Planar graphene metalens has demonstrated advantages of ultrathin thickness(200 nm),high focusing resolution(343 nm)and efficiency(>32%)and robust mechanical strength and flexibility.However,diffraction-limited ima...Planar graphene metalens has demonstrated advantages of ultrathin thickness(200 nm),high focusing resolution(343 nm)and efficiency(>32%)and robust mechanical strength and flexibility.However,diffraction-limited imaging with such a graphene metalens has not been realized,which holds the key to designing practical integrated imaging systems.In this work,the imaging rule for graphene metalenses is first derived and theoretically verified by using the Rayleigh-Sommerfeld diffraction theory to simulate the imaging performance of the 200 nm ultrathin graphene metalens.The imaging rule is applicable to graphene metalenses in different immersion media,including water or oil.Based on the theoretical prediction,high-resolution imaging using the graphene metalens with diffraction-limited resolution(500 nm)is demonstrated for the first time.This work opens the possibility for graphene metalenses to be applied in particle tracking,microfluidic chips and biomedical devices.展开更多
The realization of a high numerical aperture(NA) fiber lens is critical for achieving high imaging resolution in endoscopes, enabling subwavelength operation in optical tweezers and high efficiency coupling between op...The realization of a high numerical aperture(NA) fiber lens is critical for achieving high imaging resolution in endoscopes, enabling subwavelength operation in optical tweezers and high efficiency coupling between optical fibers and photonic chips. However, it remains challenging with conventional design and fabrication. Here we propose an ultrathin(400 nm) graphene oxide(GO) film lens fabricated in situ on a standard single-mode fiber facet using the femtosecond laser direct writing technique. An extremely high NA of 0.89 is achieved with a near diffraction-limited focal spot(FWHM = 0.68λ), which is verified theoretically and experimentally. The diameter of the fabricated fiber GO lens is as small as 12 μm with no beam expansion structure. The proposed fiber GO lens is promising for applications such as super-resolution imaging, compact optical tweezers, medical endoscopes,and on-chip integration.展开更多
Water electrolysis is to split water into hydrogen and oxygen using electricity as the driving force.To obtain low-cost hydrogen in a large scale,it is critical to develop electrocatalysts based on earth abundant elem...Water electrolysis is to split water into hydrogen and oxygen using electricity as the driving force.To obtain low-cost hydrogen in a large scale,it is critical to develop electrocatalysts based on earth abundant elements with a high efficiency.This computational work started with Cobalt on CoTh_(2)C)_(6)surface as the active site,CoTa_(2)O_(6)/Graphene heterojunctions have been explored as potential oxygen evolution reaction(OER)catalysts through density functional theory(DFT).We demonstrated that the electron transfer(_(6))from CoTa_(2)C)_(6)to graphene substrate can be utilized to boost the reactivity of Co-site,leading to an OER overpotential as low as 0.30 V when N-doped graphene is employed.Our findings offer novel design of heterojunctions as high performance OER catalysts.展开更多
Optical beams carrying orbital angular momentum(OAM)play an important role in micro-/nanoparticle manipulation and information multiplexing in optical communications.Conventional OAM generation setups require bulky op...Optical beams carrying orbital angular momentum(OAM)play an important role in micro-/nanoparticle manipulation and information multiplexing in optical communications.Conventional OAM generation setups require bulky optical elements and are unsuitable for on-chip integration.OAM generators based on metasurfaces can achieve ultracompact designs.However,they generally have limited working bandwidth and require complex designs and multistep time-consuming fabrication processes.In comparison,graphene metalenses based on the diffraction principle have simple designs and can be fabricated by laser nanoprinting in a single step.Here,we demonstrate that a single ultrathin(200 nm)graphene OAM metalens can integrate OAM generation and high-resolution focusing functions in a broad bandwidth,covering the entire visible wavelength region.Broadband graphene OAM metalenses with flexibly controlled topological charges are analytically designed using the detour phase method considering the dispersionless feature of the graphene material and fabricated using ultrafast laser nanoprinting.The experimental results agree well with the theoretical predictions,which demonstrate the accuracy of the design method.The broadband graphene OAM metalenses can find broad applications in miniaturized and integrated photonic devices enabled by OAM beams.展开更多
