Assessing challenging intra‐ and <scp>inter‐molecular charge‐transfer</scp> excitations energies with <scp>double‐hybrid</scp> density functionals

Brémond, Éric; Ottochian, Alistar; Pérez-Jiménez, Ángel J.; Ciofini, Ilaria; Scalmani, Giovanni; Frisch, Michael J.; Sancho‐García, Juan Carlos; Adamo, Carlo

doi:10.1002/jcc.26517

Cited by 28 publications

(34 citation statements)

References 111 publications

(189 reference statements)

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“…That contribution is known to be an individual quantity for each functional, molecule, and excited state, which in fact determines the final quality of an excitation energy calculated by a double-hybrid density functional. [97][98][99] Figure 5 presents the magnitude of that term for the standard B2-PLYP, PBE-QIDH, and PBE0-2 expressions, which differ in their a c weight (a c = 0.27, a c = 1/3, and a c = 1/2, respectively) and for both excitation energies (S 1 ← S 0 and T 1 ← S 0 ) for the whole set of systems. The first observation is how the magnitude of the correction for S 1 ← S 0 excitation energies increase with a c , as expected, ranging from -0.24 to -0.71 eV for B2-PLYP, from -0.26 to -0.76 eV for PBE-QIDH, and from -0.38 to -1.09 eV for PBE0-2.…”

Section: Individual Overall Performancesmentioning

confidence: 99%

Violation of Hund’s rule in molecules: Predicting the excited-state energy inversion by TD-DFT with double-hybrid methods

Sancho‐García

Brémond

Ricci

et al. 2022

The Journal of Chemical Physics

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The energy difference (∆E ST ) between the lowest singlet (S 1 ) and triplet (T 1 ) excited state of a set of azaphenalene compounds, which is theoretically and experimentally known to violate Hund's rule giving rise to the inversion of the order of those states, is calculated here with a family of double-hybrid density functionals. That excited-state inversion is known to be very challenging to reproduce for TD-DFT employing common functionals, e.g. hybrid or range-separated expressions, but not for wavefunction methods due to the inclusion of higher-thansingle excitations. Therefore, we explore here if the last developed family of density functional expressions (i.e., double-hybrid models) is able to provide not only the right excited-state energy order but also accurate ∆E ST values, thanks to the approximate inclusion of double excitations within these models. We herein employ standard double-hybrid (B2-PLYP, PBE-QIDH, and PBE0-2), range-separated (ωB2-PLYP and RSX-QIDH), spin-scaled (SCS/SOS-B2PLYP21, SCS-PBE-QIDH, and SOS-PBE-QIDH), and range-separated spin-scaled (SCS/SOS-ωB2-PLYP, SCS-RSX-QIDH, and SOS-RSX-QIDH) expressions, to systematically assess the influence of the ingredients entering into the formulation while concomitantly providing insights for their accuracy.

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Section: Individual Overall Performancesmentioning

confidence: 99%

Violation of Hund’s rule in molecules: Predicting the excited-state energy inversion by TD-DFT with double-hybrid methods

Sancho‐García

Brémond

Ricci

et al. 2022

The Journal of Chemical Physics

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“…[58][59][60][61][62][63][64] Prior to mid-2020, most of the BLYPbased global DHDFAs studies had been carried out using the full TD-DHDFA scheme, whereas most of the studies using PBE-based global DHDFAs had used the TDA-DHDFA scheme, instead. 37,38,[65][66][67][68][69][70][71][72][73][74][75] Moreover, all previous benchmark studies and applications had been limited to singlet-singlet excitations, except for the original work by Grimme and Neese from 2007, 18 leaving out other spin multiplicities of crucial relevance, such as triplet excitations, most likely due to the lack of a code that could handle those transitions. For this reason, we assessed for the first time singlet-singlet and singlet-triplet excitations with global-and LC-DHDFAs based on both BLYP and PBE expressions for the underlying exchange-correlation functional and compared them with hybrid functionals.…”

