2009
DOI: 10.1021/jp811519x
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Accurate Methods for Large Molecular Systems

Abstract: Three exciting new methods that address the accurate prediction of processes and properties of large molecular systems are discussed. The systematic fragmentation method (SFM) and the fragment molecular orbital (FMO) method both decompose a large molecular system (e.g., protein, liquid, zeolite) into small subunits (fragments) in very different ways that are designed to both retain the high accuracy of the chosen quantum mechanical level of theory while greatly reducing the demands on computational time and re… Show more

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Cited by 193 publications
(228 citation statements)
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“…Larger molecules such as phenylalanine can be simplified when they are reduced into smaller fragments or groups of structurally related molecules and their intramolecular interactions. 4,5 Several excellent reviews discussed a range of aromatic interactions in chemical and biological systems. [5][6][7] These interactions include aiding the stability of DNA base pair stacking and determining molecular recognition in drug docking.…”
Section: Introductionmentioning
confidence: 99%
“…Larger molecules such as phenylalanine can be simplified when they are reduced into smaller fragments or groups of structurally related molecules and their intramolecular interactions. 4,5 Several excellent reviews discussed a range of aromatic interactions in chemical and biological systems. [5][6][7] These interactions include aiding the stability of DNA base pair stacking and determining molecular recognition in drug docking.…”
Section: Introductionmentioning
confidence: 99%
“…In this case, the system generates a negative potential on the boundary. Hence, the boundary condition (22) implies that the anion must induce a distribution of positive image charge in the environment such that the total potential vanishes on the cavity surface. Naturally, this positive charge stabilizes the negative charge of the anion.…”
Section: Energy Calculations With Fixed (S) =mentioning
confidence: 99%
“…18 The idea of partitioning a large system into subsystems to aid computation or understanding stretches back to the early works of Löwdin 19 and McWeeny, 20 where they introduced a rigorous mathematical framework for separating (localized) degrees of freedom in large-scale electronic structure calculations. Recently, there has been considerable interest in a practical, simplified version of these ideas known as the fragment molecular orbital (FMO) method [21][22][23][24] which starts with the assumption that there are localized groups of electrons which interact with the other groups (to first order) only classically. A cluster expansion is used to correct for the many-body interaction energies after the fragment wavefunctions have converged.…”
Section: Introductionmentioning
confidence: 99%
“…Recently, a large number of fragment-based methods [1][2][3][4][5][6][7][8][9][10] have been suggested in order to facilitate computing large systems with quantum-mechanical methods. The fragment molecular orbital ͑FMO͒ [11][12][13] method is based on dividing the system into pieces ͑fragments͒ and performing ab initio calculations on fragments, their pairs, and, optionally, triples.…”
Section: Introductionmentioning
confidence: 99%
“…A number of wave functions have been interfaced with FMO, [14][15][16][17][18][19] an interfragment interaction energy analysis has been developed, 20 and geometry optimizations 21 and molecular dynamics 22 can be performed; FMO has been applied to a variety of systems. 10,12 FMO from the very beginning has had the effect of the environment included in all fragment calculations by the means of the electrostatic potential ͑ESP͒ describing the environment ͑the embedding potential͒, which in FMO consists of the one and two electron parts, describing the nucleuselectron and electron-electron Coulomb interactions, respectively. It has also been the distinct general trend in the development of many fragment methods to achieve an improvement by including the effect of the environment in the fragment calculations, usually in the form of the oneelectron Coulomb terms ͑i.e., point charges͒.…”
Section: Introductionmentioning
confidence: 99%