Hyperbolic wavelet discretization of the two-electron Schrödinger equation in an explicitly correlated formulation
Bachmayr, Markus
ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 46 (2012), p. 1337-1362 / Harvested from Numdam
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In the framework of an explicitly correlated formulation of the electronic Schrödinger equation known as the transcorrelated method, this work addresses some fundamental issues concerning the feasibility of eigenfunction approximation by hyperbolic wavelet bases. Focusing on the two-electron case, the integrability of mixed weak derivatives of eigenfunctions of the modified problem and the improvement compared to the standard formulation are discussed. Elements of a discretization of the eigenvalue problem based on orthogonal wavelets are described, and possible choices of tensor product bases are compared especially from an algorithmic point of view. The use of separable approximations of potential terms for applying operators efficiently is studied in detail, and estimates for the error due to this further approximation are given.

Publié le : 2012-01-01
DOI : https://doi.org/10.1051/m2an/2012009
Classification:  35B65,  35J10,  65T60,  81Q05 
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     author = {Bachmayr, Markus},
     title = {Hyperbolic wavelet discretization of the two-electron Schr\"odinger equation in an explicitly correlated formulation},
     journal = {ESAIM: Mathematical Modelling and Numerical Analysis - Mod\'elisation Math\'ematique et Analyse Num\'erique},
     volume = {46},
     year = {2012},
     pages = {1337-1362},
     doi = {10.1051/m2an/2012009},
     mrnumber = {2996330},
     zbl = {1276.65075},
     language = {en},
     url = {http://dml.mathdoc.fr/item/M2AN_2012__46_6_1337_0}
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Bachmayr, Markus. Hyperbolic wavelet discretization of the two-electron Schrödinger equation in an explicitly correlated formulation. ESAIM: Mathematical Modelling and Numerical Analysis - Modélisation Mathématique et Analyse Numérique, Tome 46 (2012) pp. 1337-1362. doi : 10.1051/m2an/2012009. http://gdmltest.u-ga.fr/item/M2AN_2012__46_6_1337_0/

[1] R.A. Adams and J.J.F. Fournier, Sobolev Spaces, Pure and Applied Mathematics Series, 2nd edition. Academic Press 140 (2003). | MR 2424078 | Zbl 1098.46001

[2] S. Agmon, Lectures on Exponential Decay of Solutions of Second-Order Elliptic Equations : Bounds on Eigenfunctions of N-Body Schrödinger Operators, Mathematical Notes. Princeton University Press (1982). | MR 745286 | Zbl 0503.35001

[3] M. Bachmayr, Integration of products of Gaussians and wavelets with applications to electronic structure calculations. Preprint AICES, RWTH Aachen (2012). | MR 3095478 | Zbl 1298.65040

[4] R. Balder and C. Zenger, The solution of multidimensional real Helmholtz equations on sparse grids. SIAM J. Sci. Comput. 17 (1996) 631-646. | MR 1384255 | Zbl 0855.65111

[5] G. Beylkin, On the representation of operators in bases of compactly supported wavelets. SIAM J. Numer. Anal. 29 (1992) 1716-1740. | MR 1191143 | Zbl 0766.65007

[6] S.F. Boys and N.C. Handy, The determination of energies and wavefunctions with full electronic correlation. Proc. R. Soc. Lond. A 310 (1969) 43-61.

[7] D. Braess and W. Hackbusch, On the efficient computation of high-dimensional integrals and the approximation by exponential sums, in Multiscale, Nonlinear and Adaptive Approximation, edited by R. DeVore and A. Kunoth. Springer, Berlin, Heidelberg (2009). | MR 2648371 | Zbl 1190.65036

[8] H.-J. Bungartz, Dünne Gitter und deren Anwendung bei der adaptiven Lösung der dreidimensionalen Poisson-Gleichung. Ph.D. thesis, Technische Universität München (1992).

[9] F. Chatelin, Spectral Approximation of Linear Operators, Computer Science and Applied Mathematics. Academic Press (1983). | MR 716134 | Zbl 1214.01004

[10] S.R. Chinnamsetty, M. Espig, B.N. Khoromskij, W. Hackbusch and H.-J. Flad, Tensor product approximation with optimal rank in quantum chemistry. J. Chem. Phys. 127 (2007) 084110.

