Electromagnetic coupling via an evanescent field or radiative wave is a primary characteristic of light,allowing optical signal/power transfer in a photonic circuit but limiting integration density.A leaky mode,which ...Electromagnetic coupling via an evanescent field or radiative wave is a primary characteristic of light,allowing optical signal/power transfer in a photonic circuit but limiting integration density.A leaky mode,which combines both evanescent field and radiative wave,causes stronger coupling and is thus considered not ideal for dense integration.Here we show that a leaky oscillation with anisotropic perturbation rather can achieve completely zero crosstalk realized by subwavelength grating(SWG)metamaterials.The oscillating fields in the SWGs enable coupling coefficients in each direction to counteract each other,resulting in completely zero crosstalk.We experimentally demonstrate such an extraordinarily low coupling between closely spaced identical leaky SWG waveguides,suppressing the crosstalk by≈40 dB compared to conventional strip waveguides,corresponding to≈100 times longer coupling length.This leaky-SWG suppresses the crosstalk of transverse–magnetic(TM)mode,which is challenging due to its low confinement,and marks a novel approach in electromagnetic coupling applicable to other spectral regimes and generic devices.展开更多
Concentrically distributed silicon photonic grating arrays generate long-range Besse-Gaussian beams,enabling rotational and range measurements over obstacles.This compact and mass-producible chip unlocks new potential...Concentrically distributed silicon photonic grating arrays generate long-range Besse-Gaussian beams,enabling rotational and range measurements over obstacles.This compact and mass-producible chip unlocks new potentials for long-range sensing and applications.展开更多
Integration of photonic chips with millimeter-scale atomic,micromechanical,chemical,and biological systems can advance science and enable new miniaturized hybrid devices and technology.Optical interaction via small ev...Integration of photonic chips with millimeter-scale atomic,micromechanical,chemical,and biological systems can advance science and enable new miniaturized hybrid devices and technology.Optical interaction via small evanescent volumes restricts performance in applications such as gas spectroscopy,and a general ability to photonically access optical fields in large free-space volumes is desired.However,conventional inverse tapers and grating couplers do not directly scale to create wide,high-quality collimated beams for low-loss diffraction-free propagation over many millimeters in free space,necessitating additional bulky collimating optics and expensive alignment.Here,we develop an extreme mode converter,which is a compact planar photonic structure that efficiently couples a 300 nm×250 nm silicon nitride high-index single-mode waveguide to a well-collimated near surface-normal Gaussian beam with an≈160μm waist,which corresponds to an increase in the modal area by a factor of>105.The beam quality is thoroughly characterized,and propagation over 4mm in free space and coupling back into a single-mode photonic waveguide with low loss via a separate identical mode converter is demonstrated.To achieve low phase error over a beam area that is>100×larger than that of a typical grating coupler,our approach separates the two-dimensional mode expansion into two sequential separately optimized stages,which create a fully expanded and well-collimated Gaussian slab mode before out-coupling it into free space.Developed at 780 nm for integration with chip-scale atomic vapor cell cavities,our design can be adapted for visible,telecommunication,or other wavelengths.The technique can be expanded to more arbitrary phase and intensity control of both large-diameter,free-space optical beams and wide photonic slab modes.展开更多
基金This material is based upon work supported by the National Science Foundation under Grant No.2144568 and No.1930784This work was performed,in part,at the Center for Integrated Nanotechnologies(CINT),an Office of Science User Facility operated for the U.S.Department of Energy Office of Science by Los Alamos National Laboratory and Sandia National Laboratories.This work was partially supported by the National Research Foundation of Korea(NRF)funded by the Korea government(MSIT)(No.RS2023-00210997).S.K.acknowledge the support from the KAIST new faculty research fund.
文摘Electromagnetic coupling via an evanescent field or radiative wave is a primary characteristic of light,allowing optical signal/power transfer in a photonic circuit but limiting integration density.A leaky mode,which combines both evanescent field and radiative wave,causes stronger coupling and is thus considered not ideal for dense integration.Here we show that a leaky oscillation with anisotropic perturbation rather can achieve completely zero crosstalk realized by subwavelength grating(SWG)metamaterials.The oscillating fields in the SWGs enable coupling coefficients in each direction to counteract each other,resulting in completely zero crosstalk.We experimentally demonstrate such an extraordinarily low coupling between closely spaced identical leaky SWG waveguides,suppressing the crosstalk by≈40 dB compared to conventional strip waveguides,corresponding to≈100 times longer coupling length.This leaky-SWG suppresses the crosstalk of transverse–magnetic(TM)mode,which is challenging due to its low confinement,and marks a novel approach in electromagnetic coupling applicable to other spectral regimes and generic devices.
文摘Concentrically distributed silicon photonic grating arrays generate long-range Besse-Gaussian beams,enabling rotational and range measurements over obstacles.This compact and mass-producible chip unlocks new potentials for long-range sensing and applications.
基金support under the Cooperative Research Agreement between the University of Maryland and the National Institute of Standards and Technology Center for Nanoscale Science and Technology,Award 70NANB10H193,through the University of Maryland.
文摘Integration of photonic chips with millimeter-scale atomic,micromechanical,chemical,and biological systems can advance science and enable new miniaturized hybrid devices and technology.Optical interaction via small evanescent volumes restricts performance in applications such as gas spectroscopy,and a general ability to photonically access optical fields in large free-space volumes is desired.However,conventional inverse tapers and grating couplers do not directly scale to create wide,high-quality collimated beams for low-loss diffraction-free propagation over many millimeters in free space,necessitating additional bulky collimating optics and expensive alignment.Here,we develop an extreme mode converter,which is a compact planar photonic structure that efficiently couples a 300 nm×250 nm silicon nitride high-index single-mode waveguide to a well-collimated near surface-normal Gaussian beam with an≈160μm waist,which corresponds to an increase in the modal area by a factor of>105.The beam quality is thoroughly characterized,and propagation over 4mm in free space and coupling back into a single-mode photonic waveguide with low loss via a separate identical mode converter is demonstrated.To achieve low phase error over a beam area that is>100×larger than that of a typical grating coupler,our approach separates the two-dimensional mode expansion into two sequential separately optimized stages,which create a fully expanded and well-collimated Gaussian slab mode before out-coupling it into free space.Developed at 780 nm for integration with chip-scale atomic vapor cell cavities,our design can be adapted for visible,telecommunication,or other wavelengths.The technique can be expanded to more arbitrary phase and intensity control of both large-diameter,free-space optical beams and wide photonic slab modes.