posted on 2020-01-03, 15:35authored byFeng Li, Junfeng Ding, Weili Yu, Xinwei Guan, Peng Wang, Di Wu, Tom Wu
Organolead
trihalide perovskites have attracted substantial interest with regard
to applications in charge-based photovoltaic and optoelectronic devices
because of their low processing costs and remarkable light absorption
and charge transport properties. Although spin is an intrinsic quantum
descriptor of a particle and spintronics has been a central research
theme in condensed matter physics, few studies have explored the spin
degree of freedom in the emerging hybrid perovskites. Here, we report
the characterization of a spin valve that uses hybrid perovskite films
as the spin-transporting medium between two ferromagnetic electrodes.
Because of the light-responsive nature of the hybrid perovskite, a
high magnetoresistance of 97% and a large spin-diffusion length of
81 nm were achieved at 10 K under light illumination in polycrystalline
films. Furthermore, by using thin perovskite single crystals, we discovered
that the spin-diffusion length was able to reach 1 μm at low
temperatures. Our results indicate that the spin relaxation is not
significant as previously expected in such lead-containing materials
and demonstrate the potential of low-temperature-processed hybrid
perovskites as new active materials in spintronic devices.