Rational Passivation of Sulfur Vacancy Defects in Two-Dimensional Transition Metal Dichalcogenides | Zendy

Hope Bretscher | Zendy; Zhaojun Li | Zendy; James Xiao | Zendy; Diana Y. Qiu | Zendy; Sivan RefaelyAbramson | Zendy; Jack A. AlexanderWebber | Zendy; Arelo Tanoh | Zendy; Ye Fan | Zendy; Géraud Delport | Zendy; Cyan A. Williams | Zendy; Samuel D. Stranks | Zendy; Stephan Hofmann | Zendy; Jeffrey B. Neaton | Zendy; Steven G. Louie | Zendy; Akshay Rao | Zendy

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Rational Passivation of Sulfur Vacancy Defects in Two-Dimensional Transition Metal Dichalcogenides

Author(s) -

Hope Bretscher,

Zhaojun Li,

James Xiao,

Diana Y. Qiu,

Sivan RefaelyAbramson,

Jack A. AlexanderWebber,

Arelo Tanoh,

Ye Fan,

Géraud Delport,

Cyan A. Williams,

Samuel D. Stranks,

Stephan Hofmann,

Jeffrey B. Neaton,

Steven G. Louie,

Akshay Rao

Publication year - 2021

Publication title -

acs nano

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 5.554

H-Index - 382

eISSN - 1936-086X

pISSN - 1936-0851

DOI - 10.1021/acsnano.1c01220

Subject(s) - passivation , vacancy defect , exciton , materials science , monolayer , photoluminescence , density functional theory , transition metal , chemical physics , ab initio , ab initio quantum chemistry methods , optoelectronics , nanotechnology , condensed matter physics , computational chemistry , crystallography , chemistry , molecule , catalysis , layer (electronics) , biochemistry , physics , organic chemistry

Structural defects vary the optoelectronic properties of monolayer transition metal dichalcogenides, leading to concerted efforts to control defect type and density via materials growth or postgrowth passivation. Here, we explore a simple chemical treatment that allows on-off switching of low-lying, defect-localized exciton states, leading to tunable emission properties. Using steady-state and ultrafast optical spectroscopy, supported by ab initio calculations, we show that passivation of sulfur vacancy defects, which act as exciton traps in monolayer MoS 2 and WS 2 , allows for controllable and improved mobilities and an increase in photoluminescence up to 275-fold, more than twice the value achieved by other chemical treatments. Our findings suggest a route for simple and rational defect engineering strategies for tunable and switchable electronic and excitonic properties through passivation.

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