Since the start of the 21st century,health issues caused by exposure to geological materials,such as heavy metal pollution and/or imbalances in essential elements,have consistently affected about one billion people wo...Since the start of the 21st century,health issues caused by exposure to geological materials,such as heavy metal pollution and/or imbalances in essential elements,have consistently affected about one billion people worldwide.In response to this critical problem,the field of Medical Geology has developed through collaborative efforts from experts in various disciplines,including geologists,environmental scientists,biologists,biochemists,toxicologists,epidemiologists,and public health professionals.展开更多
Light manipulation and control are essential in various contemporary technologies,and as these technologies evolve,the demand for miniaturized optical components increases.Planar-lens technologies,such as metasurfaces...Light manipulation and control are essential in various contemporary technologies,and as these technologies evolve,the demand for miniaturized optical components increases.Planar-lens technologies,such as metasurfaces and difractive optical elements,have gained attention in recent years for their potential to dramatically reduce the thickness of traditional refractive optical systems.However,their fabrication,particularly for visible wavelengths,involves complex and costly processes,such as high-resolution lithography and dry-etching,which has limited their availability.In this study,we present a simplifed method forfabricating visible Fresnel zone plate(FZP)planar lenses,a type of diffractive optical element,using an i-line stepper and a special photoresist(color resist)that only necessitates coating,exposure,and development,eliminating the need for etching or other post-processing steps.We fabricated visible FZp lens patterns using conventional photolithography equipment on 8-inch silica glass wafers,and demonstrated focusing of 550 nm light to a diameter of 1.1μm with a focusing efficiency of 7.2%.Numerical simulations showed excellent agreement with experimental results,confirming the high precision and designability of our method.Our lenses were also able to image objects with features down to 1.1μm,showcasing their potential for practical applications in imaging.Our method is a cost-effective,simple,and scalable solution for mass production of planar lenses and other optical components operating in the visible region.It enables the development of advanced,miniaturized optical systems to meet modern technology demand,making it a valuable contribution to optical component manufacturing.展开更多
文摘Since the start of the 21st century,health issues caused by exposure to geological materials,such as heavy metal pollution and/or imbalances in essential elements,have consistently affected about one billion people worldwide.In response to this critical problem,the field of Medical Geology has developed through collaborative efforts from experts in various disciplines,including geologists,environmental scientists,biologists,biochemists,toxicologists,epidemiologists,and public health professionals.
文摘Light manipulation and control are essential in various contemporary technologies,and as these technologies evolve,the demand for miniaturized optical components increases.Planar-lens technologies,such as metasurfaces and difractive optical elements,have gained attention in recent years for their potential to dramatically reduce the thickness of traditional refractive optical systems.However,their fabrication,particularly for visible wavelengths,involves complex and costly processes,such as high-resolution lithography and dry-etching,which has limited their availability.In this study,we present a simplifed method forfabricating visible Fresnel zone plate(FZP)planar lenses,a type of diffractive optical element,using an i-line stepper and a special photoresist(color resist)that only necessitates coating,exposure,and development,eliminating the need for etching or other post-processing steps.We fabricated visible FZp lens patterns using conventional photolithography equipment on 8-inch silica glass wafers,and demonstrated focusing of 550 nm light to a diameter of 1.1μm with a focusing efficiency of 7.2%.Numerical simulations showed excellent agreement with experimental results,confirming the high precision and designability of our method.Our lenses were also able to image objects with features down to 1.1μm,showcasing their potential for practical applications in imaging.Our method is a cost-effective,simple,and scalable solution for mass production of planar lenses and other optical components operating in the visible region.It enables the development of advanced,miniaturized optical systems to meet modern technology demand,making it a valuable contribution to optical component manufacturing.
