Optoelectronic devices based on MoTe_{\mathrm{2}} p-n junction.

Ya-Qing Bie; Mikkel Heuck; Marco Furchi; Gabriele Grosso; Jiabao Zheng; Yuan Cao; Efren Navarro-Moratalla; Dirk Englund; Pablo Jarillo-Herrero

Optoelectronic devices based on MoTe$_{\mathrm{2}}$ p-n junction.

ORAL

Abstract

2D transition metal dichalcogenides (2D-TMD), such as MoS$_{\mathrm{2}}$, have been verified with many remarkable physical properties, which include an indirect to direct band transition as a function of thickness and a valley dependent spin polarization. One of the 2D-TMD family members, 2H-MoTe$_{\mathrm{2}}$ has been shown to be a direct bandgap semiconductor as a monolayer and bilayer with a near infrared (NIR) bandgap of about 1.1eV. However, optoelectronic devices based on MoTe2 were so far not experimentally demonstrated. Here, we will present a high on-off ratio MoTe$_{\mathrm{2}}$ p-n junction enabled by a hexagonal boron nitride encapsulation technique. Our study of the MoTe$_{\mathrm{2}}$ p-n junction devices sheds light on designing efficient NIR optoelectronic devices such as photodetectors and energy harvesting cells and light emitters.

March 15, 2016, 4:42 PM – March 15, 2016, 4:54 PM

Authors

Ya-Qing Bie
- Condensed Matter Physics, MIT
Mikkel Heuck
- EECS, MIT
Marco Furchi
- Condensed Matter Physics, MIT
Gabriele Grosso
- EECS, MIT
- Massachusetts Institute of Technology
Jiabao Zheng
- Columbia University
Yuan Cao
- Massachusetts Inst of Tech-MIT
- Condensed Matter Physics&EECS, MIT
Efren Navarro-Moratalla
- Condensed Matter Physics, MIT
Dirk Englund
- Massachusetts Institute of Technology
- EECS, MIT
Pablo Jarillo-Herrero
- Massachusetts Inst of Tech-MIT
- Condensed Matter Physics, MIT
- MIT
- Massachusetts Institute of Technology