical Analysis - Mod\'elisation Math\'ematique et Analyse Num\'erique},
     volume = {41},
     year = {2007},
     pages = {391-426},
     doi = {10.1051/m2an:2007018},
     mrnumber = {2339634},
     zbl = {pre05252008},
     language = {en},
     url = {http://dml.mathdoc.fr/item/M2AN_2007__41_2_391_0}
}

Blanc, Xavier; Bris, Claude Le; Lions, Pierre-Louis. Atomistic to continuum limits for computational materials science. ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 41 (2007) pp. 391-426. doi : 10.1051/m2an:2007018. http://gdmltest.u-ga.fr/item/M2AN_2007__41_2_391_0/

Bibliographie

[1] R. Alicandro and M. Cicalese, A general integral representation result for continuum limits of discrete energies with superlinear growth. SIAM J. Math. Anal. 36 (2004) 1-37. | MR 2083851 | Zbl 1070.49009

[2] M. Anitescu, D. Negrut, P. Zapol and A. El-Azab, A note on the regularity of reduced models obtained by nonlocal quasi-continuum-like approach. Technical report ANL/MCS-P1303-1105, Argonne National Laboratory, Argonne, Illinois (2005). Available at http://www-unix.mcs.anl.gov/ $\sim$ anitescu/PUBLICATIONS/quasicont.pdf. | MR 2470789 | Zbl 1163.65034

[3] N. Antonic, C.J. Van Duijn, W. Jäger and A. Mikelic, Multiscale problems in science and technology. Challenges to mathematical analysis and perspectives. Springer (2002). | MR 1998789 | Zbl 0989.00039

[4] M. Arndt and M. Griebel, Derivation of higher order gradient continuum models from atomistic models for crystalline solids. SIAM J. Multiscale Model. Simul. 4 (2005) 531-562. | MR 2162866 | Zbl 1093.74012

[5] M. Arroyo and T. Belytshko, A finite deformation membrane based on inter-atomic potentials for the transverse mechanics of nanotubes. Mech. Mater. 35 (2003) 175-622.

[6] N.W. Ashcroft and N.D. Mermin, Solid-State Physics. Saunders College Publishing (1976).

[7] A. Askar, Lattice dynamical foundations of continuum theories. World Scientific, Philadelphia (1985). | MR 857096

[8] J.M. Ball, Convexity conditions and existence theorems in nonlinear elasticity. Arch. Rat. Mech. Anal. 63 (1977) 337-403. | MR 475169 | Zbl 0368.73040

[9] J.M. Ball, Singularities and computation of miminizers for variational problems, in Foundations of Computational Mathematics, R. DeVore, A. Iserles and E. Suli Eds., Cambridge University Press London Mathematical Society Lecture Note Series 284 (2001) 1-20. | MR 1836612 | Zbl 0978.65053

[10] J.M. Ball, Some open problems in elasticity, in Geometry, Mechanics, and Dynamics. Springer (2002) 3-59. | Zbl 1054.74008

[11] J.M. Ball and R.D. James, Fine phase mixtures as minimizers of energy. Arch. Rat. Mech. Anal. 100 (1987) 13-52. | Zbl 0629.49020

[12] J.M. Ball and R.D. James, Proposed experimental tests of a theory of fine microstructure and the two-well problem. Phil. Trans. Royal Soc. London A 338 (1992) 389-450. | Zbl 0758.73009

[13] J.M. Ball and F. Murat, $W^{1, p}$ -quasiconvexity and variational problems for multiple integrals. J. Funct. Anal. 58 (1984) 225-253. | Zbl 0549.46019

[14] T.J. Barth, T. Chan and R. Haimes Eds., Multiscale and multiresolution methods, Lecture notes in computational science and engineering 20. Springer (2002). | MR 1928563 | Zbl 0976.00008

[15] P. Bénilan, H. Brezis and M. Crandall, A semilinear equation in $L^{1} (ℝ^{N})$ . Ann. Sc. Norm. Sup. Pisa 2 (1975) 523-555. | Numdam | Zbl 0314.35077

