Phase transitions of electron–hole pairs on semiconductor/conductor interfaces determine fundamental properties of optoelectronics. To investigate interfacial dynamical transitions of charged quasiparticles, however, remains a grand challenge. By employing ultrafast mid-infrared microspectroscopic probes to detect excitonic internal quantum transitions and two-dimensional atomic device fabrications, we are able to directly monitor the interplay between free carriers and insulating interlayer excitons between two atomic layers. Our observations reveal unexpected ultrafast formation of tightly bound interlayer excitons between conducting graphene and semiconducting MoSe2. The result suggests carriers in the doped graphene are no longer massless, and an effective mass as small as one percent of free electron mass is sufficient to confine carriers within a 2D hetero space with energy 10 times larger than the room-temperature thermal energy. The interlayer excitons arise within 1 ps. Their formation effectively blocks charge recombination and improves charge separation efficiency for more than one order of magnitude.
%0 Journal Article
%1 wen2018ultrafast
%A Wen, Xiewen
%A Chen, Hailong
%A Wu, Tianmin
%A Yu, Zhihao
%A Yang, Qirong
%A Deng, Jingwen
%A Liu, Zhengtang
%A Guo, Xin
%A Guan, Jianxin
%A Zhang, Xiang
%A Gong, Yongji
%A Yuan, Jiangtan
%A Zhang, Zhuhua
%A Yi, Chongyue
%A Guo, Xuefeng
%A Ajayan, Pulickel M.
%A Zhuang, Wei
%A Liu, Zhirong
%A Lou, Jun
%A Zheng, Junrong
%D 2018
%J Nature Communications
%K MoS2 charge_transport interfaces organic
%N 1
%P 1859--
%R 10.1038/s41467-018-04291-9
%T Ultrafast probes of electron–hole transitions between two atomic layers
%U https://doi.org/10.1038/s41467-018-04291-9
%V 9
%X Phase transitions of electron–hole pairs on semiconductor/conductor interfaces determine fundamental properties of optoelectronics. To investigate interfacial dynamical transitions of charged quasiparticles, however, remains a grand challenge. By employing ultrafast mid-infrared microspectroscopic probes to detect excitonic internal quantum transitions and two-dimensional atomic device fabrications, we are able to directly monitor the interplay between free carriers and insulating interlayer excitons between two atomic layers. Our observations reveal unexpected ultrafast formation of tightly bound interlayer excitons between conducting graphene and semiconducting MoSe2. The result suggests carriers in the doped graphene are no longer massless, and an effective mass as small as one percent of free electron mass is sufficient to confine carriers within a 2D hetero space with energy 10 times larger than the room-temperature thermal energy. The interlayer excitons arise within 1 ps. Their formation effectively blocks charge recombination and improves charge separation efficiency for more than one order of magnitude.
@article{wen2018ultrafast,
abstract = {Phase transitions of electron–hole pairs on semiconductor/conductor interfaces determine fundamental properties of optoelectronics. To investigate interfacial dynamical transitions of charged quasiparticles, however, remains a grand challenge. By employing ultrafast mid-infrared microspectroscopic probes to detect excitonic internal quantum transitions and two-dimensional atomic device fabrications, we are able to directly monitor the interplay between free carriers and insulating interlayer excitons between two atomic layers. Our observations reveal unexpected ultrafast formation of tightly bound interlayer excitons between conducting graphene and semiconducting MoSe2. The result suggests carriers in the doped graphene are no longer massless, and an effective mass as small as one percent of free electron mass is sufficient to confine carriers within a 2D hetero space with energy 10 times larger than the room-temperature thermal energy. The interlayer excitons arise within 1 ps. Their formation effectively blocks charge recombination and improves charge separation efficiency for more than one order of magnitude.},
added-at = {2018-07-06T11:43:09.000+0200},
author = {Wen, Xiewen and Chen, Hailong and Wu, Tianmin and Yu, Zhihao and Yang, Qirong and Deng, Jingwen and Liu, Zhengtang and Guo, Xin and Guan, Jianxin and Zhang, Xiang and Gong, Yongji and Yuan, Jiangtan and Zhang, Zhuhua and Yi, Chongyue and Guo, Xuefeng and Ajayan, Pulickel M. and Zhuang, Wei and Liu, Zhirong and Lou, Jun and Zheng, Junrong},
biburl = {https://www.bibsonomy.org/bibtex/2921cdff938eeaba5ddc6466169059f46/bretschneider_m},
doi = {10.1038/s41467-018-04291-9},
interhash = {7b0d860d030fc75cd207032fbec2d674},
intrahash = {921cdff938eeaba5ddc6466169059f46},
issn = {20411723},
journal = {Nature Communications},
keywords = {MoS2 charge_transport interfaces organic},
number = 1,
pages = {1859--},
refid = {Wen2018},
timestamp = {2018-07-06T11:43:09.000+0200},
title = {Ultrafast probes of electron–hole transitions between two atomic layers},
url = {https://doi.org/10.1038/s41467-018-04291-9},
volume = 9,
year = 2018
}