Scientists Achieve Nanoscale Visualization of Spin Manipulation in Chiral Perovskites Using Novel Kelvin Probe Force Microscopy
In a groundbreaking study that pushes the boundaries of spintronics and optoelectronics, a team of international researchers has successfully mapped the elusive chiral-induced spin selectivity (CISS) effect in chiral halide perovskites at an unprecedented nanoscale resolution. This landmark achievement heralds a new era for the manipulation of electron spin within semiconductor materials, potentially revolutionizing data processing technologies spanning from quantum computing to neuromorphic systems.
Chiral halide perovskites have been at the forefront of materials science research due to their unique ability to control not only charge and light but also the spin orientation of electrons at room temperature. This peculiar trait is attributed to the CISS effect, which allows these materials to preferentially filter electrons based on their spin polarization—a fundamental quantum property that can encode information beyond traditional charge-based electronics. Leveraging this effect promises highly efficient, low-energy spintronic devices that could dramatically enhance information storage and transmission.
Yet, despite widespread interest, direct visualization and detailed understanding of the CISS effect at the microscopic scale have eluded researchers until now. Conventional experimental methodologies, while capable of detecting spin selectivity, fall short in capturing the spatial heterogeneity and local strength of the effect across material surfaces. This limitation impedes fine-tuning material properties for device applications, as microscopic inhomogeneities can critically affect performance and reliability.
To overcome these challenges, scientists collaborated across institutions—including the Ningbo Institute of Materials Technology and Engineering under the Chinese Academy of Sciences, the Hong Kong University of Science and Technology, and the U.S. National Renewable Energy Laboratory—to engineer a customized Kelvin probe force microscopy (KPFM) system. This advanced technique enabled them to perform high-resolution scans on chiral perovskite thin films under varying magnetic configurations, yielding detailed “spin maps” that quantify both the magnitude and uniformity of the CISS effect on the nanoscale.
The KPFM approach exploits subtle variations in surface potential modulated by spin orientations to construct spatially resolved images of spin polarization. Through sequential imaging while switching magnetic fields, the research team could discern how spin-dependent charge distribution evolves locally within chiral perovskite matrices. Such non-destructive, contactless probing represents a significant advance since it preserves the intrinsic material properties during measurement, permitting accurate characterization relevant to practical device conditions.
Beyond simply mapping spin behavior within the chiral films, the researchers uncovered the presence of spin–Schottky junctions at interfaces where chiral perovskites contact metal electrodes. These junctions exhibit spin-dependent energy barriers that dictate electron injection dynamics—crucial insights that illuminate how spin currents are modulated when moving across material boundaries. Understanding these interface phenomena is vital for engineering efficient spintronic devices, as interfacial spin filtering and scattering substantially influence overall device performance.
Further investigation revealed that multiple factors modulate the spin-selective efficiency of chiral perovskites. Key parameters include the nature of chiral cations incorporated into the lattice, thin film thickness, as well as synthesis and processing conditions. These factors collectively shape the spin orbit coupling and chiral asymmetry within the material, thereby tuning the strength of the CISS effect. Notably, the researchers observed marked nanoscale variations—spatial inhomogeneities in spin polarization—which could limit achievable device uniformity and call for more precise material engineering.
This pioneering work not only establishes a robust, quantitative platform for interrogating spin dynamics in chiral perovskites but also provides an essential blueprint to rationally design materials with enhanced spintronic functionality. By physically visualizing how spin selectivity manifests on the nanoscale, the study bridges the gap between fundamental quantum spin phenomena and scalable device architectures, fostering the development of next-generation, energy-efficient computing technologies.
Researchers emphasize that chiral perovskites, with their versatile optoelectronic and spin-dependent properties, occupy a unique position in the material landscape, capable of integrating light manipulation and spin control within a single system operable at ambient conditions. This dual capability opens exciting possibilities for multifunctional devices that merge photonics, electronics, and spintronics in coherent architectures.
Moreover, the experimental advances demonstrated through custom KPFM measurements stand to inspire new investigative approaches probing spin phenomena in a variety of chiral and low-dimensional materials. As the quest for spin-based information processing evolves, techniques able to resolve spin textures and dynamics in real space and real time will become indispensable tools for scientific discovery and technological innovation.
Ultimately, the insights garnered from this study provide a foundational step toward harnessing the power of spin polarization for transformative applications in quantum information science, memory devices, and neuromorphic circuits. By unveiling the nanoscale intricacies of spin selectivity and interface behavior, the research paves the way for the deliberate manipulation of electron spin with precision—an advancement expected to fuel the next wave of breakthroughs in material science and device engineering.
This cutting-edge research, published in the National Science Review, underscores the critical importance of interdisciplinary collaboration and technological innovation in realizing the full potential of chiral perovskites as versatile, high-impact materials for the future of spintronic and optoelectronic technologies.
Subject of Research: Nanoscale investigation of chiral-induced spin selectivity (CISS) effect in chiral halide perovskite thin films.
Article Title: Scientists map how chiral perovskites control electron spin.
News Publication Date: Not specified in source material.
Web References: http://dx.doi.org/10.1093/nsr/nwaf295
References: Published in National Science Review.
Image Credits: ©Science China Press
Keywords
Chiral halide perovskites, chiral-induced spin selectivity (CISS), Kelvin probe force microscopy (KPFM), spintronics, spin–Schottky junctions, electron spin, nanoscale spin mapping, quantum computing, optoelectronics, spin-polarized currents, material interfaces, neuromorphic computing.
Tags: chiral perovskites researchchiral-induced spin selectivity effectelectron spin manipulationinformation storage technologyKelvin probe force microscopy techniquelow-energy spintronic devicesnanoscale spin mappingneuromorphic systems developmentoptoelectronics innovationsQuantum Computing Applicationssemiconductor materials propertiesspintronics advancements