[16] A. Bensoussan, J.-L. Lions and G. Papnicolaou, Asymptotic analysis for periodic structures, Studies in Mathematics and its Applications 5. North-Holland (1978). | MR 503330 | Zbl 0404.35001

[17] F. Bethuel, G. Huisken, S. Müller and K. Steffen, Variational models for microstructures and phase transition, in Calculus of Variations and Geometric Evolution Problems, Lecture Notes in Mathematics 1713. Springer (1999) 85-210. | Zbl 0968.74050

[18] K. Bhattacharya, Microstructure of Martensite: Why It Forms and How It Gives Rise to the Shape-Memory Effect. Oxford Series on Materials Modelling, Oxford University Press (2003). | MR 2282631 | Zbl 1109.74002

[19] K. Bhattacharya and G. Dolzmann, Relaxation of some multi-well problems. Proc. Royal Soc. Edinburgh A 131 (2001) 279-320. | Zbl 0977.74029

[20] X. Blanc, A mathematical insight into ab initio simulations of solid phase, in Mathematical Models and Methods for Ab Initio Quantum Chemistry, M. Defranceschi and C. Le Bris Eds., Lect. Notes Chem. 74. Springer (2000) 133-158. | Zbl 0991.82001

[21] X. Blanc, Geometry optimization for crystals in Thomas-Fermi type theories of solids. Comm. P.D.E. 26 (2001) 651-696. | Zbl 1022.82017

[22] X. Blanc, Unique solvability for system of nonlinear elliptic PDEs arising in solid state physics. SIAM J. Math. Anal. 38 (2006) 1235-1248. | Zbl pre05176035

[23] X. Blanc and C. Le Bris, Optimisation de géométrie dans le cadre des théories de Thomas-Fermi pour les cristaux périodiques [Geometry optimization for Thomas-Fermi type theories of solids]. Note C.R. Acad. Sci. Sér. 1 329 (1999) 551-556. | Zbl 0932.35004

[24] X. Blanc and C. Le Bris, Thomas-Fermi type models for polymers and thin films. Adv. Diff. Equ. 5 (2000) 977-1032. | Zbl pre01700755

[25] X. Blanc and C. Le Bris, Periodicity of the infinite-volume ground-state of a one-dimensional quantum model. Nonlinear Anal., T.M.A 48 (2002) 791-803. | Zbl 0992.82043

[26] X. Blanc and C. Le Bris, Définition d'énergies d'interfaces à partir de modèles atomiques. Note C.R. Acad. Sci. Sér. 1 340 (2005) 535-540. | Zbl 1117.74006

[27] X. Blanc, C. Le Bris and F. Legoll, Analysis of a prototypical multiscale method coupling atomistic and continuum mechanics. ESAIM: M2AN 39 (2005) 797-826. | Numdam | Zbl pre02213940

[28] X. Blanc, C. Le Bris and F. Legoll, Analysis of a prototypical multiscale method coupling atomistic and continuum mechanics: the convex case. Acta Math. Appl. Sinica (to appear). | MR 2300225

[29] X. Blanc, C. Le Bris and P.-L. Lions, Convergence de modèles moléculaires vers des modèles de mécanique des milieux continus [From molecular models to continuum mechanics]. Note C.R. Acad. Sci. Sér. 1 332 (2001) 949-956. | Zbl 0986.74006

[30] X. Blanc, C. Le Bris and P.-L. Lions, From molecular models to continuum mechanics. Arch. Rat. Mech. Anal. 164 (2002) 341-381. | Zbl 1028.74005

[31] X. Blanc, C. Le Bris and P.-L. Lions, A definition of the ground state energy for systems composed of infinitely many particles. Comm. P.D.E 28 (2003) 439-475. | Zbl 1035.82004

[32] X. Blanc, C. Le Bris and P.-L. Lions, Du discret au continu pour des modèles de réseaux aléatoires d'atomes [Discrete to continuum limit for some models of stochastic lattices of atoms]. Note C.R. Acad. Sci. Sér. 1. 342 (2006) 627-633. | Zbl 1095.74006

[33] X. Blanc, C. Le Bris and P.-L. Lions, On the energy of some microscopic stochastic lattices. Arch. Rat. Mech. Anal. 184 (2007) 303-339. | Zbl pre05149166

[34] X. Blanc, C. Le Bris and P.-L. Lions (in preparation).

