The investigation of optoelectronic devices based on 2D materials and their heterostructures is a very active area of investigation with both fundamental and applied aspects involved. Here, a description of a home-built scanning photocurrent microscope is presented, which is designed and developed to perform electronic transport and optical measurements of 2D-materials-based devices. The complete system is rather inexpensive (<10 000 (sic)) and it can be easily replicated in any laboratory. To illustrate the setup, current-voltage characteristics are measured, in the dark and under global illumination, of an ultrathin p-n junction formed by the stacking of an n-doped few-layer MoS2 flake onto a p-type MoS2 flake. Scanning photocurrent maps are then acquired, and by mapping the short-circuit current generated in the device under local illumination, it is found that at zero bias, the photocurrent is generated mostly in the region of overlap between the n-type and p-type flakes.
A Versatile Scanning Photocurrent Mapping System to Characterize Optoelectronic Devices based on 2D Materials / Reuter, Christoph; Frisenda, Riccardo; Lin, Der-Yuh; Ko, Tsung-Shine; Perez de Lara, David; Castellanos-Gomez, Andres. - In: SMALL METHODS. - ISSN 2366-9608. - 1:7(2017). [10.1002/smtd.201700119]
A Versatile Scanning Photocurrent Mapping System to Characterize Optoelectronic Devices based on 2D Materials
Riccardo Frisenda
;
2017
Abstract
The investigation of optoelectronic devices based on 2D materials and their heterostructures is a very active area of investigation with both fundamental and applied aspects involved. Here, a description of a home-built scanning photocurrent microscope is presented, which is designed and developed to perform electronic transport and optical measurements of 2D-materials-based devices. The complete system is rather inexpensive (<10 000 (sic)) and it can be easily replicated in any laboratory. To illustrate the setup, current-voltage characteristics are measured, in the dark and under global illumination, of an ultrathin p-n junction formed by the stacking of an n-doped few-layer MoS2 flake onto a p-type MoS2 flake. Scanning photocurrent maps are then acquired, and by mapping the short-circuit current generated in the device under local illumination, it is found that at zero bias, the photocurrent is generated mostly in the region of overlap between the n-type and p-type flakes.| File | Dimensione | Formato | |
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