Ultrathin flat optics allow control of light at the subwavelength scale that is unmatched by traditional refractive optics.To approach the atomically thin limit,the use of 2D materials is an attractive possibility due...Ultrathin flat optics allow control of light at the subwavelength scale that is unmatched by traditional refractive optics.To approach the atomically thin limit,the use of 2D materials is an attractive possibility due to their high refractive indices.However,achievement of diffraction-limited focusing and imaging is challenged by their thickness-limited spatial resolution and focusing efficiency.Here we report a universal method to transform 2D monolayers into ultrathin flat lenses.Femtosecond laser direct writing was applied to generate local scattering media inside a monolayer,which overcomes the longstanding challenge of obtaining sufficient phase or amplitude modulation in atomically thin 2D materials.We achieved highly efficient 3D focusing with subwavelength resolution and diffractionlimited imaging.The high focusing performance even allows diffraction-limited imaging at different focal positions with varying magnifications.Our work paves the way for downscaling of optical devices using 2D materials and reports an unprecedented approach for fabricating ultrathin imaging devices.展开更多
Particle nanotracking(PNT)is highly desirable in lab-on-a-chip systems for flexible and convenient multiparameter measurement.An ultrathin flat lens is the preferred imaging device in such a system,with the advantage ...Particle nanotracking(PNT)is highly desirable in lab-on-a-chip systems for flexible and convenient multiparameter measurement.An ultrathin flat lens is the preferred imaging device in such a system,with the advantage of high focusing performance and compactness.However,PNT using ultrathin flat lenses has not been demonstrated so far because PNT requires the clear knowledge of the relationship between the object and image in the imaging system.Such a relationship still remains elusive in ultrathin flat lens-based imaging systems because they operate based on diffraction rather than refraction.In this paper,we experimentally reveal the imaging relationship of a graphene metalens using nanohole arrays with micrometer spacing.The distance relationship between the object and image as well as the magnification ratio is acquired with nanometer accuracy.The measured imaging relationship agrees well with the theoretical prediction and is expected to be applicable to other ultrathin flat lenses based on the diffraction principle.By analyzing the high-resolution images from the graphene metalens using the imaging relationship,3D trajectories of particles with high position accuracy in PNT have been achieved.The revealed imaging relationship for metalenses is essential in designing different types of integrated optical systems,including digital cameras,microfluidic devices,virtual reality devices,telescopes,and eyeglasses,and thus will find broad applications.展开更多
The electrochemical reduction of carbon dioxide(CO_(2))into value‐added fuels and chemicals presents a sustainable route to alleviate CO_(2) emissions,promote carbon‐neutral cycles and reduce the dependence on fossi...The electrochemical reduction of carbon dioxide(CO_(2))into value‐added fuels and chemicals presents a sustainable route to alleviate CO_(2) emissions,promote carbon‐neutral cycles and reduce the dependence on fossil fuels.Considering the thermodynamic stability of the CO_(2) molecule and sluggish reaction kinetics,it is still a challenge to design highly efficient electrocatalysts for the CO_(2) reduction reaction(CO_(2)RR).It has been found that the surface and interface chemistry of electrocatalysts can modulate the electronic structure and increase the active sites,which is favorable for CO_(2) adsorption,electron transfer,mass transport,and optimizing adsorption strength of reaction intermediates.However,the effect of surface and interface chemistry on metal‐free electrocatalysts(MFEs)for CO_(2)RR has not been comprehensively reviewed.Herein,we discuss the importance of the surface and interface chemistry on MFEs for improving the electrochemical CO_(2)RR performance based on thermodynamic and kinetic views.The fundamentals and challenges of CO_(2)RR are firstly presented.Then,the recent advances of the surface and interface chemistry in improving reaction rate and overcoming reaction constraints are reviewed from regulating electronic structure,active sites,electron transfer,mass transport,and intermediate binding energy.Finally,the research challenges and prospects are proposed to suggest the future designs of advanced MFEs in CO_(2)RR.展开更多
Flat lenses thinner than a wavelength promise to replace conventional refractive lenses in miniaturized optical systems.However,Fresnel zone plate flat lens designs require dense annuli,which significantly challenges ...Flat lenses thinner than a wavelength promise to replace conventional refractive lenses in miniaturized optical systems.However,Fresnel zone plate flat lens designs require dense annuli,which significantly challenges nanofabrication resolution.Herein,we propose a new implementation of detour phase graphene flat lens with flexible annular number and width.Several graphene metalenses demonstrated that with a flexible selection of the line density and width,the metalenses can achieve the same focal length without significant distortions.This will significantly weaken the requirement of the nanofabrication system which is important for the development of large-scale flat lenses in industry applications.展开更多
