Phosphorene Heterostructure Nanodevices for Ultrafast Energy Harvesting and Next Generation Electronics
Sydney L. Marler

TL;DR
This paper presents a novel nanofabrication technique that significantly improves the air stability and scalability of phosphorene heterostructure devices, enabling their use in ultrafast energy harvesting and next-generation electronics.
Contribution
It introduces a new contact fabrication method that enhances phosphorene stability and demonstrates promising electronic and photonic device performance.
Findings
Extended anodic contact prevents phosphorene degradation in ambient conditions
Device exhibits high-speed transistor properties
Potential for applications in photodetectors and energy storage
Abstract
Transition metal dichalcogenides (TMDCs) have recently shown much promise as thin layer semiconductors in application to transistor technology. TMDCs provide a unique vantage point for studying the properties of phosphorene, a highly efficient and tunable super-material. Phosphorene-TMDC heterostructure nanodevices have remained largely unexplored due to the lack of air stability observed in phosphorene under ambient conditions. This study investigates a novel nanofabrication technique that effectively enhances the air stability and practical scalability of graphene-analogous phosphorene. A phosphorene-WS2 heterostructure was first designed and synthesized via micromechanical exfoliation and dry transfer methods. A novel umbrella contact was fabricated using electron beam lithography which extended the electrical anode over the phosphorene heterojunction region. SEM, Raman spectroscopy,…
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Taxonomy
Topics2D Materials and Applications · MXene and MAX Phase Materials · Perovskite Materials and Applications
