Yong Wang scite author profile

Exploring exciting and exotic physics, scientists are pursuing practical device applications for topological insulators. The Dirac-like surface states in topological insulators are protected by the time-reversal symmetry, which naturally forbids backscattering events during the carrier transport process, and therefore offers promising applications in dissipationless spintronic devices. Although considerable efforts have been devoted to controlling their surface conduction, limited work has been focused on tuning surface states and bulk carriers in Bi(2)Te(3) nanostructures by external field. Here we report gate-tunable surface conduction in Na-doped Bi(2)Te(3) topological insulator nanoplates. Significantly, by applying external gate voltages, such topological insulators can be tuned from p-type to n-type. Our results render a promise in finding novel topological insulators with enhanced surface states.

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Broadly Defining Lasing Wavelengths in Single Bandgap-Graded Semiconductor Nanowires

Yang

et al. 2014

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Designing lasing wavelengths and modes is essential to the practical applications of nanowire (NW) lasers. Here, according to the localized photoluminescence spectra, we first demonstrate the ability to define lasing wavelengths over a wide range (up to 119 nm) based on an individual bandgap-graded CdSSe NW by forward cutting the NW from CdSe to CdS end. Furthermore, free spectral range (FSR) and modes of the obtained lasers could be controlled by backward cutting the NW from CdS to CdSe end step-by-step. Interestingly, single-mode NW laser with predefined lasing wavelength is realized in short NWs because of the strong mode competition and increase in FSR. Finally, the gain properties of the bandgap-graded NWs are investigated. The combination of wavelength and mode selectivity in NW lasers may provide a new platform for the next generation of integrated optoelectronic devices.

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Photocatalytically Powered Matchlike Nanomotor for Light‐Guided Active SERS Sensing

et al. 2018

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Surface enhanced Raman spectroscopy (SERS) is a powerful optical sensing technique that can detect analytes of extremely low concentrations. However, the presence of enough SERS probes in the detection area and a close contact between analytes and SERS probes are critical for efficient acquisition of a SERS signal. Presented here is a light-powered micro/nanomotor (MNM) that can serve as an active SERS probe. The matchlike AgNW@SiO core-shell structure of the nanomotors work as SERS probes based on the shell-isolated enhanced Raman mechanism. The AgCl tail serves as photocatalytic nanoengine, providing a self-propulsion force by light-induced self-diffusiophoresis. The phototactic behavior was utilized to achieve enrichment of the nanomotor-based SERS probes for on-demand biochemical sensing. The results demonstrate the possibility of using photocatalytic nanomotors as active SERS probes for remote, light-controlled, and smart biochemical sensing on the micro/nanoscale.

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Yong Wang

Gate-Controlled Surface Conduction in Na-Doped Bi₂Te₃ Topological Insulator Nanoplates

Broadly Defining Lasing Wavelengths in Single Bandgap-Graded Semiconductor Nanowires

Photocatalytically Powered Matchlike Nanomotor for Light‐Guided Active SERS Sensing

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Yong Wang

Gate-Controlled Surface Conduction in Na-Doped Bi2Te3 Topological Insulator Nanoplates

Broadly Defining Lasing Wavelengths in Single Bandgap-Graded Semiconductor Nanowires

Photocatalytically Powered Matchlike Nanomotor for Light‐Guided Active SERS Sensing

Contact Info

Product

Resources

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Gate-Controlled Surface Conduction in Na-Doped Bi₂Te₃ Topological Insulator Nanoplates