TY - JOUR
T1 - Photoluminescence Induced by Substitutional Nitrogen in Single-Layer Tungsten Disulfide
AU - Qian, Qingkai
AU - Wu, Wenjing
AU - Peng, Lintao
AU - Wang, Yuanxi
AU - Tan, Anne Marie Z.
AU - Liang, Liangbo
AU - Hus, Saban M.
AU - Wang, Ke
AU - Choudhury, Tanushree H.
AU - Redwing, Joan M.
AU - Puretzky, Alexander A.
AU - Geohegan, David B.
AU - Hennig, Richard G.
AU - Ma, Xuedan
AU - Huang, Shengxi
N1 - Publisher Copyright:
© 2022 American Chemical Society.
PY - 2022/5/24
Y1 - 2022/5/24
N2 - The electronic and optical properties of two-dimensional materials can be strongly influenced by defects, some of which can find significant implementations, such as controllable doping, prolonged valley lifetime, and single-photon emissions. In this work, we demonstrate that defects created by remote N2 plasma exposure in single-layer WS2 can induce a distinct low-energy photoluminescence (PL) peak at 1.59 eV, which is in sharp contrast to that caused by remote Ar plasma. This PL peak has a critical requirement on the N2 plasma exposure dose, which is strongest for WS2 with about 2.0% sulfur deficiencies (including substitutions and vacancies) and vanishes at 5.6% or higher sulfur deficiencies. Both experiments and first-principles calculations suggest that this 1.59 eV PL peak is caused by defects related to the sulfur substitutions by nitrogen, even though low-temperature PL measurements also reveal that not all the sulfur vacancies are remedied by the substitutional nitrogen. The distinct low-energy PL peak suggests that the substitutional nitrogen defect in single-layer WS2 can potentially serve as an isolated artificial atom for creating single-photon emitters, and its intensity can also be used to monitor the doping concentrations of substitutional nitrogen.
AB - The electronic and optical properties of two-dimensional materials can be strongly influenced by defects, some of which can find significant implementations, such as controllable doping, prolonged valley lifetime, and single-photon emissions. In this work, we demonstrate that defects created by remote N2 plasma exposure in single-layer WS2 can induce a distinct low-energy photoluminescence (PL) peak at 1.59 eV, which is in sharp contrast to that caused by remote Ar plasma. This PL peak has a critical requirement on the N2 plasma exposure dose, which is strongest for WS2 with about 2.0% sulfur deficiencies (including substitutions and vacancies) and vanishes at 5.6% or higher sulfur deficiencies. Both experiments and first-principles calculations suggest that this 1.59 eV PL peak is caused by defects related to the sulfur substitutions by nitrogen, even though low-temperature PL measurements also reveal that not all the sulfur vacancies are remedied by the substitutional nitrogen. The distinct low-energy PL peak suggests that the substitutional nitrogen defect in single-layer WS2 can potentially serve as an isolated artificial atom for creating single-photon emitters, and its intensity can also be used to monitor the doping concentrations of substitutional nitrogen.
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U2 - 10.1021/acsnano.1c09809
DO - 10.1021/acsnano.1c09809
M3 - Article
C2 - 35536919
AN - SCOPUS:85130820539
SN - 1936-0851
VL - 16
SP - 7428
EP - 7437
JO - ACS nano
JF - ACS nano
IS - 5
ER -