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

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

doi:10.1063/1.4967959

Cited by 6 publications

(5 citation statements)

References 33 publications

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“…As a result, a wide range of empirical correction schemes are commonly added to GGA calculations so as to produce a realistic description of the critical interactions ( 24 , 25 ). The vdW dispersion interactions described by these schemes typically involve sums over interatomic interactions, each described by the London force ( 21 , 26 – 28 ), with only small corrections. Related variants include replacing the atomic sums by electron-density integrals.…”

mentioning

confidence: 99%

Faraday cage screening reveals intrinsic aspects of the van der Waals attraction

Reimers

Dobson

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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SignificanceHow the van der Waals dispersion interaction relates to chemical electron-correlation effects presents a critical challenge to density functional theory development. Here, recently observed screening of the dispersion force between two insulating objects caused by the insertion of an intermediary graphene layer is explained in terms of Dobson’s general description of dispersion. This then provides a much-needed handle concerning how density functional approaches relate such long-range dispersion interactions to the subtleties of covalent bonding. Screening at intermediate distances appears to change the London expression from r−6 to r−7, an effect that becomes antiscreening (dispersion enhancement) at distances shorter than van der Waals contact. This provides basic insight into modern revelations that dispersion forces can outcompete covalent forces to control chemical structure.

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mentioning

confidence: 99%

Faraday cage screening reveals intrinsic aspects of the van der Waals attraction

Reimers

Dobson

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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“…Comparing eqs 13 and 9, we find that we can make our Ansatz give the correct long-wavelength response provided that we choose the constant B in χ 0 Ansatz such that (14) The factor of 1/R on the right side of eq 14 comes from the conversion between continuous "()" and discrete "[ ]" Fourier transforms. Putting eqs 9 and 13 into eq 14 gives (15) So, eq 16 becomes (16) This agrees with the known 1D metallic response when q → 0 but is not necessarily correct for larger q. However, the principal "Type-C" effects of metallicity on dispersion interactions come from the long-wavelength metallic response, and so, the present model should be appropriate.…”

Section: ■ General Form Of the Mbd + C Approachmentioning

confidence: 57%

“…In low-dimensional metals, this gives rise to gapless plasmon excitations that are not captured by the MBD theory. Coupling between these plasmons results in unusual power law decays of the dispersion interaction between low-dimensional metals, sometimes termed “Type-C” dispersion interactions. − Similar anomalous dispersion interactions have been proposed in a variety of other cases with a small or zero electronic energy gap. − The Type-C interactions are not captured by standard MBD calculations. ,, …”

Section: Introductionmentioning

confidence: 93%

MBD + C: How to Incorporate Metallic Character into Atom-Based Dispersion Energy Schemes

Dobson,

Ambrosetti

2023

J. Chem. Theory Comput.

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“…Recent studies have suggested that Type-B non-additivity can also be interpreted as a manifestation of electric many-body effects. 17 Type-C non-additivity is observed in low-dimensional nanostructures or metallic systems, where long-range charge ŕuctuations result in dispersion interactions with non-standard power laws, with a smaller magnitude of the exponent of R. 18 Semiclassical models with pairwise expressions, such as Eq. ( 1), including Grimme's DFT+Dn (n = 1, 2, 3, 4) schemes, [19][20][21][22][23] Tkatchenko and Scheffler (TS) method, 13 the exchange-hole dipole moment (XDM) method by Becke and Johnson, 12,24,25 and the localresponse dispersion (LRD) model by Sato and Nakai, [26][27][28] consider type-A non-additive dispersion interactions.…”

Section: Introductionmentioning

confidence: 99%

The significance of fluctuating charges for molecular polarizability and dispersion coefficients

Cheng,

Verstraelen

2023

The Journal of Chemical Physics

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The influence of fluctuating charges or charge flow on the dynamic linear response properties of isolated molecules from the TS42 database is evaluated, with particular emphasis on dipole polarizability and C6 dispersion coefficients. Two new descriptors are defined to quantify the charge-flow contribution to response properties, making use of the recoupled dipole polarizability to separate isotropic and anisotropic components. Molecular polarizabilities are calculated using the “frequency-dependent atom-condensed Kohn–Sham density functional theory approximated to second order,” i.e., the ACKS2ω model. With ACKS2ω, the charge-flow contribution can be constructed in two conceptually distinct ways that appear to yield compatible results. The charge-flow contribution is significantly affected by molecular geometry and the presence of polarizable bonds, in line with previous studies. We show that the charge-flow contribution qualitatively reproduces the polarizability anisotropy. The contribution to the anisotropic C6 coefficients is less pronounced but cannot be neglected. The effect of fluctuating charges is only negligible for small molecules with at most one non-hydrogen atom. They become important and sometimes dominant for larger molecules or when highly polarizable bonds are present, such as conjugated, double, or triple bonds. Charge flow contributions cannot be explained in terms of individual atomic properties because they are affected by non-local features such as chemical bonding and geometry. Therefore, polarizable force fields and dispersion models can benefit from the explicit modeling of charge flow.

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

Cited by 6 publications

References 33 publications

Faraday cage screening reveals intrinsic aspects of the van der Waals attraction

Faraday cage screening reveals intrinsic aspects of the van der Waals attraction

MBD + C: How to Incorporate Metallic Character into Atom-Based Dispersion Energy Schemes

The significance of fluctuating charges for molecular polarizability and dispersion coefficients

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