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Spin‐Dependent Charge Transport in 1D Chiral Hybrid Lead‐Bromide Perovskite with High Stability

Ying Lü, Qian Wang, Ruyi Chen, Leilei Qiao, Foxin Zhou, Xia Yang, Dong Wang, Hui Cao, Wanli He, Feng Pan, Zhou Yang, Cheng Song

2021Advanced Functional Materials93 citationsDOI

Abstract

Abstract Spin‐dependent charge transport, along with the potential electronic applications, is investigated in chiral 2D iodide hybrid organic/inorganic perovskites (HOIPs) via the chirality‐induced spin selectivity (CISS) effect, paving a new way in spintronics. Despite the high spin‐polarized current enhancement, the intrinsic oxidation tendency of iodide ions brings about severe problems in the stability and lifetime of electronic devices. Here, spin‐dependent charge transport properties in lead‐bromide perovskites hybrid with chiral R/S ‐methylbenzylammonium (MBA), that is, ( R/S ‐MBA)PbBr 3 are explored. Distinct from layered 2D iodide perovskites ( R/S ‐MBA) 2 PbI 4 which experience obvious crystal degradation along time, ( R/S ‐MBA)PbBr 3 maintain good crystallinity even in the oxidative, humid, and high‐temperature environment due to the lower Fermi level of bromide than iodide. Magnetic conductive atomic force microscopy displays a spin filtration efficiency as high as 90%, showing negligible decay after 1 month. This work expands the spin transport to chiral bromide perovskites with higher stability, and thus provides significant support for the practical application of HOIPs in spintronics.

Topics & Concepts

SpintronicsPerovskite (structure)Materials scienceIodideBromideCrystallinitySpin (aerodynamics)Chemical physicsNanotechnologyCondensed matter physicsCrystallographyInorganic chemistryChemistryFerromagnetismPhysicsComposite materialThermodynamicsPerovskite Materials and ApplicationsAdvanced Condensed Matter Physics2D Materials and Applications
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