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Chirality-Induced Spin–Orbit Coupling, Spin Transport, and Natural Optical Activity in Hybrid Organic–Inorganic Perovskites

Zhi Yu

2020The Journal of Physical Chemistry Letters98 citationsDOI

Abstract

Hybrid organic–inorganic perovskites (HOIPs) with chiral organic ligands exhibit highly spin-dependent transport and strong natural optical activity (NOA). Here we show that these remarkable features can be traced to a chirality-induced spin–orbit coupling (SOC), Hso = ατkzσz, which connects the carrier’s spin (σz), its wave vector (kz), and the material’s helicity (τ) along the screw direction with strength α controlled by the geometry of the organic ligands. This SOC leads to a macroscopic spin polarization in the presence of an electrical current and is responsible for the observed spin-selective transport. NOA originates from a coupling between the exciton’s center-of-mass wave vector Kz and its circular polarization jzex, Hso′ = α′τKzjzex, contributed jointly from the electron’s and the hole’s SOCs in an exciton. Our model provides a roadmap to achieve a strong and tunable chirality in HOIPs for novel applications utilizing carrier spin and photon polarization.

Topics & Concepts

Chirality (physics)HelicityCircular polarizationExcitonCondensed matter physicsSpin polarizationSpin (aerodynamics)Polarization (electrochemistry)Spin–orbit interactionCoupling (piping)Spin Hall effectMaterials scienceElectronSpintronicsChemistryPhysicsMagnetic fieldChiral anomalyQuantum mechanicsFerromagnetismThermodynamicsFermionNambu–Jona-Lasinio modelMetallurgyPhysical chemistryPerovskite Materials and ApplicationsOrganic and Molecular Conductors ResearchOrganic Light-Emitting Diodes Research
Chirality-Induced Spin–Orbit Coupling, Spin Transport, and Natural Optical Activity in Hybrid Organic–Inorganic Perovskites | Litcius