Visualizing intercalation effects in 2D materials using AFM based techniques

TL;DR

This paper demonstrates how AFM-based techniques can effectively visualize and analyze intercalation effects in 2D materials, providing a noninvasive alternative to traditional vacuum methods.

Contribution

It introduces AFM techniques for mapping structural, electronic, and optical changes due to intercalation in 2D materials, offering a versatile characterization approach.

Findings

AFM topography reveals structural changes due to intercalation.

Phase imaging shows reduced Young's modulus and adhesion in intercalated regions.

Kelvin Probe Force Microscopy detects variations in surface potential and work function.

Abstract

Intercalation of two dimensional materials, particularly transition metal dichalcogenides, is a noninvasive way to modify electronic, optical and structural properties of these materials. However, research of these atomic-scale phenomena usually relies on using Ultra High Vacuum techniques which is time consuming, expensive and spatially limited. Here we utilize Atomic Force Microscopy (AFM) based techniques to visualize local structural and electronic changes of the MoS2 on graphene on Ir(111), caused by sulfur intercalation. AFM topography reveals structural changes, while phase imaging and mechanical measurements show reduced Young's modulus and adhesion. Kelvin Probe Force Microscopy highlights variations in surface potential and work function, aligning with intercalation signatures, while Photoinduced Force Microscopy detects enhanced optical response in intercalated regions. These results demonstrate the efficacy of AFM based techniques in mapping intercalation, offering insights into tailoring 2D materials electronic and optical properties. This work underscores the potential of AFM techniques for advanced material characterization and the development of 2D material applications.