Section: Introductionmentioning

confidence: 99%

Time-Dependent Long-Range-Corrected Double-Hybrid Density Functionals with Spin-Component and Spin-Opposite Scaling: A Comprehensive Analysis of Singlet–Singlet and Singlet–Triplet Excitation Energies

Casanova-Páez

Goerigk

2021

J. Chem. Theory Comput.

171

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Following the work on spin-component and spin-opposite scaled (SCS/SOS) global double hybrids for singlet-singlet excitations by Schwabe and Goerigk [J. Chem. Theory Comput. 2017, 13, 4307-4323] and our own works on new long-range corrected (LC) double hybrids for singlet-singlet and singlet-triplet excitations [J. Chem. Theory Comput. 2019, 15, 4735-4744; J. Chem. Phys. 2020, 153, 064106], we present new LC double hybrids with SCS/SOS that demonstrate further improvement over previously published results and methods. We introduce new unscaled and scaled versions of different global and LC double hybrids based on Becke88 or PBE exchange combined with LYP, PBE or P86 correlation. For singlet-singlet excitations, we cross-validate them on six benchmark sets that cover small to medium-sized chromophores with different excitation types (local valence, Rydberg, and charge transfer). For singlet-triplet excitations, we perform the cross-validation on three different benchmark sets following the same analysis as in our previous work in 2020. In total, 203 unique excitations are analyzed. Our results confirm and extend those of Schwabe and Goerigk regarding the superior performance of SCS and SOS variants compared to their unscaled parents by decreasing mean absolute deviations, root-mean-square deviations or error spans by more than half and bringing absolute mean deviations closer to zero. Our SCS/SOS variants show to be highly efficient and robust for the computation of vertical excitation energies, which even outperform specialized double hybrids that also contain an LC in their perturbative part. In particular, our new SCS/SOS-ωPBEPP86 and SCS/SOS-ωB88PP86 functional are four of the most accurate and robust methods tested in this work and we fully recommend them for future applications. However, if the relevant SCS and SOS algorithms are not available to the user, we suggest ωB88PP86 as the best unscaled method in this work.

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“…Next, we study CT excitations, which present a well-known problem even in this class of methods. ,, The numerical results for the CT benchmark set of Szalay et al are presented in Figure . Inspecting the errors, the advantages of the range separation become clear since only these functionals can provide acceptable results compared to the wave-function-based methods.…”

Section: Resultsmentioning

confidence: 99%

Spin-Scaled Range-Separated Double-Hybrid Density Functional Theory for Excited States

Mester

Kállay

2021

J. Chem. Theory Comput.

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Our recently presented range-separated (RS) double-hybrid (DH) time-dependent density functional approach [J. Chem. Theory Comput. 17, 927 (2021)] is combined with spin-scaling techniques. The proposed spin-component-scaled (SCS) and scaled-opposite-spin (SOS) variants are thoroughly tested for almost 500 excitations including the most challenging types. This comprehensive study provides useful information not only about the new approaches but also about the most prominent methods in the DH class. The benchmark calculations confirm the robustness of the RS-DH ansatz, while several tendencies and deficiencies are pointed out for the existing functionals. Our results show that the SCS variant consistently improves the results, while the SOS variant preserves the benefits of the original RS-DH method reducing its computational expenses. It is also demonstrated that, besides our approaches, only the nonempirical functionals provide balanced performance for general applications, while particular methods are only suggested for certain types of excitations.

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Assessing challenging intra‐ and inter‐molecular charge‐transfer excitations energies with double‐hybrid density functionals

Cited by 28 publications

References 111 publications

Violation of Hund’s rule in molecules: Predicting the excited-state energy inversion by TD-DFT with double-hybrid methods

Violation of Hund’s rule in molecules: Predicting the excited-state energy inversion by TD-DFT with double-hybrid methods

Time-Dependent Long-Range-Corrected Double-Hybrid Density Functionals with Spin-Component and Spin-Opposite Scaling: A Comprehensive Analysis of Singlet–Singlet and Singlet–Triplet Excitation Energies

Spin-Scaled Range-Separated Double-Hybrid Density Functional Theory for Excited States

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