We report a facile phase conversion method that can locally convert n-type SnSe_(2)into p-type SnSe by direct laser irradiation.Raman spectra of SnSe_(2)flakes before and after laser irradiation confirm the phase conv...We report a facile phase conversion method that can locally convert n-type SnSe_(2)into p-type SnSe by direct laser irradiation.Raman spectra of SnSe_(2)flakes before and after laser irradiation confirm the phase conversion of SnSe_(2)to SnSe.By performing the laser irradiation on SnSe_(2)flakes at different temperatures,it is found that laser heating effect induces the removal of Se atoms from SnSe_(2)and results in the phase conversion of SnSe_(2)to SnSe.Lattice-revolved transmission electron microscope images of SnSe_(2)flakes before and after laser irradiation further confirm such conversion.By selective laser irradiation on SnSe_(2)flakes,a pattern with SnSe_(2)/SnSe heteostructures is created.This indicates that the laser induced phase conversion technique has relatively high spatial resolution and enables the creation of micron-sized in-plane p-n junction at predefined region.展开更多
We designed a sector bowtie nanoantenna integrated with a rectifier (Au-TiOx-Ti diode) for collect- ing infrared energy. The optical performance of the metallic bowtie nanoantenna was numerically investigated at inf...We designed a sector bowtie nanoantenna integrated with a rectifier (Au-TiOx-Ti diode) for collect- ing infrared energy. The optical performance of the metallic bowtie nanoantenna was numerically investigated at infrared frequencies (5-30 μm) using three-dimensional frequency-domain electro- magnetic field calculation software based on the finite element method. The simulation results indi- cate that the resonance wavelength and local field enhancement are greatly affected by the shape and size of the bowtie nanoantenna, as well as the relative permittivity and conductivity of the dielectric layer. The output current of the rectified nano-rectenna is substantially at nanoampere magnitude with an electric field intensity of 1 V/m. Moreover, the power conversion efficiency for devices with three different substrates illustrates that a substrate with a larger refractive index yields a higher efficiency and longer infrared response wavelength. Consequently, the optimized structure can pro- vide theoretical support for the design of novel optical rectennas and fabrication of optoelectronic devices.展开更多
基金supported by the National Key Research&Development Project of China(Grant Nos.2016YFA0202300 and 2018FYA0305800)the National Natural Science Foundation of China(Grant No.61888102)+1 种基金Strategic Priority Research Program of Chinese Academy of Sciences(Grant Nos.XDB30000000 and XDB28000000)Youth Innovation Promotion Association of Chinese Academy of Sciences(Grant No.Y201902)。
文摘We report a facile phase conversion method that can locally convert n-type SnSe_(2)into p-type SnSe by direct laser irradiation.Raman spectra of SnSe_(2)flakes before and after laser irradiation confirm the phase conversion of SnSe_(2)to SnSe.By performing the laser irradiation on SnSe_(2)flakes at different temperatures,it is found that laser heating effect induces the removal of Se atoms from SnSe_(2)and results in the phase conversion of SnSe_(2)to SnSe.Lattice-revolved transmission electron microscope images of SnSe_(2)flakes before and after laser irradiation further confirm such conversion.By selective laser irradiation on SnSe_(2)flakes,a pattern with SnSe_(2)/SnSe heteostructures is created.This indicates that the laser induced phase conversion technique has relatively high spatial resolution and enables the creation of micron-sized in-plane p-n junction at predefined region.
基金This work was supported by the Ministry of Science and Technology of China (Grant No. 2015DFG62610) and the National Natural Science Foundation of China (Grant No. 11404074).
文摘We designed a sector bowtie nanoantenna integrated with a rectifier (Au-TiOx-Ti diode) for collect- ing infrared energy. The optical performance of the metallic bowtie nanoantenna was numerically investigated at infrared frequencies (5-30 μm) using three-dimensional frequency-domain electro- magnetic field calculation software based on the finite element method. The simulation results indi- cate that the resonance wavelength and local field enhancement are greatly affected by the shape and size of the bowtie nanoantenna, as well as the relative permittivity and conductivity of the dielectric layer. The output current of the rectified nano-rectenna is substantially at nanoampere magnitude with an electric field intensity of 1 V/m. Moreover, the power conversion efficiency for devices with three different substrates illustrates that a substrate with a larger refractive index yields a higher efficiency and longer infrared response wavelength. Consequently, the optimized structure can pro- vide theoretical support for the design of novel optical rectennas and fabrication of optoelectronic devices.