Pengfei Guo scite author profile

Band gap engineering of atomically thin two-dimensional layered materials is critical for their applications in nanoelectronics, optoelectronics, and photonics. Here we report, for the first time, a simple one-step chemical vapor deposition approach for the simultaneous growth of alloy MoS2xSe2(1-x) triangular nanosheets with complete composition tunability. Both the Raman and the photoluminescence studies show tunable optical properties consistent with composition of the alloy nanosheets. Importantly, all samples show a single bandedge emission peak, with the spectral peak position shifting from 668 nm (for pure MoS2) to 795 nm (for pure MoSe2), indicating the high quality for these complete composition alloy nanosheets. These band gap engineered 2D structures could open up an exciting opportunity for probing their fundamental physical properties in 2D and may find diverse applications in functional electronic/optoelectronic devices.

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Review of Silicon Photonics Technology and Platform Development

Siew¹,

Li²,

Gao³

et al. 2021

J. Lightwave Technol.

564

200

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Wanget al.Reply

et al. 2015

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Room-Temperature Dual-Wavelength Lasing from Single-Nanoribbon Lateral Heterostructures

et al. 2012

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Nanoscale dual-wavelength lasers are attractive for their potential applications in highly integrated photonic devices. Here we report the growth of nanoribbon lateral heterostructures made of a CdS(x)Se(1-x) central region with epitaxial CdS lateral sides using a multistep thermal evaporation route with a moving source. Under laser excitation, the emission of these ribbons indicates sandwich-like structures along the width direction, with characteristic red emission in the center and green emission at both edges. More importantly, dual-wavelength lasing with tunable wavelengths is demonstrated at room temperature based on these single-nanoribbon heterostructures for the first time. These achievements represent a significant advance in designing nanoscale dual-wavelength lasers and have the potential to open up new and exciting opportunities for diverse applications in integrated photonics, optoelectronics, and sensing.

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Wavelength-Converted/Selective Waveguiding Based on Composition-Graded Semiconductor Nanowires

Zhuang

Guo

et al. 2012

Nano Lett.

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Compact wavelength-sensitive optical components are desirable for optical information processing and communication in photonic integrated system. In this work, optical waveguiding along single composition-graded CdS(x)Se(1-x) nanowires were systematically investigated. Under a focused laser excitation, the excited light can be guided passively along the bandgap-increased direction of the nanowire, keeping the photonic energy of the guided light almost unchanged during the whole propagation. In comparison, the excited light is guided actively through incessantly repeated band-to-band reabsorption and re-emitting processes along the bandgap-decreased direction, resulting in a gradual wavelength conversion during propagation. On the basis of this wavelength-converted waveguiding, a concept of nanoscale wavelength splitter is demonstrated by assembling a graded nanowire with several composition-uniform nanowires into branched nanowire structure. Our study indicates that composition-graded semiconductor nanowires would open new exciting opportunities in developing new wavelength-sensitive optical components for integrated nanophotonic devices.

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Pengfei Guo

Growth of Alloy MoS_2xSe_2(1–x) Nanosheets with Fully Tunable Chemical Compositions and Optical Properties

Review of Silicon Photonics Technology and Platform Development

Wanget al.Reply

Room-Temperature Dual-Wavelength Lasing from Single-Nanoribbon Lateral Heterostructures

Wavelength-Converted/Selective Waveguiding Based on Composition-Graded Semiconductor Nanowires

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Product

Resources

About

Pengfei Guo

Growth of Alloy MoS2xSe2(1–x) Nanosheets with Fully Tunable Chemical Compositions and Optical Properties

Review of Silicon Photonics Technology and Platform Development

Wanget al.Reply

Room-Temperature Dual-Wavelength Lasing from Single-Nanoribbon Lateral Heterostructures

Wavelength-Converted/Selective Waveguiding Based on Composition-Graded Semiconductor Nanowires

Contact Info

Product

Resources

About

Growth of Alloy MoS_2xSe_2(1–x) Nanosheets with Fully Tunable Chemical Compositions and Optical Properties