Light beams carrying orbital angular momentum(OAM)have inspired various advanced applications,and such abundant practical applications in turn demand complex generation and manipulation of optical vortices.Here,we pro...Light beams carrying orbital angular momentum(OAM)have inspired various advanced applications,and such abundant practical applications in turn demand complex generation and manipulation of optical vortices.Here,we propose a multifocal graphene vortex generator,which can produce broadband angular momentum cascade containing continuous integer non-diffracting vortex modes.Our device naturally embodies a continuous spiral slit vortex generator and a zone plate,which enables the generation of high-quality continuous vortex modes with deep depths of foci.Meanwhile,the generated vortex modes can be simultaneously tuned through incident wavelength and position of the focal plane.The elegant structure of the device largely improves the design efficiency and can be fabricated by laser nanofabrication in a single step.Moreover,the outstanding property of graphene may enable new possibilities in enormous practical applications,even in some harsh environments,such as aerospace.展开更多
基金Supported by the Scholarship of China Scholarship Council (Grant No.201706030189)the Industrial Transformation Training Centres Scheme (Grant No.IC180100005)the National Natural Science Foundation of China (Grant No.61935001)
文摘Planar graphene metalens has demonstrated advantages of ultrathin thickness(200 nm),high focusing resolution(343 nm)and efficiency(>32%)and robust mechanical strength and flexibility.However,diffraction-limited imaging with such a graphene metalens has not been realized,which holds the key to designing practical integrated imaging systems.In this work,the imaging rule for graphene metalenses is first derived and theoretically verified by using the Rayleigh-Sommerfeld diffraction theory to simulate the imaging performance of the 200 nm ultrathin graphene metalens.The imaging rule is applicable to graphene metalenses in different immersion media,including water or oil.Based on the theoretical prediction,high-resolution imaging using the graphene metalens with diffraction-limited resolution(500 nm)is demonstrated for the first time.This work opens the possibility for graphene metalenses to be applied in particle tracking,microfluidic chips and biomedical devices.
基金National Natural Science Foundation of China(62275150)。
文摘The realization of a high numerical aperture(NA) fiber lens is critical for achieving high imaging resolution in endoscopes, enabling subwavelength operation in optical tweezers and high efficiency coupling between optical fibers and photonic chips. However, it remains challenging with conventional design and fabrication. Here we propose an ultrathin(400 nm) graphene oxide(GO) film lens fabricated in situ on a standard single-mode fiber facet using the femtosecond laser direct writing technique. An extremely high NA of 0.89 is achieved with a near diffraction-limited focal spot(FWHM = 0.68λ), which is verified theoretically and experimentally. The diameter of the fabricated fiber GO lens is as small as 12 μm with no beam expansion structure. The proposed fiber GO lens is promising for applications such as super-resolution imaging, compact optical tweezers, medical endoscopes,and on-chip integration.
基金support through the Australia Research Council Industrial Transformation Training Centres scheme(Grant No.IC180100005)The authors acknowledge the financial support by Guangdong Innovation Research Team for Higher Education(Grant No.2017KCXTD030)+1 种基金High-level Talents Project of Dongguan University of Technology(Grant No.KCYKYQD2017017)Engineering Research Center of None-food Biomass Efficient Pyrolysis and Utilization Technology of Guangdong Higher Education Institutes(Grant No.2016GCZX009).
文摘Water electrolysis is to split water into hydrogen and oxygen using electricity as the driving force.To obtain low-cost hydrogen in a large scale,it is critical to develop electrocatalysts based on earth abundant elements with a high efficiency.This computational work started with Cobalt on CoTh_(2)C)_(6)surface as the active site,CoTa_(2)O_(6)/Graphene heterojunctions have been explored as potential oxygen evolution reaction(OER)catalysts through density functional theory(DFT).We demonstrated that the electron transfer(_(6))from CoTa_(2)C)_(6)to graphene substrate can be utilized to boost the reactivity of Co-site,leading to an OER overpotential as low as 0.30 V when N-doped graphene is employed.Our findings offer novel design of heterojunctions as high performance OER catalysts.
