It is desirable to have electromagnetic wave absorbers with ultrathin structural thickness and broader spectral absorption bandwidth with numerous applications in optoelectronics.In this paper,we theoretically propose...It is desirable to have electromagnetic wave absorbers with ultrathin structural thickness and broader spectral absorption bandwidth with numerous applications in optoelectronics.In this paper,we theoretically propose and numerically demonstrate a novel ultrathin nanostructure absorber composed of semiconductor nanoring array and a uniform gold substrate.The results show that the absorption covers the entire visible light region,achieving an average absorption rate more than 90%in a wavelength range from 300 nm to 740 nm and a nearly perfect absorption from 450 nm to 500 nm,and the polarization insensitivity performance is particularly great.The absorption performance is mainly caused by the electrical resonance and magnetic resonance of semiconductor nanoring array as well as the field coupling effects.Our designed broadband visible light absorber has wide application prospects in the fields of thermal photovoltaics and photodetectors.展开更多
Over the past decade, ultrathin lanthanide oxides (Ln2O3, Ln = La to Lu) nanomaterials have been intensively studied in the fields of rare earth materials science. This unique class of nanomaterials has shown many u...Over the past decade, ultrathin lanthanide oxides (Ln2O3, Ln = La to Lu) nanomaterials have been intensively studied in the fields of rare earth materials science. This unique class of nanomaterials has shown many unprecedented properties (big surface area, high surface effect, physical and chemical activities) and is thus being explored for numerous promising applications. In this review, a brief introduction of ultrathin Ln2O3 nanomaterials was given and their unique advantages were highlighted. Then, the typical synthetic methodologies were summarized and compared (thermal decomposition, solvothermal, soft template, co-precipition and microwave etc.). Due to the high surface effect, some promising applications of ultmthin Ln203 nanomaterials, such as drug delivery and catalysis of CO oxidation, were reviewed. Finally, on the basis of current achievements on ultrathin Ln203 nanomaterials, personal perspectives and challenges on future research directions were proposed.展开更多
基金Project supported by the Natural Science Foundation of Guangdong Province,China(Grant Nos.2018A030313854 and 2016A030313851)
文摘It is desirable to have electromagnetic wave absorbers with ultrathin structural thickness and broader spectral absorption bandwidth with numerous applications in optoelectronics.In this paper,we theoretically propose and numerically demonstrate a novel ultrathin nanostructure absorber composed of semiconductor nanoring array and a uniform gold substrate.The results show that the absorption covers the entire visible light region,achieving an average absorption rate more than 90%in a wavelength range from 300 nm to 740 nm and a nearly perfect absorption from 450 nm to 500 nm,and the polarization insensitivity performance is particularly great.The absorption performance is mainly caused by the electrical resonance and magnetic resonance of semiconductor nanoring array as well as the field coupling effects.Our designed broadband visible light absorber has wide application prospects in the fields of thermal photovoltaics and photodetectors.
基金supported by the Start-up Funding from Xi’an Jiaotong Universitythe Fundamental Research Funds for the Central Universities (2015qngz12)+1 种基金the National Natural Science Foundation of China (21371140)the China National Funds for Excellent Young Scientists (21522106)
文摘Over the past decade, ultrathin lanthanide oxides (Ln2O3, Ln = La to Lu) nanomaterials have been intensively studied in the fields of rare earth materials science. This unique class of nanomaterials has shown many unprecedented properties (big surface area, high surface effect, physical and chemical activities) and is thus being explored for numerous promising applications. In this review, a brief introduction of ultrathin Ln2O3 nanomaterials was given and their unique advantages were highlighted. Then, the typical synthetic methodologies were summarized and compared (thermal decomposition, solvothermal, soft template, co-precipition and microwave etc.). Due to the high surface effect, some promising applications of ultmthin Ln203 nanomaterials, such as drug delivery and catalysis of CO oxidation, were reviewed. Finally, on the basis of current achievements on ultrathin Ln203 nanomaterials, personal perspectives and challenges on future research directions were proposed.