[35] A. Braides, $Γ$ -convergence for beginners, Oxford Lecture Series in Mathematics and its Applications 22. Oxford University Press, Oxford (2002). | MR 1968440 | Zbl pre01865939

[36] A. Braides, Non-local variational limits of discrete systems. Commun. Contemp. Math. 2 (2000) 285-297. | Zbl 0957.49011

[37] A. Braides and M.S. Gelli, Continuum limits of discrete systems without convexity hypotheses. Math. Mech. Solids 7 (2002) 41-66. | Zbl 1024.74004

[38] A. Braides and M.S. Gelli, Limits of discrete systems with long-range interactions. J. Convex Anal. 9 (2002) 363-399. | Zbl 1031.49022

[39] A. Braides and M.S. Gelli, The passage from discrete to continuous variational problems: a nonlinear homogenization process. Preprint of the Scuola Normale Superiore di Pisa (2003). Available at http://cvgmt.sns.it/cgi/get.cgi/papers/bragel03/ | MR 2268900

[40] A. Braides, G. Dal Maso and A. Garroni, Variational formulation of softening phenomena in fracture mechanics: the one-dimensional case. Arch. Rat. Mech. Anal. 146 (1999) 23-58. | Zbl 0945.74006

[41] A. Braides, M.S. Gelli and M. Sigalotti, The passage from nonconvex discrete systems to variational problems in Sobolev spaces: the one-dimensional case. Proc. Steklov Inst. Math. 236 (2002) 395-414. | Zbl 1023.49009

[42] L. Breimana, Probability, Classics in Applied Mathematics. SIAM, Philadelphia (1992). | MR 1163370 | Zbl 0753.60001

[43] H. Brezis, Semilinear equations in $ℝ^{N}$ without condition at infinity. Appl. Math. Optim. 12 (1984) 271-282. | Zbl 0562.35035

[44] V.V. Bulatov and T. Diaz De La Rubia, Multiscale modelling of materials. MRS Bulletin 26 (2001).

[45] D. Caillerie, A. Mourad and A. Raoult, Discrete homogenization in graphene sheet modeling, J. Elasticity 84 (2006) 33-68. | Zbl 1103.74348

[46] C. Carstensen, Numerical Analysis of Microstructure, in Theory and Numerics of Differential Equations, J.F. Blowey, J.P. Coleman and A.W. Craig Eds., Springer (2001) 59-126. | Zbl 1070.74033

[47] C. Carstensen and T. Roubíček, Numerical approximation of young measuresin non-convex variational problems. Numer. Math. 84 (2000) 395-415. | Zbl 0945.65070

[48] I. Catto, C. Le Bris and P.-L. Lions, Limite thermodynamique pour des modèles de type Thomas-Fermi. Note C.R.A.S. Sér. 1 322 (1996) 357-364. | Zbl 0849.35114

[49] I. Catto, C. Le Bris and P.-L. Lions, Sur la limite thermodynamique pour des modèles de type Hartree et Hartree-Fock [On the thermodynamic limit for Hartree and Hartree-Fock type models]. Note C.R.A.S. Sér. 1 327 (1998) 259-266. | Zbl 0919.35142

[50] I. Catto, C. Le Bris and P.-L. Lions, Mathematical theory of thermodynamic limits: Thomas-Fermi type models. Oxford University Press (1998). | MR 1673212 | Zbl 0938.81001

[51] I. Catto, C. Le Bris and P.-L. Lions, On the thermodynamic limit for Hartree-Fock type models. Ann. Inst. H. Poincaré, Anal. Non Linéaire 18 (2001) 687-760. | Numdam | Zbl 0994.35115

[52] I. Catto, C. Le Bris and P.-L. Lions, On some periodic Hartree-type models for crystals. Ann. Inst. H. Poincaré, Anal. Non Linéaire 19 (2002) 143-190. | Numdam | Zbl 1005.81101

[53] I. Catto, C. Le Bris and P.-L. Lions, From atoms to crytals: a mathematical journey. Bull. Amer. Math. Soc. 42 (2005) 291-363. | Zbl 1136.81371

[54] M. Chipot and D. Kinderlehrer, Equilibrium configurations of crystals. Arch. Rat. Mech. Anal. 103 (1988) 237-277. | Zbl 0673.73012

[55] P.G. Ciarlet, Mathematical elasticity, Vol. 1. North Holland (1993). | Zbl 0648.73014

[56] G. Csányi, T. Albaret, G. Moras, M.C. Payne and A. De Vita, Multiscale hybrid simulation methods for material systems J. Phys. Condens. Matt. 17 (2005) R691.

