Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering

Yecun Wu; Huei Ru Fuh; Duan Zhang; Cormac Coileáin; Hongjun Xu; Jiung Cho; Miri Choi; Byong Sun Chun; Xuju Jiang; Mourad Abid; Mohamed Abid; Huajun Liu; Jing Jing Wang; Igor V. Shvets; Ching Ray Chang; Han Chun Wu

doi:10.1016/j.nanoen.2016.12.034

Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering

Yecun Wu, Huei Ru Fuh, Duan Zhang^*, Cormac Coileáin, Hongjun Xu, Jiung Cho, Miri Choi, Byong Sun Chun, Xuju Jiang, Mourad Abid, Mohamed Abid, Huajun Liu, Jing Jing Wang, Igor V. Shvets, Ching Ray Chang, Han Chun Wu

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

47 Citations (Scopus)

Abstract

For applications in wearable human-device interfaces and optoelectronics, flexible materials capable of supporting spatial and uninterrupted bandgap tunability are of immense value. We demonstrate theoretically and experimentally the wide bandgap tunability of GaSe nanosheets, with simultaneous PL enhancement, via elastic strain engineering at room temperature. The elastic strain gives rise to a continuously variable electronic band structure profile, with a rate of 40 meV/1%, and a 3-fold enhancement in PL intensity is achieved when a uniaxial strain of 1% is introduced. An additional effect is that a new exciton state arises when the strain is raised beyond 0.6%. This work suggests that strain engineering can effectively modulate/control the generation, separation, transport, and recombination of photo-induced charge carriers in GaSe, making it a valuable material for flexible optoelectronic-mechanical applications.

Original language	English
Pages (from-to)	157-164
Number of pages	8
Journal	Nano Energy
Volume	32
DOIs	https://doi.org/10.1016/j.nanoen.2016.12.034
Publication status	Published - 1 Feb 2017

Keywords

Exciton
GaSe
Photoluminescence
Piezoptics
Strain engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.nanoen.2016.12.034

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Wu, Y., Fuh, H. R., Zhang, D., Coileáin, C., Xu, H., Cho, J., Choi, M., Chun, B. S., Jiang, X., Abid, M., Abid, M., Liu, H., Wang, J. J., Shvets, I. V., Chang, C. R., & Wu, H. C. (2017). Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering. Nano Energy, 32, 157-164. https://doi.org/10.1016/j.nanoen.2016.12.034

@article{246455a8bf454613a05883406ecb77d7,

title = "Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering",

abstract = "For applications in wearable human-device interfaces and optoelectronics, flexible materials capable of supporting spatial and uninterrupted bandgap tunability are of immense value. We demonstrate theoretically and experimentally the wide bandgap tunability of GaSe nanosheets, with simultaneous PL enhancement, via elastic strain engineering at room temperature. The elastic strain gives rise to a continuously variable electronic band structure profile, with a rate of 40 meV/1%, and a 3-fold enhancement in PL intensity is achieved when a uniaxial strain of 1% is introduced. An additional effect is that a new exciton state arises when the strain is raised beyond 0.6%. This work suggests that strain engineering can effectively modulate/control the generation, separation, transport, and recombination of photo-induced charge carriers in GaSe, making it a valuable material for flexible optoelectronic-mechanical applications.",

keywords = "Exciton, GaSe, Photoluminescence, Piezoptics, Strain engineering",

author = "Yecun Wu and Fuh, {Huei Ru} and Duan Zhang and Cormac Coile{\'a}in and Hongjun Xu and Jiung Cho and Miri Choi and Chun, {Byong Sun} and Xuju Jiang and Mourad Abid and Mohamed Abid and Huajun Liu and Wang, {Jing Jing} and Shvets, {Igor V.} and Chang, {Ching Ray} and Wu, {Han Chun}",

note = "Publisher Copyright: {\textcopyright} 2016 Elsevier Ltd",

year = "2017",

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day = "1",

doi = "10.1016/j.nanoen.2016.12.034",

language = "English",

volume = "32",

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journal = "Nano Energy",

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Wu, Y, Fuh, HR, Zhang, D, Coileáin, C, Xu, H, Cho, J, Choi, M, Chun, BS, Jiang, X, Abid, M, Abid, M, Liu, H, Wang, JJ, Shvets, IV, Chang, CR & Wu, HC 2017, 'Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering', Nano Energy, vol. 32, pp. 157-164. https://doi.org/10.1016/j.nanoen.2016.12.034

TY - JOUR

T1 - Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering

AU - Wu, Yecun

AU - Fuh, Huei Ru

AU - Zhang, Duan

AU - Coileáin, Cormac

AU - Xu, Hongjun

AU - Cho, Jiung

AU - Choi, Miri

AU - Chun, Byong Sun

AU - Jiang, Xuju

AU - Abid, Mourad

AU - Abid, Mohamed

AU - Liu, Huajun

AU - Wang, Jing Jing

AU - Shvets, Igor V.

AU - Chang, Ching Ray

AU - Wu, Han Chun

PY - 2017/2/1

Y1 - 2017/2/1

N2 - For applications in wearable human-device interfaces and optoelectronics, flexible materials capable of supporting spatial and uninterrupted bandgap tunability are of immense value. We demonstrate theoretically and experimentally the wide bandgap tunability of GaSe nanosheets, with simultaneous PL enhancement, via elastic strain engineering at room temperature. The elastic strain gives rise to a continuously variable electronic band structure profile, with a rate of 40 meV/1%, and a 3-fold enhancement in PL intensity is achieved when a uniaxial strain of 1% is introduced. An additional effect is that a new exciton state arises when the strain is raised beyond 0.6%. This work suggests that strain engineering can effectively modulate/control the generation, separation, transport, and recombination of photo-induced charge carriers in GaSe, making it a valuable material for flexible optoelectronic-mechanical applications.

AB - For applications in wearable human-device interfaces and optoelectronics, flexible materials capable of supporting spatial and uninterrupted bandgap tunability are of immense value. We demonstrate theoretically and experimentally the wide bandgap tunability of GaSe nanosheets, with simultaneous PL enhancement, via elastic strain engineering at room temperature. The elastic strain gives rise to a continuously variable electronic band structure profile, with a rate of 40 meV/1%, and a 3-fold enhancement in PL intensity is achieved when a uniaxial strain of 1% is introduced. An additional effect is that a new exciton state arises when the strain is raised beyond 0.6%. This work suggests that strain engineering can effectively modulate/control the generation, separation, transport, and recombination of photo-induced charge carriers in GaSe, making it a valuable material for flexible optoelectronic-mechanical applications.

KW - Exciton

KW - GaSe

KW - Photoluminescence

KW - Piezoptics

KW - Strain engineering

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U2 - 10.1016/j.nanoen.2016.12.034

DO - 10.1016/j.nanoen.2016.12.034

M3 - Article

AN - SCOPUS:85007240800

SN - 2211-2855

VL - 32

SP - 157

EP - 164

JO - Nano Energy

JF - Nano Energy

ER -

Simultaneous large continuous band gap tunability and photoluminescence enhancement in GaSe nanosheets via elastic strain engineering

Abstract

Keywords

UN SDGs

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