Density-functional expansion methods: Generalization of the auxiliary basis

Giese, Timothy J.; York, Darrin M.

doi:10.1063/1.3587052

Cited by 12 publications

(37 citation statements)

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“…When reading those works [ 56 -58 ], a reader may misconstrue the use of a third-order expansion to mean that the underlying problem giving rise to the quadratic behavior of the hardness is a premature truncation of the Taylor series to second-order. Our previous works suggest that this is not the case [26,32]. The pure-quadratic response self-energy of an isolated atom, as modeled by DFTB2, results only from having limited the auxiliary basis so completely that both the diffuse and tightlybound electron densities are represented by the same spatial function, and thus contribute equally to the self-energy.…”

Section: Generalization Of the Auxiliary Basismentioning

confidence: 99%

“…Table 1 compares the geometry optimized bond, angle, dipole moment, and relative energy errors of various PBE/6-31G*-based models to standard PBE/6-31G*. The statistics include results from 52 molecules [ 81 ] taken from the G2/97 neutral small molecule test set [ 82 ], which were also used in our previous VE studies [26,32]. For the purpose of discussing the generalization of the auxiliary basis, the reader should compare VEJ/1S(M) and VEJ/2P,3D,4F to VEJ, and note how well VEJ compares to VE.…”

Section: Computational Detailsmentioning

confidence: 99%

“…For the purpose of discussing the generalization of the auxiliary basis, the reader should compare VEJ/1S(M) and VEJ/2P,3D,4F to VEJ, and note how well VEJ compares to VE. The parametrization of the VEJ/2P,3D,4F auxiliary basis Slater exponents is described elsewhere [32]. Table 1 is used to compare the errors of the VE1, VE1S, and VE1W models, all of which are variations of the VE0 model.…”

Section: Computational Detailsmentioning

confidence: 99%

“…The VEJ model, where the AO products are represented with an auxiliary basis of Gaussian multipole expansions (GME) (32) whose primitive contraction coefficients c γ , and exponents ζ γ (ξ), have been chosen to mimic a Slater multipole-like expansion with exponent ξ. The notation 2P,3D,4F indicates that period 1 elements use two GMEs of l max = 1, each corresponding to one of two Slater exponents; period 2 elements use three GMEs of l max = 2; and period 3 elements use four GMEs of l max = 3.…”

Section: Vej/2p3d4fmentioning

confidence: 99%

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Density-functional expansion methods: grand challenges

Giese¹,

York²

2012

Highlights in Theoretical Chemistry

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We discuss the source of errors in semiempirical density functional expansion (VE) methods. In particular, we show that VE methods are capable of well-reproducing their standard Kohn-Sham density functional method counterparts, but suffer from large errors upon using one or more of these approximations: the limited size of the atomic orbital basis, the Slater monopole auxiliary basis description of the response density, and the one-and two-body treatment of the coreHamiltonian matrix elements. In the process of discussing these approximations and highlighting their symptoms, we introduce a new model that supplements the second-order density-functional tight-binding model with a self-consistent charge-dependent chemical potential equalization correction; we review our recently reported method for generalizing the auxiliary basis description of the atomic orbital response density; and we decompose the first-order potential into a summation of additive atomic components and many-body corrections, and from this examination, we provide new insights and preliminary results that motivate and inspire new approximate treatments of the core-Hamiltonian.

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Section: Generalization Of the Auxiliary Basismentioning

confidence: 99%

Section: Computational Detailsmentioning

confidence: 99%

Section: Computational Detailsmentioning

confidence: 99%

Section: Vej/2p3d4fmentioning

confidence: 99%

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Density-functional expansion methods: grand challenges

Giese¹,

York²

2012

Highlights in Theoretical Chemistry

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“…Essentially, the same idea was used more recently by Giese and York. [52] In the PARI scheme, we exploit locality in a manner similar to that of Baerends et al except that we approximate the electron integrals ðabjcdÞ individually for each jcdÞ rather than its total Coulomb interaction ðabjqÞ. Also, we apply the robust Dunlap correction.…”

Section: The Pari Methodsmentioning

confidence: 99%

Attractive electron–electron interactions within robust local fitting approximations

et al. 2013

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An analysis of Dunlap's robust fitting approach reveals that the resulting two-electron integral matrix is not manifestly positive semidefinite when local fitting domains or non-Coulomb fitting metrics are used. We present a highly local approximate method for evaluating four-center two-electron integrals based on the resolution-of-the-identity (RI) approximation and apply it to the construction of the Coulomb and exchange contributions to the Fock matrix. In this pair-atomic resolutionof-the-identity (PARI) approach, atomic-orbital (AO) products are expanded in auxiliary functions centered on the two atoms associated with each product. Numerical tests indicate that in 1% or less of all Hartree-Fock and Kohn-Sham calculations, the indefinite integral matrix causes nonconvergence in the self-consistent-field iterations. In these cases, the two-electron contribution to the total energy becomes negative, meaning that the electronic interaction is effectively attractive, and the total energy is dramatically lower than that obtained with exact integrals. In the vast majority of our test cases, however, the indefiniteness does not interfere with convergence. The total energy accuracy is comparable to that of the standard Coulomb-metric RI method. The speed-up compared with conventional algorithms is similar to the RI method for Coulomb contributions; exchange contributions are accelerated by a factor of up to eight with a triple-zeta quality basis set. A positive semidefinite integral matrix is recovered within PARI by introducing local auxiliary basis functions spanning the full AO product space, as may be achieved by using Cholesky-decomposition techniques. Local completion, however, slows down the algorithm to a level comparable with or below conventional calculations.

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Indolizine‐Based Donors as Organic Sensitizer Components for Dye‐Sensitized Solar Cells

Huckaba

Giordano

McNamara

et al. 2014

Advanced Energy Materials

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Strong electron‐donating functionality is desirable for many organic donor‐π‐bridge‐acceptor (D‐π‐A) dyes. Strategies for increasing the electron‐donating strength of common nitrogen‐based donors include planarization of nitrogen substituents and the use of low resonance‐stabilized energy aromatic ring‐substituted nitrogen atoms. Organic donor motifs based on the planar nitrogen containing heterocycle indolizine are synthesized and incorporated into dye‐sensitized solar cell (DSC) sensitizers. Resonance active substitutions at several positions on indolizine in conjugation with the D‐π‐A π‐system are examined computationally and experimentally. The indolizine‐based donors are observed to contribute electron density with strengths greater than triarylamines and diarylamines, as evidenced by UV/Vis, IR absorptions, and oxidation potential measurements. Fluorescence lifetime studies in solution and on TiO2 yield insights in understanding the performance of indolizine‐based dyes in DSC devices.

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Density-functional expansion methods: Generalization of the auxiliary basis

Cited by 12 publications

References 65 publications

Density-functional expansion methods: grand challenges

Density-functional expansion methods: grand challenges

Attractive electron–electron interactions within robust local fitting approximations

Indolizine‐Based Donors as Organic Sensitizer Components for Dye‐Sensitized Solar Cells

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