基金the Australia Research Council(grant no.DP220100603,FT210100806,and FT220100559)the Industrial Transformation Training Centres scheme(grant no.IC180100005)Linkage Project scheme(LP210200345).
文摘Optical beams carrying orbital angular momentum(OAM)play an important role in micro-/nanoparticle manipulation and information multiplexing in optical communications.Conventional OAM generation setups require bulky optical elements and are unsuitable for on-chip integration.OAM generators based on metasurfaces can achieve ultracompact designs.However,they generally have limited working bandwidth and require complex designs and multistep time-consuming fabrication processes.In comparison,graphene metalenses based on the diffraction principle have simple designs and can be fabricated by laser nanoprinting in a single step.Here,we demonstrate that a single ultrathin(200 nm)graphene OAM metalens can integrate OAM generation and high-resolution focusing functions in a broad bandwidth,covering the entire visible wavelength region.Broadband graphene OAM metalenses with flexibly controlled topological charges are analytically designed using the detour phase method considering the dispersionless feature of the graphene material and fabricated using ultrafast laser nanoprinting.The experimental results agree well with the theoretical predictions,which demonstrate the accuracy of the design method.The broadband graphene OAM metalenses can find broad applications in miniaturized and integrated photonic devices enabled by OAM beams.
基金support from the Australian Research Council through the Discovery Project scheme(DP190103186)the Industrial Transformation Training Centres scheme(Grant No.IC180100005)+6 种基金support from the Australian Postgraduate Award(APA)and international postgraduate research scholarship(IPRS)support from the National Key Research&Development Program(No.2016YFA0201902)aShenzhen Nanshan District Pilotage Team Program(LHTD20170006)support from the Australian Research Council(FT150100450 and CE170100039)financial support from the A*STAR Pharos Program(grant number 1527000014,with project number R-263-000-B91-305)the National Research Foundation,Prime Minister’s Office,Singapore under its Competitive Research Program(CRP award NRF CRP22-2019-0006)the support of the National Research Foundation-Competitive Research Program(NRF-CRP21–2018–007).
文摘Ultrathin flat optics allow control of light at the subwavelength scale that is unmatched by traditional refractive optics.To approach the atomically thin limit,the use of 2D materials is an attractive possibility due to their high refractive indices.However,achievement of diffraction-limited focusing and imaging is challenged by their thickness-limited spatial resolution and focusing efficiency.Here we report a universal method to transform 2D monolayers into ultrathin flat lenses.Femtosecond laser direct writing was applied to generate local scattering media inside a monolayer,which overcomes the longstanding challenge of obtaining sufficient phase or amplitude modulation in atomically thin 2D materials.We achieved highly efficient 3D focusing with subwavelength resolution and diffractionlimited imaging.The high focusing performance even allows diffraction-limited imaging at different focal positions with varying magnifications.Our work paves the way for downscaling of optical devices using 2D materials and reports an unprecedented approach for fabricating ultrathin imaging devices.
基金Australian Research Council(DP190103186,IC180100005)China Scholarship Council(201706030189).
文摘Particle nanotracking(PNT)is highly desirable in lab-on-a-chip systems for flexible and convenient multiparameter measurement.An ultrathin flat lens is the preferred imaging device in such a system,with the advantage of high focusing performance and compactness.However,PNT using ultrathin flat lenses has not been demonstrated so far because PNT requires the clear knowledge of the relationship between the object and image in the imaging system.Such a relationship still remains elusive in ultrathin flat lens-based imaging systems because they operate based on diffraction rather than refraction.In this paper,we experimentally reveal the imaging relationship of a graphene metalens using nanohole arrays with micrometer spacing.The distance relationship between the object and image as well as the magnification ratio is acquired with nanometer accuracy.The measured imaging relationship agrees well with the theoretical prediction and is expected to be applicable to other ultrathin flat lenses based on the diffraction principle.By analyzing the high-resolution images from the graphene metalens using the imaging relationship,3D trajectories of particles with high position accuracy in PNT have been achieved.The revealed imaging relationship for metalenses is essential in designing different types of integrated optical systems,including digital cameras,microfluidic devices,virtual reality devices,telescopes,and eyeglasses,and thus will find broad applications.
