Slow cooling and efficient extraction of C-exciton hot carriers in MoS2 monolayer

Lei Wang; Zhuo Wang; Hai Yu Wang; Gustavo Grinblat; Yu Li Huang; Dan Wang; Xiao Hui Ye; Xian Bin Li; Qiaoliang Bao; Andrewthye Shen Wee; Stefan A. Maier; Qi Dai Chen; Min Lin Zhong; Cheng Wei Qiu; Hong Bo Sun

doi:10.1038/ncomms13906

Slow cooling and efficient extraction of C-exciton hot carriers in MoS₂ monolayer

Lei Wang, Zhuo Wang, Hai Yu Wang^*, Gustavo Grinblat, Yu Li Huang, Dan Wang, Xiao Hui Ye, Xian Bin Li, Qiaoliang Bao, Andrewthye Shen Wee, Stefan A. Maier, Qi Dai Chen, Min Lin Zhong, Cheng Wei Qiu, Hong Bo Sun

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167 引用（Scopus）

摘要

In emerging optoelectronic applications, such as water photolysis, exciton fission and novel photovoltaics involving low-dimensional nanomaterials, hot-carrier relaxation and extraction mechanisms play an indispensable and intriguing role in their photo-electron conversion processes. Two-dimensional transition metal dichalcogenides have attracted much attention in above fields recently; however, insight into the relaxation mechanism of hot electron-hole pairs in the band nesting region denoted as C-excitons, remains elusive. Using MoS2₂ monolayers as a model two-dimensional transition metal dichalcogenide system, here we report a slower hot-carrier cooling for C-excitons, in comparison with band-edge excitons. We deduce that this effect arises from the favourable band alignment and transient excited-state Coulomb environment, rather than solely on quantum confinement in two-dimension systems. We identify the screening-sensitive bandgap renormalization for MoS₂ monolayer/graphene heterostructures, and confirm the initial hot-carrier extraction for the C-exciton state with an unprecedented efficiency of 80%, accompanied by a twofold reduction in the exciton binding energy.

源语言	英语
文章编号	13906
期刊	Nature Communications
卷	8
DOI	https://doi.org/10.1038/ncomms13906
出版状态	已出版 - 5 1月 2017
已对外发布	是

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Wang, L., Wang, Z., Wang, H. Y., Grinblat, G., Huang, Y. L., Wang, D., Ye, X. H., Li, X. B., Bao, Q., Wee, A. S., Maier, S. A., Chen, Q. D., Zhong, M. L., Qiu, C. W., & Sun, H. B. (2017). Slow cooling and efficient extraction of C-exciton hot carriers in MoS₂ monolayer. Nature Communications, 8, 文章 13906. https://doi.org/10.1038/ncomms13906

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title = "Slow cooling and efficient extraction of C-exciton hot carriers in MoS2 monolayer",

abstract = "In emerging optoelectronic applications, such as water photolysis, exciton fission and novel photovoltaics involving low-dimensional nanomaterials, hot-carrier relaxation and extraction mechanisms play an indispensable and intriguing role in their photo-electron conversion processes. Two-dimensional transition metal dichalcogenides have attracted much attention in above fields recently; however, insight into the relaxation mechanism of hot electron-hole pairs in the band nesting region denoted as C-excitons, remains elusive. Using MoS22 monolayers as a model two-dimensional transition metal dichalcogenide system, here we report a slower hot-carrier cooling for C-excitons, in comparison with band-edge excitons. We deduce that this effect arises from the favourable band alignment and transient excited-state Coulomb environment, rather than solely on quantum confinement in two-dimension systems. We identify the screening-sensitive bandgap renormalization for MoS2 monolayer/graphene heterostructures, and confirm the initial hot-carrier extraction for the C-exciton state with an unprecedented efficiency of 80%, accompanied by a twofold reduction in the exciton binding energy.",

author = "Lei Wang and Zhuo Wang and Wang, {Hai Yu} and Gustavo Grinblat and Huang, {Yu Li} and Dan Wang and Ye, {Xiao Hui} and Li, {Xian Bin} and Qiaoliang Bao and Wee, {Andrewthye Shen} and Maier, {Stefan A.} and Chen, {Qi Dai} and Zhong, {Min Lin} and Qiu, {Cheng Wei} and Sun, {Hong Bo}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2017.",

year = "2017",

month = jan,

day = "5",

doi = "10.1038/ncomms13906",

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journal = "Nature Communications",

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T1 - Slow cooling and efficient extraction of C-exciton hot carriers in MoS2 monolayer

AU - Wang, Lei

AU - Wang, Zhuo

AU - Wang, Hai Yu

AU - Grinblat, Gustavo

AU - Huang, Yu Li

AU - Wang, Dan

AU - Ye, Xiao Hui

AU - Li, Xian Bin

AU - Bao, Qiaoliang

AU - Wee, Andrewthye Shen

AU - Maier, Stefan A.

AU - Chen, Qi Dai

AU - Zhong, Min Lin

AU - Qiu, Cheng Wei

AU - Sun, Hong Bo

PY - 2017/1/5

Y1 - 2017/1/5

N2 - In emerging optoelectronic applications, such as water photolysis, exciton fission and novel photovoltaics involving low-dimensional nanomaterials, hot-carrier relaxation and extraction mechanisms play an indispensable and intriguing role in their photo-electron conversion processes. Two-dimensional transition metal dichalcogenides have attracted much attention in above fields recently; however, insight into the relaxation mechanism of hot electron-hole pairs in the band nesting region denoted as C-excitons, remains elusive. Using MoS22 monolayers as a model two-dimensional transition metal dichalcogenide system, here we report a slower hot-carrier cooling for C-excitons, in comparison with band-edge excitons. We deduce that this effect arises from the favourable band alignment and transient excited-state Coulomb environment, rather than solely on quantum confinement in two-dimension systems. We identify the screening-sensitive bandgap renormalization for MoS2 monolayer/graphene heterostructures, and confirm the initial hot-carrier extraction for the C-exciton state with an unprecedented efficiency of 80%, accompanied by a twofold reduction in the exciton binding energy.

AB - In emerging optoelectronic applications, such as water photolysis, exciton fission and novel photovoltaics involving low-dimensional nanomaterials, hot-carrier relaxation and extraction mechanisms play an indispensable and intriguing role in their photo-electron conversion processes. Two-dimensional transition metal dichalcogenides have attracted much attention in above fields recently; however, insight into the relaxation mechanism of hot electron-hole pairs in the band nesting region denoted as C-excitons, remains elusive. Using MoS22 monolayers as a model two-dimensional transition metal dichalcogenide system, here we report a slower hot-carrier cooling for C-excitons, in comparison with band-edge excitons. We deduce that this effect arises from the favourable band alignment and transient excited-state Coulomb environment, rather than solely on quantum confinement in two-dimension systems. We identify the screening-sensitive bandgap renormalization for MoS2 monolayer/graphene heterostructures, and confirm the initial hot-carrier extraction for the C-exciton state with an unprecedented efficiency of 80%, accompanied by a twofold reduction in the exciton binding energy.

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DO - 10.1038/ncomms13906

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SN - 2041-1723

VL - 8

JO - Nature Communications

JF - Nature Communications

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ER -

Slow cooling and efficient extraction of C-exciton hot carriers in MoS2 monolayer

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Slow cooling and efficient extraction of C-exciton hot carriers in MoS₂ monolayer