[57] R. Dacorogna, Direct methods in the calculus of variations. Springer-Verlag Berlin (1989). | MR 990890 | Zbl 0703.49001

[58] G. Dal Maso, An introduction to $Γ$ -convergence, Progress in Nonlinear Differential Equations and their Applications 8. Birkhäuser Boston, Inc., Boston, MA (1993). | MR 1201152 | Zbl 0816.49001

[59] P. Deák, T. Frauenheim and M.R. Pederson, Eds., Computer simulation of materials at atomic level. Wiley (2000).

[60] B.N. Delaunay, N.P. Dolbilin, M.I. Shtogrin and R.V. Galiulin, A local criterion for regularity of a system of points. Sov. Math. Dokl. 17 (1976) 319-322. | Zbl 0338.50007

[61] G. Dolzmann, Variational Methods for Crystalline Microstructure - Analysis and Computation. Springer-Verlag (2003). | Zbl 1016.74002

[62] W. E and B. Engquist, The Heterogeneous Multi-Scale Methods. Comm. Math. Sci. 1 (2003) 87-132. | Zbl 1093.35012

[63] W. E and Z. Huang, Matching conditions in atomistic-continuum modeling of materials. Phys. Rev. Lett. 87 (2001) 135501.

[64] W. E and Z. Huang, A dynamic atomistic-continuum method for the simulation of crystalline materials. J. Comp. Phys. 182 (2002) 234-261. | Zbl 1013.82022

[65] W. E and P.B. Ming, Atomistic and continuum theory of solids, I. Preprint (2003).

[66] W. E and P.B. Ming, Analysis of multiscale methods. J. Comp. Math. 22 (2004) 210-219. | Zbl 1046.65108

[67] W. E and P.B. Ming, Cauchy-Born rule and stability of crystals: static problems. Arch. Rat. Mech. Anal. 183 (2007) 241-297. | Zbl 1106.74019

[68] M. Fago, R.L. Hayes, E.A. Carter and M. Ortiz, Density-functional-theory-based local quasicontinuum method: Prediction of dislocation nucleation. Phys. Rev. B 70 (2004) 100102(R).

[69] I. Fonseca, Variational methods for elastic crystals. Arch. Rat. Mech. Anal. 97 (1987) 187-220. | Zbl 0611.73023

[70] I. Fonseca, The lower quasiconvex envelope of the stored energy function for an elastic crystal. J. Math. Pures Appl. 67 (1988) 175-195. | Zbl 0718.73075

[71] G. Friesecke and R.D. James, A scheme for the passage from atomic to continuum theory for thin films, nanotubes and nanorods. J. Mech. Phys. Solids 48 (2000) 1519-1540. | Zbl 0984.74009

[72] G. Friesecke, R.D. James and S. Müller, Rigorous derivation of nonlinear plate theory and geometric rigidity. C.R. Acad. Sci. Paris Sér. I 334 (2002) 173-178. | Zbl 1012.74043

[73] G. Friesecke and F. Theil, Validity and failure of the Cauchy-Born hypothesis in a Two-Dimensional Mass-Spring Lattice. J. Nonlinear Sci. 12 (2002) 445-478. | Zbl 1084.74501

[74] C.S. Gardner and C. Radin, The infinite-volume ground state of the Lennard-Jones potential. J. Stat. Phys. 20 (1979) 719-724.

