Ce document est le fruit d'un long travail approuvé par le jury de ...

More documents

Recommendations

Info

140 Bibliographie 300. Chen, W. et Gordon, M. S. Energy Decomposition Analyses for Many-Body Inter- action and Applications to Water Complexes. J. Phys. Chem. 100, 14316–14328 (1996). 301. Freitag, M. A., Gordon, M. S., Jensen, J. H. et Stevens, W. J. Evaluation of charge penetration between distributed multipolar expansions. J. Chem. Phys. 112, 7300 (2000). 302. Swart, M., van Duijnen, P. T. et Snijders, J. G. A charge analysis derived from an atomic multipole expansion. J. Comput. Chem. 22, 79–88 (2000). 303. Dzyabchenko, A. V. A multipole approximation of the electrostatic potential of molecules. Russ. J. Phys. Chem. A 82, 758–766 (2008). 304. Chen, B., Xing, J. et Siepmann, J. I. Development of Polarizable Water Force Fields for Phase Equilibrium Calculations. J. Phys. Chem. B 104, 2391–2401 (2000). 305. Curutchet, C., Bofill, J. M., Hernàndez, B., Orozco, M. et Luque, F. J. Energy decomposition in molecular complexes : Implications for the treatment of polarization in molecular simulations. J. Comput. Chem. 24, 1263–1275 (2002). 306. Cieplak, P., Caldwell, J. et Kollman, P. Molecular mechanical models for organic and biological systems going beyond the atom centered two body additive approximation : aqueous solution free energies of methanol and N-methyl acetamide, nucleic acid base, and amide hydrogen bonding and chloroform/water partition coefficients of the nucleic acid bases. J. Comput. Chem. 22, 1048–1057 (2001). 307. Frisch, M. J. et al. Gaussian 03, Revision C.02 Gaussian, Inc., Wallingford, CT, 2004. 308. Schmidt, M. W., Baldridge, K. K., Boatz, J. A., Elbert, S. T., Gordon, M. S., Jensen, J. H., Koseki, S., Matsunaga, N., Nguyen, K. A., Su, S., Windus, T. L., Dupuis, M. et Montgomery, J. A. J. Comput. Chem. 14, 1347 (1993). 309. Chipot, C. et Ángyán, J. G. Continuing challenges in the parametrization of intermolecular force fields. Towards an accurate description of electrostatic and induction terms. New J. Chem. 29, 411–420 (2005). 310. Piquemal, J.-P., Gresh, N. et Giessner-Prettre, C. Improved Formulas for the Cal- culation of the Electrostatic Contribution to the Intermolecular Interaction Energy from Multipolar Expansion of the Electronic Distribution. J. Phys. Chem. A 107, 10353–10359 (2003).
Bibliographie 141 311. Cisneros, G. A., Tholander, S. N.-I., Parisel, O., Darden, T. A., Elking, D., Perera, L. et Piquemal, J.-P. Simple formulas for improved point-charge electrostatics in classical force fields and hybrid quantum mechanical/molecular mechanical embed- ding. Int. J. Quant. Chem. 108, 1905–1912 (2008). 312. Stone, A. J. dans Theoretical models of chemical bonding (éd. Maksić, H.) 103–131 (Springer–Verlag, Berlin, 1991). 313. Jorgensen, W. L., Chandrasekhar, J., Madura, J. D., Impey, R. W. et Klein, M. L. Comparison of simple potential functions for simulating liquid water. J. Chem. Phys. 79, 926–935 (1983). 314. Cieplak, P., Lybrand, T. P. et Kollman, P. A. Calculation of free energy changes in ion-water clusters using nonadditive potentials and the Monte Carlo method. J. Chem. Phys. 86, 6393–6403 (1987). 315. Mas, E. M. et Szalewicz, K. Effects of monomer geometry and basis set saturation on computed depth of water dimer potential. J. Chem. Phys. 104, 7606 (1996). 316. Hunter, C. A., Lawson, K. R., Perkins, J. et Urch, C. J. Aromatic interactions. J. Chem. Soc., Perkin Trans. 2, 651–669 (2001). 