Dispersion interaction in hydrogen-chain models

Liu, Ru-Fen; Ángyán, János G.; Dobson, John F.

doi:10.1063/1.3563596

Cited by 27 publications

(33 citation statements)

References 46 publications

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“…The leading term in the infinite stack result (51) is twice the two-layer result (40), which makes sense because in the infinite stack each layer has two nearest-neighbour layers.…”

Section: Inter-layer Rpa Interactions In An Infinite Uniform Stacmentioning

confidence: 99%

“…Putting this into (39), for example, we obtain a sub-asymptotic correction to (40) for the cross-correlation energy of two identical insulating layers…”

Section: A Formal Next-order Correction To Inter-layer Correlation Ementioning

confidence: 99%

“…At moderate inter-layer distances D the inverse exponential e −2QD , from the Coulomb potential in correlation energy expressions such as (40), creates a natural cutoff ensuring that the unphysical large-Q behaviour of our small-Q resonse expressions (69,70) does not contribute significantly to the energy. However, as the two layers approach their natural binding distance D 0 this exponential decay is insufficient for the task, and we need to recognize that the Q integrations should at least be restricted to the first Brillouin zone.…”

Section: Including O(q 2 ) Corrections In the Layer Responsementioning

confidence: 99%

“…In particular, the RPA approach correctly describes the very long-wavelength charge fluctuations not captured in pairwise theories, but responsible for anomalous long-ranged van der Waals interactions 25 . These differences from the pairwise predictions are manifested in both the dependence of the energy on layer spacing D 25,40 and, for finite systems, on the number of atoms N 27,29 . Furthermore, the RPA (without extensions) has been shown 33 to give simultaneously a good description of the layer spacing, the breathing elastic constant C 33 and the layer binding energy of graphite, a task that proved elusive with other methods.…”

Section: Introductionmentioning

confidence: 99%

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Layer response theory: Energetics of layered materials from semianalytic high-level theory

2016

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We present a readily computable semi-analytic "Layer response theory" (LRT) for analysis of cohesive energetics involving two-dimensional layers such as BN or graphene. The theory approximates the Random Phase Approximation (RPA) correlation energy. Its RPA character ensures that the energy has the correct van der Waals asymptotics for well-separated layers, in contrast to simple pairwise atom-atom theories, which fail qualitatively for layers with zero electronic energy gap. At the same time our theory is much less computationally intensive than the full RPA energy. It also gives accurate correlation energies near to the binding minimum, in contrast to Lifshitz-type theory. We apply our LRT theory successfully to graphite and to BN, and to a graphene-BN heterostructure.

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“…The leading term in the infinite stack result (51) is twice the two-layer result (40), which makes sense because in the infinite stack each layer has two nearest-neighbour layers.…”

Section: Inter-layer Rpa Interactions In An Infinite Uniform Stacmentioning

confidence: 99%

“…Putting this into (39), for example, we obtain a sub-asymptotic correction to (40) for the cross-correlation energy of two identical insulating layers…”

Section: A Formal Next-order Correction To Inter-layer Correlation Ementioning

confidence: 99%

Section: Including O(q 2 ) Corrections In the Layer Responsementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Layer response theory: Energetics of layered materials from semianalytic high-level theory

2016

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“…For the one-dimensional case of two parallel metallic nanotubes at separation Z, the conventional summed result is E (Z) ∝ −Z −5 whereas more acurate microscopic approaches yield E (Z) ∝ −Z −2 (ln |z|) −3/2 [6], [4], [7] [8] in the electromagnetlicaly non-retarded regime. These 2D and 1D nanosystems were argued [4], [9], [10], [11] to exhibit unconvential vdW powers because of their zero electronic energy gap and their low dimensionality (limiting the influence of coulomb screening). In a recent work [9], these unconventional dispersion power laws were attributed to "Type-C vdW non-additivity" arising from the de-localization (hopping) of electrons between nuclear centres, i.e.…”

mentioning

confidence: 99%

Spooky correlations and unusual van der Waals forces between gapless and near-gapless molecules

Dobson

Savin

Ángyán

et al. 2016

The Journal of Chemical Physics

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We consider the zero-temperature van der Waals interaction between two molecules, each of which has a zero or near-zero electronic gap between a groundstate and the first excited state, using a toy model molecule ( equilateral H 3 ) as an example. We show that the van der Waals energy between two groundstate molecules falls off as D −3 instead of the usual D −6 dependence, when the molecules are separated by distance D. We show that this is caused by perfect "spooky" correlation between the two fluctuating electric dipoles. The phenomenon is related to, but not the same as, the "resonant" interaction between an electronically excited and a groundstate molecule introduced by Eisenschitz and London in 1930. It is also an example of "type C van der Waals nonadditivity" recently introduced by one of us ( Int. J. Quantum Chem. 114, 1157Chem. 114, (2014). Our toy molecule H 3 is not stable, but symmetry considerations suggest that a similar vdW phenomenon may be observable, despite Jahn-Teller effects, in molecules with discrete rotational symmetry and broken inversion symmetry, such as certain metal atom clusters. The motion of the nuclei will need to be included for a definitive analysis of such cases, however.

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Current Understanding of Van der Waals Effects in Realistic Materials

Tkatchenko

2014

Adv Funct Materials

122

126

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Van der Waals (vdW) interactions arise from correlated electronic fluctuations in matter and are therefore present in all materials. Our understanding of these relatively weak yet ubiquitous quantum mechanical interactions has improved significantly during the last decade. This understanding has been largely driven by the development of efficient methods that now enable the modeling of vdW interactions in many realistic materials of interest for fundamental scientific questions and technological applications. In this work, we briefly review the physics behind the currently available vdW methods, highlighting their applications to a wide variety of materials, ranging from molecular assemblies to solids with and without defects, nanostructures of varying size and dimensionality, as well as interfaces between inorganic and organic materials. The origin of collective vdW interactions in materials is discussed using the concept of topological dipole waves.We focus on the important observation that the full many-body treatment of vdW interactions becomes crucial in the investigation and characterization of materials with increasing complexity, especially when studying their response properties, including vibrational, mechanical, and optical phenomena. Despite significant recent advances, many challenges still remain in the development of accurate and efficient methods for treating vdW interactions that will be broadly applicable to the modeling of functional materials at all relevant length and time scales. * tkatchenko@fhi-berlin.mpg.de

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Dispersion interaction in hydrogen-chain models

Cited by 27 publications

References 46 publications

Layer response theory: Energetics of layered materials from semianalytic high-level theory

Layer response theory: Energetics of layered materials from semianalytic high-level theory

Spooky correlations and unusual van der Waals forces between gapless and near-gapless molecules

Current Understanding of Van der Waals Effects in Realistic Materials

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