[75] G. Geymonat, F. Krasucki and S. Lenci, Analyse asymptotique du comportement d'un assemblage collé [Asymptotic analysis of the behaviour of a bonded joint]. C.R. Acad. Sci. Paris Sér. I 322 (1996) 1107-1112. | Zbl 0862.73011

[76] G. Geymonat, F. Krasucki and S. Lenci, Mathematical analysis of a bonded joint with a soft thin adhesive. Math. Mech. Solids 4 (1999) 201-225. | Zbl 1001.74591

[77] WJ. Hehre, L. Radom, P.V.R. Shleyer and J. Pople, Ab initio molecular orbital theory. Wiley (1986).

[78] O. Iosifescu, C. Licht and G. Michaille, Variational limit of a one dimensional discrete and statistically homogeneous system of material points. Asymptot. Anal. 28 (2001) 309-329. | Zbl 1031.74041

[79] O. Iosifescu, C. Licht and G. Michaille, Variational limit of a one-dimensional discrete and statistically homogeneous system of material points. C.R. Acad. Sci. Paris Sér. I Math. 332 (2001) 575-580. | Zbl 0995.60030

[80] F. John, Rotation and strain. Comm. Pure Appl. Math. 14 (1961) 391-413. | Zbl 0102.17404

[81] F. John, Bounds for deformations in terms of average strains, in Inequalities III, O. Shisha Ed. (1972) 129-144. | Zbl 0292.53003

[82] D. Kinderlehrer, Remarks about equilibrium configurations of crystals, in Material instabilities in contiuum mechanics and related mathematical problems, J.M. Ball Ed., Oxford University Press (1998) 217-242.

[83] D. Kinderlehrer and P. Pedregal, Characterization of Young measures generated by gradients. Arch. Rat. Mech. Anal. 115 (1991) 329-365. | Zbl 0754.49020

[84] D. Kinderlehrer and P. Pedregal, Gradient Young measures generated by sequences in Sobolev spaces. J. Geom. Anal. 4 (1994) 59-90. | Zbl 0808.46046

[85] O. Kirchner, L.P. Kubin and V. Pontikis Eds., Computer simulation in materials science, Kluwer (1996).

[86] H. Kitagawa, T. Aihara Jr. and Y. Kawazoe Eds., Mesoscopic dynamics of fracture, Advances in Materials Research. Springer (1998).

[87] C. Kittel, Introduction to Solid State Physics. 7th edn. Wiley (1996). | Zbl 0052.45506

[88] J. Knap and M. Ortiz, An Analysis of the QuasiContinuum Method. J. Mech. Phys. Solids 49 (2001) 1899. | Zbl 1002.74008

[89] R.V. Kohn and G. Strang, Optimal design and relaxation of variational problems. I-II-III. Comm. Pure Appl. Math. 39 (1986) 113-137, 139-182, 353-377. | Zbl 0621.49008

[90] U. Krengel, Ergodic theorems, Studies in Mathematics 6. de Gruyter (1985). | MR 797411 | Zbl 0575.28009

[91] J. Kristensen, On the non-locality of quasiconvexity. Ann. Inst. H. Poincaré, Anal. Non Linéaire 16 (1999) 1-13. | Numdam | Zbl 0932.49015

[92] C. Le Bris, Computational Chemistry, in Handbook of numerical analysis, Vol. X, P.G. Ciarlet Ed., North-Holland (2003). | MR 2008385 | Zbl 1052.81001

[93] C. Le Bris, Computational chemistry from the perspective of numerical analysis, Acta Numer. 14 (2005) 363-444. | Zbl 1119.65390

[94] J. Li, K.J. Van Vliet, T. Zhu, S. Suresh and S. Yip, Atomistic mechanisms governing elastic limit and incipient plasticity in crystals. Nature 418 (2002) 307.

