Molecular Geometry Impact on Deep Learning Predictions of Inverted Singlet–Triplet Gaps

Barneschi, Leonardo; Rotondi, Leonardo; Padula, Daniele

doi:10.1021/acs.jpca.4c00172

J. Phys. Chem. A

2024

DOI: 10.1021/acs.jpca.4c00172

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Molecular Geometry Impact on Deep Learning Predictions of Inverted Singlet–Triplet Gaps

Leonardo Barneschi,

Leonardo Rotondi,

Daniele Padula

Abstract: We present a deep learning model able to predict excited singlet−triplet gaps with a mean absolute error (MAE) of ≈20 meV to obtain potential inverted singlet−triplet (IST) candidates. We exploit cutting-edge spherical message passing graph neural networks designed specifically for generating 3D graph representations in molecular learning. In a nutshell, the model takes as input a list of unsaturated heavy atom Cartesian coordinates and atomic numbers, producing singlet−triplet gaps as output. We exploited ava… Show more

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2024

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Cited by 4 publications

References 73 publications

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Singlet–Triplet Inversion in Triangular Boron Carbon Nitrides

Bedogni,

Di Maiolo

2024

J. Chem. Theory Comput.

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The discovery of singlet–triplet (ST) inversion in some π-conjugated triangle-shaped boron carbon nitrides is a remarkable breakthrough that defies Hund’s first rule. Deeply rooted in strong electron–electron interactions, ST inversion has garnered significant interest due to its potential to revolutionize triplet harvesting in organic LEDs. Using the well-established Pariser–Parr–Pople model for correlated electrons in π-conjugated systems, we employ a combination of CISDT and restricted active space configuration interaction calculations to investigate the photophysics of several triangular boron carbon nitrides. Our findings reveal that ST inversion in these systems is primarily driven by a network of alternating electron-donor and electron-acceptor groups in the molecular rim, rather than by the triangular molecular structure itself.

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Singlet–Triplet Inversion in Triangular Boron Carbon Nitrides

Bedogni,

Di Maiolo

2024

J. Chem. Theory Comput.

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Excited-State Hund’s Rule Violations in Bridged [10]- and [14]Annulene Perimeters

Blaskovits,

Corminboeuf,

Garner

2024

J. Phys. Chem. A

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Molecules with Hund's rule violations between low-lying singlet and triplet states may enable a new generation of fluorescent emitters. However, only a few classes of molecules are known with this property at the current time. Here, we use a high-throughput screening algorithm of the FORMED database to uncover a class of compounds where the first excited state violates Hund's rule. We examine this class of bridged [10]-and [14]annulene perimeters with saturated bridges, and relate them to known conjugated polycyclic systems with Hund's rule violations. Despite the structural similarities with the related class of nonalternant polycyclic hydrocarbons, the mechanism is different in these bridged annulene perimeters. Here, two molecular orbital configurations contribute to each excited state. Consequently, a Hund's rule violation can only be unambiguously assigned based on the symmetry of the lowest excited singlet and triplet states. With several examples of synthetically realistic molecules, the class of bridged [10]-and [14]annulenes thus provides a structural link between the known nonalternant and alternant (azaphenalene) classes of molecules violating Hund's rule. These design principles may open avenues for the identification of new types of molecules where the order of the photophysically relevant first excited singlet and triplet states are inverted.

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Turning on Organic Radical Emitters

Dubbini,

Bonvini,

Savi

et al. 2024

J. Phys. Chem. C

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Radical emitters have attracted considerable interest because of their potential to surpass the limitations of singlet emitters due to spin statistics, thereby revolutionizing organic LEDs. Utilizing the well-known Pariser−Parr−Pople (PPP) model for correlated electrons in π-conjugated systems, we perform extended configuration interaction with single, double, and triple excitations (XCISDT) to explore the photophysics of various phenalenyl radicals differently decorated with nitrogen atoms. By introducing the PPP particle-hole difference operator and connecting it to DFT calculations, we offer a new tool for predicting highly emissive organic radicals using ground-state quantum chemistry methods.

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Molecular Geometry Impact on Deep Learning Predictions of Inverted Singlet–Triplet Gaps

Cited by 4 publications

References 73 publications

Singlet–Triplet Inversion in Triangular Boron Carbon Nitrides

Singlet–Triplet Inversion in Triangular Boron Carbon Nitrides

Excited-State Hund’s Rule Violations in Bridged [10]- and [14]Annulene Perimeters

Turning on Organic Radical Emitters

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