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Dr Joyce’s research aims to create nanoscale and low-dimensional components for future electronic and optoelectronic devices. These components include low-dimensional materials such as graphene, monolayer transition metal dichalcogenides (e.g. monolayer MoS2) and semiconductor nanowires.
Particularly promising are semiconductor nanowires made out of III–V materials, such as GaAs, InAs, InP and AlGaAs. These nanowires typically feature diameters between 10 to 100 nm and lengths of several microns. The excellent electronic properties of these III–V materials, coupled with the tiny dimensions of the nanowire geometry, make III–V nanowires outstanding candidates for future electronic and optoelectronic devices, including light emitting diodes, lasers and solar cells.
If nanoscale materials are to be useful in future devices, we need to be able (i) to fabricate them controllably and reproducibly using techniques such as chemical vapour deposition and molecular beam epitaxy, (ii) to measure and control their fundamental optical and electronic properties, and (iii) to develop processing techniques to make functional devices. Dr Joyce’s research endeavours to grow and characterise nanowires and other low-dimensional materials, and implement novel devices, particularly solar cell devices, based on these materials.
Particularly promising are semiconductor nanowires made out of III–V materials, such as GaAs, InAs, InP and AlGaAs. These nanowires typically feature diameters between 10 to 100 nm and lengths of several microns. The excellent electronic properties of these III–V materials, coupled with the tiny dimensions of the nanowire geometry, make III–V nanowires outstanding candidates for future electronic and optoelectronic devices, including light emitting diodes, lasers and solar cells.
If nanoscale materials are to be useful in future devices, we need to be able (i) to fabricate them controllably and reproducibly using techniques such as chemical vapour deposition and molecular beam epitaxy, (ii) to measure and control their fundamental optical and electronic properties, and (iii) to develop processing techniques to make functional devices. Dr Joyce’s research endeavours to grow and characterise nanowires and other low-dimensional materials, and implement novel devices, particularly solar cell devices, based on these materials.
研究兴趣
论文共 211 篇作者统计合作学者相似作者
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Kaveh Delfanazari, Jiahui Li, Yusheng Xiong,Pengcheng Ma,Reuben K. Puddy,Teng Yi,Ian Farrer,Sachio Komori,Jason W. A. Robinson,Llorenc Serra,David A. Ritchie,Michael J. Kelly,
PHYSICAL REVIEW APPLIEDno. 1 (2024)
Feng Tang,Jingjun Wu,Tom Albrow-Owen,Hanxiao Cui,Fujia Chen,Yaqi Shi, Lan Zou, Jun Chen,Xuhan Guo, Yijun Sun,Jikui Luo, Bingfeng Ju,
arxiv(2024)
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APL PHOTONICSno. 1 (2024): 011101-011101-20
NANOSCALE ADVANCESno. 9 (2023): 2610-2620
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Kaveh Delfanazari, Jiahui Li, Pengchen Ma,Reuben K. Puddy,Teng Yi, Yusheng Xiong,Ian Farrer,Sachio Komori,Jason W. A. Robinson,David A. Ritchie,Michael J. Kelly,Hannah J. Joyce,
ADVANCED ELECTRONIC MATERIALSno. 2 (2023): n/a-n/a
Yang Wu, Gabriele Restifo Pecorella,Gianluca Verderame, Daniele Annicchiarico, Thanuja Galhena,Stephen Hodge,Hannah Jane Joyce,Patrizia Livreri,Antonio Lombardo
IEEE Sensors Journalno. 17 (2023): 19282-19289
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2023 48TH INTERNATIONAL CONFERENCE ON INFRARED, MILLIMETER, AND TERAHERTZ WAVES, IRMMW-THZpp.1-1, (2023)
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