[95] C. Licht, Comportement asymptotique d'une bande dissipative mince de faible rigidité [Asymptotic behaviour of a thin dissipative layer with low stiffness]. C.R. Acad. Sci. Paris Sér. I 317 (1993) 429-433. | Zbl 0781.73059

[96] C. Licht and G. Michaille, Une modélisation du comportement d'un joint collé élastique [A modelling of elastic adhesively bonding joints]. C.R. Acad. Sci. Paris Sér. I 322 (1996) 295-300. | Zbl 0863.73019

[97] E.H. Lieb, Thomas-Fermi and related theories of atoms and molecules. Rev. Modern Phys. 53 (1981) 603-641 . | Zbl 1049.81679

[98] E.H. Lieb and B. Simon, The Thomas-Fermi theory of atoms, molecules and solids. Adv. Math. 23 (1977) 22-116. | Zbl 0938.81568

[99] P. Lin, A nonlinear wave equation of mixed type for fracture dynamics. Research report No. 777, Department of Mathematics, The National University of Singapore, August 2000. Available at http://www.math.nus.edu.sg/ matlinp/WWW/linsiap.pdf

[100] P. Lin, Theoretical and numerical analysis of the quasi-continuum approximation of a material particle model. Math. Comput. 72 (2003) 657-675. | Zbl 1010.74003

[101] P. Lin, Convergence analysis of a quasi-continuum approximation for a two-dimensional material. Preprint 2005-80 of the Institute for mathematical sciences, National University of Singapore (2005). Available at http://www.ims.nus.edu.sg/preprints/2005-80.pdf

[102] P. Lin and C.W. Shu, Numerical solution of a virtual internal bond model for material fracture. Physica D 167 (2002) 101-121. | Zbl 1098.74525

[103] W.K. Liu, D. Qian and M.F. Horstemeyer, Special Issue on Multiple Scale Methods for Nanoscale Mechanics and Materials. Comp. Meth. Appl. Mech. Eng. 193 (2004) 17-20. | Zbl 1079.74595

[104] M. Luskin, On the computation of crystalline microstructure. Acta Numer. 5 (1996) 191-258. | Zbl 0867.65033

[105] M. Luskin, Computational modeling of microstructure, in Proceedings of the International Congress of Mathematicians, ICM, Beijing (2002) 707-716. | Zbl 1025.49014

[106] R. Miller and E.B. Tadmor, The Quasicontinuum Method: Overview, applications and current directions. J. Computer-Aided Materials Design 9 (2002) 203-239.

[107] R. Miller, E.B. Tadmor, R. Phillips and M. Ortiz, Quasicontinuum simulation of fracture at the atomic scale. Modelling Simul. Mater. Sci. Eng. 6 (1998) 607.

[108] C.B. Morrey Jr., Quasi-convexity and the lower semi-continuity of multiple integrals. Pacific J. Math. 2 (1952) 25-53. | Zbl 0046.10803

[109] S. Müller, Variational models for microstructure and phase transitions, in Calculus of Variations and Geometric Evolution Problems. Lect. Notes Math. 1713. Springer Verlag, Berlin (1999) 85-210. | Zbl 0968.74050

[110] B.R.A. Nijboer and W.J. Ventevogel, On the configuration of systems of interacting particles with minimum potential energy per particle. Physica 98A (1979) 274. | MR 546896

[111] B.R.A Nijboer and W.J. Ventevogel, On the configuration of systems of interacting particles with minimum potential energy per particle. Physica 99A (1979) 569. | MR 552855

[112] C. Ortner, Continuum limit of a one-dimensional atomistic energy based on local minimization. Technical report 05/11, Oxford University Computing Laboratory (2005).

[113] S. Pagano and R. Paroni, A simple model for phase transitions: from the discrete to the continuum problem. Quart. Appl. Math. 61 (2003) 89-109. | Zbl 1068.74050

[114] P. Pedregal, Parametrized Measures and Variational Principles. Birkhäuser (1997). | MR 1452107 | Zbl 0879.49017

[115] P. Pedregal, Variational Methods in Nonlinear Elasticity. SIAM (2000). | MR 1741439 | Zbl 0941.74002

[116] C. Pisani Ed., Quantum mechanical ab initio calculation of the properties of crystalline materials, Lecture Notes in Chemistry 67. Springer (1996).

[117] D. Raabe, Computational Material Science. Wiley (1998).