[11] A. Cohen, Numerical Analysis of Wavelet Methods. Stud. Math. Appl. 32 (2003). | MR 1990555 | Zbl 1038.65151

[12] W. Dahmen and C.A. Micchelli, Using the refinement equation for evaluating integrals of wavelets. SIAM J. Numer. Anal. 30 (1993) 507-537. | MR 1211402 | Zbl 0773.65006

[13] I. Daubechies, Orthonormal bases of compactly supported wavelets. Commun. Pure Appl. Math. 41 (1988) 909-996. | MR 951745 | Zbl 0644.42026

[14] T.J. Dijkema, C. Schwab and R. Stevenson, An adaptive wavelet method for solving high-dimensional elliptic PDEs. Constr. Approx. 30 (2009) 423-455. | MR 2558688 | Zbl 1205.65313

[15] G. Donovan, J. Geronimo and D. Hardin, Intertwining multiresolution analyses and the construction of piecewise-polynomial wavelets. SIAM J. Math. Anal. 27 (1996) 1791-1815. | MR 1416519 | Zbl 0857.42023

[16] G. Donovan, J. Geronimo and D. Hardin, Orthogonal polynomials and the construction of piecewise polynomial smooth wavelets. SIAM J. Math. Anal. 30 (1999) 1029-1056. | MR 1709786 | Zbl 0932.42021

[17] H.-J. Flad, W. Hackbusch, D. Kolb and R. Schneider, Wavelet approximation of correlated wave functions. I. Basics. J. Chem. Phys. 116 (2002) 9641-9657.

[18] H.-J. Flad, W. Hackbusch and R. Schneider, Best N-term approximation in electronic structure calculations. II. Jastrow factors. ESAIM : M2AN 41 (2007) 261. | Numdam | MR 2339628 | Zbl 1135.81029

[19] H.-J. Flad, W. Hackbusch, B.N. Khoromskij and R. Schneider, Matrix Methods : Theory, Algorithms and Applications, in Concepts of Data-Sparse Tensor-Product Approximation in Many-Particle Modelling. World Scientific (2010) 313-347. | MR 2648626 | Zbl 1214.81077

[20] S. Fournais, M. Hoffmann-Ostenhof, T. Hoffmann-Ostenhof and T. Østergaard Sørensen, Sharp regularity results for many-electron wave functions. Commun. Math. Phys. 255 (2005) 183-227. | MR 2123381 | Zbl 1075.35063

[21] L. Genovese, T. Deutsch, A. Neelov, S. Goedecker and G. Beylkin, Efficient solution of poisson's equation with free boundary conditions. J. Chem. Phys. 125 (2006) 074105.

[22] L. Genovese, A. Neelov, S. Goedecker, T. Deutsch, S.A. Ghasemi, A. Willand, D. Caliste, O. Zilberberg, M. Rayson, A. Bergman and R. Schneider, Daubechies wavelets as a basis set for density functional pseudopotential calculations. J. Chem. Phys. 129 (2008) 014109.

[23] D. Gilbarg and N.S. Trudinger, Elliptic Partial Differential Equations of Second Order, Classics in Mathematics. Springer, Berlin, Heidelberg (1998). | MR 1814364 | Zbl 1042.35002

[24] M. Griebel and J. Hamaekers, A wavelet based sparse grid method for the electronic Schrödinger equation, in Proc. of the International Congress of Mathematicians, edited by M. Sanz-Solé, J. Soria, J. Varona and J. Verdera III (2006) 1473-1506. | MR 2275738 | Zbl 1130.65134

[25] M. Griebel and J. Hamaekers, Tensor product multiscale many-particle spaces with finite-order weights for the electronic Schrödinger equation. Z. Phys. Chem. 224 (2010) 527-543. Also available as INS Preprint No. 0911.

[26] M. Griebel and S. Knapek, Optimized tensor-product approximation spaces. Constr. Approx. 16 (2000) 525. | MR 1771694 | Zbl 0969.65107

[27] M. Griebel and P. Oswald, Tensor product type subspace splittings and multilevel iterative methods for anisotropic problems. Adv. Comput. Math. 4 (1995) 171-206. | MR 1338900 | Zbl 0826.65099

[28] J. Hamaekers, Tensor Product Multiscale Many-Particle Spaces with Finite-Order Weights for the Electronic Schödinger Equation. Ph.D. thesis, Universität Bonn (2009).

[29] H. Harbrecht, R. Schneider and C. Schwab, Multilevel frames for sparse tensor product spaces. Numer. Math. 110 (2008) 199-220. | MR 2425155 | Zbl 1151.65010

[30] R.J. Harrison, G.I. Fann, T. Yanai, Z. Gan and G. Beylkin, Multiresolution quantum chemistry : basic theory and initial applications. J. Chem. Phys. 121 (2004) 11587-11598.

[31] E. Hille, A class of reciprocal functions. Ann. Math. 27 (1926) 427-464. | JFM 52.0400.02 | MR 1502747

[32] J.O. Hirschfelder, Removal of electron-electron poles from many-electron Hamiltonians. J. Chem. Phys. 39 (1963) 3145-3146.

