High-speed Mapping of Surface Charge Dynamics Using Sparse Scanning Kelvin Probe Force Microscopy

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Nov 8

PMID 37938577

Authors

Marti Checa

Addis S Fuhr

Changhyo Sun

Rama Vasudevan

Maxim Ziatdinov

Ilia Ivanov

Seok Joon Yun

Kai Xiao

Alp Sehirlioglu

Yunseok Kim

Pankaj Sharma

Kyle P Kelley

Neus Domingo

Stephen Jesse

Liam Collins

Affiliations

Soon will be listed here.

Abstract

Unraveling local dynamic charge processes is vital for progress in diverse fields, from microelectronics to energy storage. This relies on the ability to map charge carrier motion across multiple length- and timescales and understanding how these processes interact with the inherent material heterogeneities. Towards addressing this challenge, we introduce high-speed sparse scanning Kelvin probe force microscopy, which combines sparse scanning and image reconstruction. This approach is shown to enable sub-second imaging (>3 frames per second) of nanoscale charge dynamics, representing several orders of magnitude improvement over traditional Kelvin probe force microscopy imaging rates. Bridging this improved spatiotemporal resolution with macroscale device measurements, we successfully visualize electrochemically mediated diffusion of mobile surface ions on a LaAlO/SrTiO planar device. Such processes are known to impact band-alignment and charge-transfer dynamics at these heterointerfaces. Furthermore, we monitor the diffusion of oxygen vacancies at the single grain level in polycrystalline TiO. Through temperature-dependent measurements, we identify a charge diffusion activation energy of 0.18 eV, in good agreement with previously reported values and confirmed by DFT calculations. Together, these findings highlight the effectiveness and versatility of our method in understanding ionic charge carrier motion in microelectronics or nanoscale material systems.

Citing Articles

On-demand nanoengineering of in-plane ferroelectric topologies.

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Scanning Probe Microscopies for Characterizations of 2D Materials.

Su S, Zhao J, Ly T Small Methods. 2024; 8(11):e2400211.

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