[118] C. Radin, Ground states for soft disks. J. Stat. Phys. 26 (1981) 365. | MR 643714

[119] Y.G. Reshetnyak, Liouville's theory on conformal mappings under minimal regularity assumptions. Sibirskii Math. 8 (1967) 69-85. | Zbl 0172.37801

[120] M.O. Rieger and J. Zimmer, Young measure flow as a model for damage, SIAM J. Math. Anal. (2005) (to appear). | MR 2000976 | Zbl 1161.74007

[121] R.E. Rudd and J.Q. Broughton, Concurrent coupling of length scales in solid state system, in [59] 251-291.

[122] B. Schmidt, On the passage form atomic to continuum theory for thin films. Preprint 82/2005 of the Max Planck Institute of Leipzig (2005). Available at http://www.mis.mpg.de/preprints/2005/prepr2005_82.html | MR 2334775 | Zbl 1156.74028

[123] B. Schmidt, Qualitative properties of a continuum theory for thin films. Preprint 83/2005 of the Max Planck Institute of Leipzig (2005). Available at http://www.mis.mpg.de/preprints/2005/prepr2005_83.html | MR 2383078 | Zbl 1142.74026

[124] B. Schmidt, A derivation of continuum nonlinear plate theory form atomistic models. Preprint 90/2005 of the Max Planck Institute of Leipzig (2005). Available at http://www.mis.mpg.de/preprints/2005/prepr2005_90.html | MR 2247767 | Zbl 1117.49018

[125] V.B. Shenoy, R. Miller, E.B. Tadmor, R. Phillips and M. Ortiz, Quasicontinuum models of interfacial structure and deformation. Phys. Rev. Lett. 80 (1998) 742.

[126] V.B. Shenoy, R. Miller, E.B. Tadmor, D. Rodney, R. Phillips and M. Ortiz, An adaptative finite element approach to atomic-scale mechanics - the QuasiContinuum Method. J. Mech. Phys. Solids 47 (1999) 611. | Zbl 0982.74071

[127] J.P. Solovej, Universality in the Thomas-Fermi-von Weizsäcker model of atoms and molecules. Comm. Math. Phys. 129 (1990) 561-598. | Zbl 0708.35071

[128] V. Šveràk, On regularity for Monge-Ampère equations. Preprint, Heriott-Watt University (1991).

[129] V. Šveràk, Rank-one convexity does not imply quasiconvexity. Proc. Roy. Soc. Edinburgh A 120 (1992) 185-189. | Zbl 0777.49015

[130] V. Šveràk, On the problem of two wells, in Microstructure and phase transition, IMA Vol. Math. Appl. 54. Springer, New York, (1993) 183-189. | Zbl 0797.73079

[131] A. Szabo and N.S. Ostlund, Modern quantum chemistry: an introduction. Macmillan (1982).

[132] E.B. Tadmor and R. Phillips, Mixed atomistic and continuum models of deformation in solids. Langmuir 12 (1996) 4529.

[133] E.B. Tadmor, M. Ortiz and R. Phillips, Quasicontinuum analysis of defects in solids. Phil. Mag. A. 73 (1996) 1529-1563.

[134] E.B. Tadmor, G.S. Smith, N. Bernstein and E. Kaxiras, Mixed finite element and atomistic formulation for complex crystals. Phys. Rev. B 59 (1999) 235.

[135] F. Theil, A proof of crystallization in two dimensions. Comm. Math. Phys. 262 (2006) 209-236. | Zbl 1113.82016

[136] L. Truskinovsky, Fracture as a phase transformation, in Contemp. Res. in Mech. and Math. of Materials, Ericksen's symposium, R. Batra and M. Beatty Eds., CIMNE, Barcelone (1996) 322-332.

[137] W.J. Ventevogel, On the configuration of a one-dimensional system of interacting particles with minimum potential energy per particle. Physica 92A (1978) 343.

[138] S. Yip, Synergistic materials science. Nature Mater. 2 (2003) 3-5.

[139] L.C. Young, Lectures on the calculus of variations and optimal control theory. W.B. Saunders Co., Philadelphia-London-Toronto (1969). | Zbl 0177.37801

[140] F. Zaittouni, F. Lebon and C. Licht, Étude théorique et numérique du comportement d'un assemblage de plaques [Theoretical study of the behaviour of bonded plates]. C.R. Mécanique 330 (2002) 359-364. | Zbl 1038.74030