基金CSIRO Energy Centre and Kick‐Start ProjectAustralian Research Council(ARC)Future Fellowships,Grant/Award Numbers:FT210100298,FT210100806+9 种基金Key Project of Scientific Research of the Education Department of Liaoning Province,Grant/Award Number:LZD201902National Natural Science Foundation of China,Grant/Award Numbers:51873085,52071171Liaoning Revitalization Talents Program‐Pan Deng Scholars,Grant/Award Numbers:XLYC1802005,XLYC2007056Industrial Transformation Training Centre,Grant/Award Number:IC180100005Shenyang Science and Technology Project,Grant/Award Number:21‐108‐9‐04veski-Study Melbourne Research Partnerships(SMRP)projectLiaoning BaiQianWan Talents Program,Grant/Award Number:LNBQW2018B0048Natural Science Fund of Liaoning Province for Excellent Young Scholars,Grant/Award Number:2019‐YQ‐04Discovery Project,Grant/Award Number:DP220100603Linkage project,Grant/Award Number:LP210100467。
文摘The electrochemical reduction of carbon dioxide(CO_(2))into value‐added fuels and chemicals presents a sustainable route to alleviate CO_(2) emissions,promote carbon‐neutral cycles and reduce the dependence on fossil fuels.Considering the thermodynamic stability of the CO_(2) molecule and sluggish reaction kinetics,it is still a challenge to design highly efficient electrocatalysts for the CO_(2) reduction reaction(CO_(2)RR).It has been found that the surface and interface chemistry of electrocatalysts can modulate the electronic structure and increase the active sites,which is favorable for CO_(2) adsorption,electron transfer,mass transport,and optimizing adsorption strength of reaction intermediates.However,the effect of surface and interface chemistry on metal‐free electrocatalysts(MFEs)for CO_(2)RR has not been comprehensively reviewed.Herein,we discuss the importance of the surface and interface chemistry on MFEs for improving the electrochemical CO_(2)RR performance based on thermodynamic and kinetic views.The fundamentals and challenges of CO_(2)RR are firstly presented.Then,the recent advances of the surface and interface chemistry in improving reaction rate and overcoming reaction constraints are reviewed from regulating electronic structure,active sites,electron transfer,mass transport,and intermediate binding energy.Finally,the research challenges and prospects are proposed to suggest the future designs of advanced MFEs in CO_(2)RR.
基金Natural Science Foundation of Guangdong Province(2016A030310130)Australia Research Council(the Discovery Project scheme)(DP190103186)+5 种基金Australian Research Council Industrial Transformation Training Centre for Functional Grains(IC180100005)National Natural Science Foundation of China(62175162)Foundation of Shenzhen Science and Technology(20200814100534001)Science,Technology and Innovation Commission of Shenzhen Municipality(KQTD20170330110444030,KQTD20180412181324255)Foundation of Guangdong Education Committee(2020KTSCX117)China Postdoctoral Science Foundation(2021M692173)。
文摘Flat lenses thinner than a wavelength promise to replace conventional refractive lenses in miniaturized optical systems.However,Fresnel zone plate flat lens designs require dense annuli,which significantly challenges nanofabrication resolution.Herein,we propose a new implementation of detour phase graphene flat lens with flexible annular number and width.Several graphene metalenses demonstrated that with a flexible selection of the line density and width,the metalenses can achieve the same focal length without significant distortions.This will significantly weaken the requirement of the nanofabrication system which is important for the development of large-scale flat lenses in industry applications.
基金the support from Advanced Research and Technology Innovation Centre(ARTIC)in National University of Singapore(R-261-518-004-720|A-0005947-1600)the Australia Research Council through the Discovery Project Scheme(DP190103186,DP220100603,and FT210100806)the Industrial Transformation Training Centre Scheme(IC180100005).
文摘Light beams carrying orbital angular momentum(OAM)have inspired various advanced applications,and such abundant practical applications in turn demand complex generation and manipulation of optical vortices.Here,we propose a multifocal graphene vortex generator,which can produce broadband angular momentum cascade containing continuous integer non-diffracting vortex modes.Our device naturally embodies a continuous spiral slit vortex generator and a zone plate,which enables the generation of high-quality continuous vortex modes with deep depths of foci.Meanwhile,the generated vortex modes can be simultaneously tuned through incident wavelength and position of the focal plane.The elegant structure of the device largely improves the design efficiency and can be fabricated by laser nanofabrication in a single step.Moreover,the outstanding property of graphene may enable new possibilities in enormous practical applications,even in some harsh environments,such as aerospace.