KITE: high-performance accurate modelling of electronic structure and response functions of large molecules, disordered crystals and heterostructures

M., João, Simão; Anđelković, Miša; Covaci, Lucian; Rappoport, Tatiana G.; Lopes, J. M. Viana Parente; Ferreira, Aires

doi:10.1098/rsos.191809

Cited by 50 publications

(49 citation statements)

References 112 publications

(299 reference statements)

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“…For calculating the OH conductivity σ z OH , we consider j α ≡ j x and j β as the orbital current density operator j β ≡ j s y = 1 2 { z , v y }, where z is the z component of the atomic angular momentum operator. Our transport calculations are performed in real-space with the use of a modified version of the quantum transport software KITE [28,29] based on Chebyshev polynomial expansions [30]. This method is highly efficient for computations of Hall response in 2D systems [31][32][33][34][35].…”

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confidence: 99%

Orbital Hall insulating phase in transition metal dichalcogenide monolayers

et al. 2020

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We show that H-phase transition metal dichalcogenides (TMDs) monolayers such as MoS2 and WSe2, are orbital Hall insulators. They present very large orbital Hall conductivity plateaus in their semiconducting gap, where the spin Hall conductivity vanishes. This novel effect does not rely on conducting edge channels as in the case of quantum spin Hall insulators. Our results open the possibility of using TMDs for orbital current injection and orbital torque transfers that surpass their spin-counterparts in spin-orbitronics devices. The orbital Hall effect (OHE) in TMD monolayers occurs even in the absence of spin-orbit coupling. It can be linked to exotic momentum-space orbital textures, analogous to the spin-momentum locking in 2D Dirac fermions that arise from a combination of orbital attributes and lattice symmetry.

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confidence: 99%

Orbital Hall insulating phase in transition metal dichalcogenide monolayers

et al. 2020

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“…5, characterizing spectral, topological and localization properties. The density of states (DOS) was calculated for finite systems containing more than 10 6 sites using the Kite quantum transport software that has a very efficient implementation of the kernel polynomial method (KPM) [28]. The topological phase diagram was obtained by computing the Chern number through the Coupling Matrix Method introduced in Ref.…”

Section: Model and Methodsmentioning

confidence: 99%

Instability of QBC systems to Topological Anderson Insulating phases

Sobrosa,

Gonçalves,

Castro

2021

Preprint

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Here we study the instabilities of a quadratic band crossing system to Chern insulating states and uncorrelated disorder. We determined the phase diagram in the plane of topological mass versus disorder strength, characterizing the system with respect to spectral, localization and topological properties. In the clean limit, the system has two gapped Chern insulating phases with Chern numbers C = ±2, and a trivial phase with C = 0. For finite disorder, the quadratic band crossing points are unstable to emergent gapless Chern insulating phases with C = ±1, not present in the clean limit. These phases occupy a considerable region of the phase diagram for intermediate disorder and show features of topological Anderson insulators: it is possible to reach them through disorder-driven transitions from trivial phases.

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“…( 1), is a spectral quantity similar to the density of states ρ(E) = n δ(E − E n ). For such quantities, highly efficient numerical approaches have been recently developed which avoid the need to diagonalize large Hamiltonian matrices [38][39][40][41]. To harness these spectral methods, we write the hot-carrier rate as…”

Section: A Formalismmentioning

confidence: 99%

“…As a consequence, they cannot describe the evolution of interband and intraband contributions to hot carrier generation as function of nanoparticle size, nor do they shed light on the role played by d-electrons in photocatalysis [36,37]. In this paper, we use novel atomistic electronic structure techniques based on an accurate tight-binding Hamiltonian which includes d-states and reproduces the band structure of ab initio calculations [38][39][40][41][42] to study hot-carrier generation rates in large nanoparticles of silver, gold and copper with diameters up to 30 nm. We find that hot-carrier generation rates in small nanoparticles with diameters of a few nanometers exhibit a molecule-like behaviour with discrete peaks which evolve into a continuous distribution for larger nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

Plasmon-induced hot carriers from interband and intraband transitions in large noble metal nanoparticles

Jin,

Kahk,

Papaconstantopoulos

et al. 2022

Preprint

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Hot electrons generated from the decay of localized surface plasmons in metallic nanostructures have the potential to transform photocatalysis, photodetection and other optoelectronic applications. However, the understanding of hot-carrier generation in realistic nanostructures, in particular the relative importance of interband and intraband transitions, remains incomplete. Here we report theoretical predictions of hot-carrier generation rates in spherical nanoparticles of the noble metals silver, gold and copper with diameters up to 30 nanometers obtained from a novel atomistic linear-scaling approach. As the nanoparticle size increases the relative importance of interband transitions from d-bands to sp-bands relative to surface-enabled sp-band to sp-band transitions increases. We find that the hot-hole generation rate is characterized by a peak at the onset of the d-bands, while the position of the corresponding peak in the hot-electron distribution can be controlled through the illumination frequency. In contrast, intraband transitions give rise to hot electrons, but relatively cold holes. Importantly, increasing the dielectric constant of the environment removes hot carriers generated from interband transitions, while increasing the number of hot carriers from intraband transitions. The insights resulting from our work enable the design of nanoparticles for specific hot-carrier applications through their material composition, size and dielectric environment.

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KITE: high-performance accurate modelling of electronic structure and response functions of large molecules, disordered crystals and heterostructures

Cited by 50 publications

References 112 publications

Orbital Hall insulating phase in transition metal dichalcogenide monolayers

Orbital Hall insulating phase in transition metal dichalcogenide monolayers

Instability of QBC systems to Topological Anderson Insulating phases

Plasmon-induced hot carriers from interband and intraband transitions in large noble metal nanoparticles

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