6 research outputs found
Importance of nonuniform Brillouin zone sampling for ab initio Bethe-Salpeter equation calculations of exciton binding energies in crystalline solids
Excitons are prevalent in semiconductors and insulators, and their binding energies are critical for optoelectronic applications. The state-of-the-art method for first-principles calculations of excitons in extended systems is the ab initio GW-Bethe-Salpeter equation (BSE) approach, which can require a fine sampling of reciprocal space to accurately resolve solid-state exciton properties. Here we show, for a range of semiconductors and insulators, that the commonly employed approach of uniformly sampling the Brillouin zone can lead to underconverged exciton binding energies, as impractical grid sizes are required to achieve adequate convergence. We further show that nonuniform sampling of the Brillouin zone, focused on the region of reciprocal space where the exciton wave function resides, enables efficient rapid numerical convergence of exciton binding energies at a given level of theory. We propose a well-defined convergence procedure, which can be carried out at relatively low computational cost and which in some cases leads to a correction of previous best theoretical estimates by almost a factor of 2, qualitatively changing the predicted exciton physics. These results call for the adoption of nonuniform sampling methods for ab initio GW-BSE calculations and for revisiting previously computed values for exciton binding energies of many systems
Impact of exciton delocalization on exciton-vibration interactions in organic semiconductors
Organic semiconductors exhibit properties of individual molecules and
extended crystals simultaneously. The strongly bound excitons they host are
typically described in the molecular limit, but excitons can delocalize over
many molecules, raising the question of how important the extended crystalline
nature is. Using accurate Green's function based methods for the electronic
structure and non-perturbative finite difference methods for exciton-vibration
coupling, we describe exciton interactions with molecular and crystal degrees
of freedom concurrently. We find that the degree of exciton delocalization
controls these interactions, with thermally activated crystal phonons
predominantly coupling to delocalized states, and molecular quantum
fluctuations predominantly coupling to localized states. Based on this picture,
we quantitatively predict and interpret the temperature and pressure dependence
of excitonic peaks in the acene series of organic semiconductors, which we
confirm experimentally, and we develop a simple experimental protocol for
probing exciton delocalization. Overall, we provide a unified picture of
exciton delocalization and vibrational effects in organic semiconductors,
reconciling the complementary views of finite molecular clusters and periodic
molecular solids
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Importance of vibrational anharmonicity for electron-phonon coupling in molecular crystals
Accurate predictions of electronic band gaps are key to the computational design of functional materials with tailored optical and thermoelectric properties. While an accurate description of the underlying electronic structure is indispensable, electron-phonon interactions also play a prominent role in determining the band gap. The harmonic vibrational approximation is used almost universally to describe electron-phonon coupling and provides a satisfactory description in most systems. Here, we demonstrate that this is not the case for molecular crystals due to the presence of strongly anharmonic motions. We demonstrate the breakdown of the harmonic approximation in acene molecular crystals, and show that converged band gaps can be obtained by rigorously accounting for vibrational anharmonicity using path-integral molecular dynamics. Finally, we characterize the most anharmonic vibrational modes and their contributions to the band-gap renormalization
Microcavity-like exciton-polaritons can be the primary photoexcitation in bare organic semiconductors
Strong-coupling between excitons and confined photonic modes can lead to the formation of new quasi-particles termed exciton-polaritons which can display a range of interesting properties such as super-fluidity, ultrafast transport and Bose-Einstein condensation. Strong-coupling typically occurs when an excitonic material is confided in a dielectric or plasmonic microcavity. Here, we show polaritons can form at room temperature in a range of chemically diverse, organic semiconductor thin films, despite the absence of an external cavity. We find evidence of strong light-matter coupling via angle-dependent peak splittings in the reflectivity spectra of the materials and emission from collective polariton states. We additionally show exciton-polaritons are the primary photoexcitation in these organic materials by directly imaging their ultrafast (5 × 106 m s−1), ultralong (~270 nm) transport. These results open-up new fundamental physics and could enable a new generation of organic optoelectronic and light harvesting devices based on cavity-free exciton-polariton