1. Revealing Strain-Induced Effects in Ultrathin Heterostructures at the Nanoscale
- Author
-
Yingqiu Zhou, Jamie H. Warner, Harish Bhaskaran, Syed Ghazi Sarwat, Yuewen Sheng, Martin Tweedie, Benjamin F. Porter, and Jan A. Mol
- Subjects
Kelvin probe force microscope ,Materials science ,Strain (chemistry) ,Graphene ,Mechanical Engineering ,Bioengineering ,Nanotechnology ,Heterojunction ,02 engineering and technology ,General Chemistry ,Substrate (electronics) ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,0104 chemical sciences ,Characterization (materials science) ,law.invention ,law ,General Materials Science ,Work function ,0210 nano-technology ,Nanoscopic scale - Abstract
Two-dimensional materials are being increasingly studied, particularly for flexible and wearable technologies because of their inherent thickness and flexibility. Crucially, one aspect where our understanding is still limited is on the effect of mechanical strain, not on individual sheets of materials, but when stacked together as heterostructures in devices. In this paper, we demonstrate the use of Kelvin probe microscopy in capturing the influence of uniaxial tensile strain on the band-structures of graphene and WS2 (mono- and multilayered) based heterostructures at high resolution. We report a major advance in strain characterization tools through enabling a single-shot capture of strain defined changes in a heterogeneous system at the nanoscale, overcoming the limitations (materials, resolution, and substrate effects) of existing techniques such as optical spectroscopy. Using this technique, we observe that the work-functions of graphene and WS2 increase as a function of strain, which we attribute to the Fermi level lowering from increased p-doping. We also extract the nature of the interfacial heterojunctions and find that they get strongly modulated from strain. We observe that the strain-enhanced charge transfer with the substrate plays a dominant role, causing the heterostructures to behave differently from two-dimensional materials in their isolated forms.
- Published
- 2018