Scalable Fabrication of Atomically Thin Monolayer MoS2 Photodetectors

Abstract

Scalable fabrication of high quality photodetectors derived from synthetically grown monolayer transition metal dichalcogenides is highly desired and important for wide range of nanophotonics applications. We present here scalable fabrication of monolayer MoS2 photodetectors on sapphire substrates through an efficient process, which includes growing large scale monolayer MoS2 via chemical vapor deposition (CVD), and multi-step optical lithography for device patterning and high quality metal electrodes fabrication. In every measured device, we observed the following universal features: (i) negligible dark current (Idark≤slant10 fA); (ii) sharp peaks in photocurrent at 1.9eV and 2.1eV attributable to the optical transitions due to band edge excitons; (iii) a rapid onset of photocurrent above 2.5eV peaked at 2.9eV due to an excitonic absorption originating from the van Hove singularity of MoS2. We observe low (≤slant 300\%) device-to-device variation of photoresponsivity. Furthermore, we observe very fast rise time 0.5 ms, which is three orders of magnitude faster than other reported CVD grown 1L-MoS2 based photodetectors. The combination of scalable device fabrication, ultra-high sensitivity and high speed offer a great potential for applications in photonics.