317. Chipot, C., Jaffe, R., Maigret, B., Pearlman, D. A. et Kollman, P. A. Benzene Dimer : A Good Model for - Interactions in Proteins ? A Comparison between the Benzene and the Toluene Dimers in the Gas Phase and in an Aqueous Solution. J. Am. Chem. Soc. 118, 11217–11224 (1996). 318. Shiratori, Y. et Nakagawa, S. Parametrization of calcium binding site in proteins and molecular dynamics simulation on phospholipase A2. J. Comput. Chem. 12, 717–730 (1991). 319. Soteras, I., Curutchet, C., Bidon-Chanal, A., Dehez, F., Ángyán, J. G., Orozco, M., Chipot, C. et Luque, F. J. Derivation of Distributed Models of Atomic Polarizability for Molecular Simulations. J. Chem. Theory Comput. 3, 1901–1913 (2007). 320. Celebi, N., Ángyán, J. G., Dehez, F., Millot, C. et Chipot, C. Distributed polarizabilities derived from induction energies : A finite perturbation approach. J. Chem. Phys. 112, 2709–2717 (2000). 321. Dehez, F., Soetens, J.-C., Chipot, C., Ángyán, J. G. et Millot, C. Determination of Distributed Polarizabilities from a Statistical Analysis of Induction Energies. J. Phys. Chem. A 104, 1293–1303 (2000).
Page 1 and 2:
AVERTISSEMENT Ce document est le fr
Page 3:
ÉCOLE DOCTORALE SESAMES SYNTHÈSES
Page 7 and 8:
Table des matières 1 Champs de for
Page 9 and 10:
Sommaire Chapitre 1 Champs de force
Page 11 and 12:
molécule n’ont pas la même libe
Page 13 and 14:
1.1. Champs de force additifs de pa
Page 15 and 16:
1.1. Champs de force additifs de pa
Page 17 and 18:
1.2. La polarisation explicite est-
Page 19 and 20:
Page 21 and 22:
Page 23:
1.3. Problématique et objectifs 15
Page 26 and 27:
18 Chapitre 2. Énergies intermolé
Page 28 and 29:
Page 30 and 31:
Page 32 and 33:
Page 34 and 35:
Page 36 and 37:
Page 38 and 39:
Page 40 and 41:
Page 42 and 43:
Page 45 and 46:
Chapitre 3 Développement d’un po
Page 47 and 48:
3.1. Référence quantique utilisé
Page 49 and 50:
3.2. Électrostatique 41 3.1.3 SAPT
Page 51 and 52:
3.2. Électrostatique 43 La procéd
Page 53 and 54:
3.2. Électrostatique 45 Les consta
Page 55 and 56:
3.2. Électrostatique 47 ∆ε 20.8
Page 57 and 58:
3.2. Électrostatique 49 Figure 3.2
Page 59 and 60:
Page 61 and 62:
Page 63 and 64:
3.2. Électrostatique 55 quatre poi
Page 65 and 66:
Page 67 and 68:
3.2. Électrostatique 59 charge dé
Page 70 and 71:
62 Chapitre 3. Développement d’u
Page 72 and 73:
Page 74 and 75:
Page 76 and 77:
Page 78 and 79:
Page 80 and 81:
Page 82 and 83:
Page 84 and 85:
Page 86 and 87:
Page 88 and 89:
Page 90 and 91:
Page 92 and 93:
Page 94 and 95:
Page 96 and 97:
Page 98 and 99: 90 Chapitre 3. Développement d’u
Page 108 and 109: 100 Chapitre 4. Conclusion et persp
Page 110 and 111: 102 Annexe A. Fichiers d’entrée
Page 117 and 118: Annexe B Détermination des paramè
Page 119 and 120: Annexe C Intégration des moments i
Page 121: 113 Ce qui fait que cette matrice e
Page 124 and 125: 116 Bibliographie 13. Schrödinger,
Page 126 and 127: 118 Bibliographie 35. Wang, Z.-X.,
Page 128 and 129: 120 Bibliographie 62. Jungwirth, P.
Page 130 and 131: 122 Bibliographie 87. De Courcy, B.
Page 132 and 133: 124 Bibliographie 110. Agre, P. et
Page 134 and 135: 126 Bibliographie 133. Xu, Z., Luo,
Page 136 and 137: 128 Bibliographie 160. Murdachaew,
Page 138 and 139: 130 Bibliographie 184. Karim, O. A.
Page 140 and 141: 132 Bibliographie 208. Masella, M.
Page 142 and 143: 134 Bibliographie 231. Hermida-Ram
Page 144 and 145: 136 Bibliographie 254. Sefcik, J.,
Page 146 and 147: 138 Bibliographie 277. Darden, T.,
Page 150 and 151: 142 Bibliographie 322. Chipot, C.,
Page 153: Vers une modélisation plus réalis
show all

Ce document est le fruit d'un long travail approuvé par le jury de ...

You also want an ePaper? Increase the reach of your titles

Delete template?

Save as template?