[33] E. Hylleraas, Über den Grundzustand des Heliumatoms. Z. Phys. 48 (1929) 469. | JFM 54.1000.05

[34] T. Kato, On the eigenfunctions of many-particle systems in quantum mechanics. Commun. Pure Appl. Math. X (1957) 151-177. | MR 88318 | Zbl 0077.20904

[35] T. Kato, Perturbation Theory for Linear Operators, Grundlehren der mathematischen Wissenschaften, 2nd edition. Springer-Verlag, Berlin, Heidelberg, New York 132 (1976). | MR 407617 | Zbl 0342.47009

[36] W. Klopper, R12 methods, Gaussian geminals, in Modern Methods and Algorithms of Quantum Chemistry, edited by J. Grotendorst (2000) 181-229.

[37] H.-C. Kreusler and H. Yserentant, The mixed regularity of electronic wave functions in fractional order and weighted Sobolev spaces. Preprint 94, DFG SPP 1324 (2011). | MR 2945616 | Zbl 1258.35152

[38] H. Luo, D. Kolb, H.-J. Flad, W. Hackbusch and T. Koprucki, Wavelet approximation of correlated wave functions. II. Hyperbolic wavelets and adaptive approximation schemes. J. Chem. Phys. 117 (2002) 3625-3638.

[39] Y. Meyer and R. Coifman, Wavelets : Calderon-Zygmund and multilinear operators, Cambridge Studies in Advanced Mathematics. Cambridge University Press (1997). | MR 1456993 | Zbl 0916.42023

[40] A. Neelov and S. Goedecker, An efficient numerical quadrature for the calculation of the potential energy of wavefunctions expressed in the Daubechies wavelet basis. J. Comput. Phys. 217 (2006) 312-339. | MR 2260604 | Zbl 1102.65110

[41] M. Nooijen, and R.J. Bartlett, Elimination of Coulombic infinities through transformation of the Hamiltonian. J. Chem. Phys. 109 (1998).

[42] M. Reed and B. Simon, Methods of Modern Mathematical Physics, Analysis of Operators IV. Academic Press (1978). | MR 493422 | Zbl 0459.46001

[43] C. Schwab and R.A. Todor, Sparse finite elements for stochastic elliptic problems - higher order moments. Computing 71 (2003) 43-63. | MR 2009650 | Zbl 1044.65006

[44] R. Stevenson, On the compressibility of operators in wavelet coordinates. SIAM J. Math. Anal. 35 (2004) 1110-1132. | MR 2050194 | Zbl 1087.47012

[45] W. Sweldens, The lifting scheme : a custom-design construction of biorthogonal wavelets. Appl. Comput. Harmon. Anal. 3 (1996) 186-200. | MR 1385051 | Zbl 0874.65104

[46] S. Tenno, A feasible transcorrelated method for treating electronic cusps using a frozen Gaussian geminal. Chem. Phys. Lett. 330 (2000) 169-174.

[47] D.P. Tew and W. Klopper, New correlation factors for explicitly correlated electronic wave functions. J. Chem. Phys. 123 (2005) 074101.

[48] H. Yserentant, On the regularity of the electronic Schrödinger equation in Hilbert spaces of mixed derivatives. Numer. Math. 98 (2004) 731-759. | MR 2099319 | Zbl 1062.35100

[49] H. Yserentant, Regularity and Approximability of Electronic Wave Functions. Lect. Notes Math. 2000 (2010). | MR 2656512 | Zbl 1204.35003

[50] H. Yserentant, The mixed regularity of electronic wave functions multiplied by explicit correlation factors. ESAIM : M2AN 45 (2011) 803-824. | Numdam | MR 2817545 | Zbl pre06184109

[51] A. Zeiser, Direkte Diskretisierung der Schrödingergleichung auf dünnen Gittern. Ph.D. thesis, TU Berlin (2010).

[52] A. Zeiser, Fast matrix-vector multiplication in the sparse-grid Galerkin method. J. Sci. Comput. 47 (2010) 328-346. | MR 2793587 | Zbl 1231.65224

[53] A. Zeiser, Wavelet approximation in weighted Sobolev spaces of mixed order with applications to the electronic Schrödinger equation. To appear in Constr. Approx. (2011) DOI : 10.1007/s00365-011-9138-7. | MR 2914362 | Zbl 1253.41016

[54] H.J.A. Zweistra, C.C.M. Samson and W. Klopper, Similarity-transformed Hamiltonians by means of Gaussian-damped interelectronic distances. Collect. Czech. Chem. Commun. 68 (2003) 374-386.