All-dielectric metasurfaces are usually limited because of their static functionality and small scale.In this paper,we use an easy nanofabrication technique to fabricate all-dielectric metasurfaces with the advantages...All-dielectric metasurfaces are usually limited because of their static functionality and small scale.In this paper,we use an easy nanofabrication technique to fabricate all-dielectric metasurfaces with the advantages of having dynamic tunability and a large area.Using an anodized aluminum oxide(AAO)template as an evaporation mask,a large-area metasurface embedded in polydimethylsiloxane(PDMS)(>2 cm^(2))is fabricated.The metasurface exhibits remarkable electric dipole(ED)and magnetic dipole(MD)resonances.Based on the solvent-swelling effect of PDMS in 20%toluene,the ED/MD resonance peak shifts dynamically∼40 nm to red.So far,to the best of our knowledge,a large-area metasurface embedded in PDMS and achieved by using the AAO template method has not appeared.展开更多
The far-field imaging properties of a high index microsphere lens spatially separated from the object are experimentally studied. Our experimental results show that, for a Blu-ray disk whose spacing is 300 nm, the hig...The far-field imaging properties of a high index microsphere lens spatially separated from the object are experimentally studied. Our experimental results show that, for a Blu-ray disk whose spacing is 300 nm, the high index microsphere lens also can discern the patterns of the object sample when the distance between the lens and the object is up to 5.4 μm. When the distance is increased from 0 to 5.4 μm, for the microsphere lens with a diameter of 24 μm, the lateral magnification increases from 3.5× to 5.5×, while the field of view decreases from 5.1 to 3.0 μm. By varying the distance between the lens and the object, the optical image can be optimized. We also indicate that the far-field imaging capability of a high index microsphere lens is dependent on the electromagnetic field intensityprofile of the photonic nanojet under different positions of the microsphere lens.展开更多
基金financially supported by the National Natural Science Foundation of China(No.62075040)National Key Research and Development Program of China(No.2021YFF0701100)。
文摘All-dielectric metasurfaces are usually limited because of their static functionality and small scale.In this paper,we use an easy nanofabrication technique to fabricate all-dielectric metasurfaces with the advantages of having dynamic tunability and a large area.Using an anodized aluminum oxide(AAO)template as an evaporation mask,a large-area metasurface embedded in polydimethylsiloxane(PDMS)(>2 cm^(2))is fabricated.The metasurface exhibits remarkable electric dipole(ED)and magnetic dipole(MD)resonances.Based on the solvent-swelling effect of PDMS in 20%toluene,the ED/MD resonance peak shifts dynamically∼40 nm to red.So far,to the best of our knowledge,a large-area metasurface embedded in PDMS and achieved by using the AAO template method has not appeared.
基金financial support for this research from the Doctoral Fund of Ministry of Education of China (No. 20133207110007)the National Natural Science Foundation of China (No. 61475073)
文摘The far-field imaging properties of a high index microsphere lens spatially separated from the object are experimentally studied. Our experimental results show that, for a Blu-ray disk whose spacing is 300 nm, the high index microsphere lens also can discern the patterns of the object sample when the distance between the lens and the object is up to 5.4 μm. When the distance is increased from 0 to 5.4 μm, for the microsphere lens with a diameter of 24 μm, the lateral magnification increases from 3.5× to 5.5×, while the field of view decreases from 5.1 to 3.0 μm. By varying the distance between the lens and the object, the optical image can be optimized. We also indicate that the far-field imaging capability of a high index microsphere lens is dependent on the electromagnetic field intensityprofile of the photonic nanojet under different positions of the microsphere lens.
