Advanced Photonics Live Streaming | Programmable metasurfaces: from time-varying orbital angular momentum to quantum algorithms
On the Cover: A comparison of cross-correlation based and phase-correlation based image registration algorithms for optical coherence tomographic angiography
On the Cover: On-chip source-device-independent quantum random number generator
On the Cover: Grating-free autofocus for single-pixel microscopic imaging
On the Cover:  Silicon photonic spectrometer with multiple customized wavelength bands

Large field of view is highly demanded for disease diagnosis in clinical applications of optical coherence tomography (OCT) and OCT angiography (OCTA) imaging. Due to the limits on optical scanning range, scanning speed, or data processing speed, only a relatively small region could be acquired and processed for most of current clinical OCT systems at one time, and generate a mosaic image of multiple adjacent small-region images with registration algorithms for disease analysis. In this work, we propose a dual-cross-correlation based translation and rotation registration (DCCTRR) algorithm for wild range OCTA imaging, which performs cross-correlation in both polarcoordinate images and Cartesian-coordinate images to calculate rotation and translation difference respectively. The performance of the proposed method is compared to standard Fourier-Merlin-transform algorithm and the results quantitatively demonstrate that the proposed method is able to align OCTA images with a lower overlap-rate, which could improve the scanning efficiency of large-scale imaging in clinical applications

Device-Independence is the ultimate goal of the realistic security of quantum information, but violating Bells inequality is difficult and complex. We have implemented the first on-chip SDI-QRNG in the whole DI/SDI field, paving the way for large-scale secure utilization of quantum resources at room temperature.

An ultrafast autofocus method for microscopy by Fourier single-pixel imaging via maximizing frequency component magnitude. It is imaging-free and is derived from the physical mechanism, making it highly attractive for autofocusing transparent samples under non-visible illumination.

Silicon photonic spectrometer with multiple customized wavelength-bands incorporated with wideband/narrowband optical filters shows great potential for various applications, including gas monitors, wearable biosensors, portable spectral-domain optical coherence tomography and so on.

On the Cover
Research Progress on Preparation of Three-Dimensional Micro-Nano Connected Structures in Transparent Materials by Femtosecond Laser Material Reduction Method
With the continuous development of medicine, optics, chemistry, communication and other fields, various micro total analysis system, lab-on-a-chip, micro electro mechanical systems and high-precision micro-nano devices began to appear and are gradually used. Most of these systems or structures are realized by preparing three-dimensional micro-nano
Laser & Optoelectronics Progress
  • Sep. 13, 2024
  • Vol. 60, Issue 21 (2023)
On the Cover
Applications of Non-Diffracting Beams in Biological Microscopic Imaging
Non-diffracting beams have attracted attention in recent years due to their unique properties, such as diffraction-free propagation and self-repairing and self-accelerating ability, which make them promising candidates for microscopic imaging applications. Non-diffraction beams can suppress beam diffraction during propagation, thereby improving the
Laser & Optoelectronics Progress
  • Sep. 13, 2024
  • Vol. 60, Issue 20 (2023)
On the Cover
Effect of Pulse Duration on Laser-Induced Forward Transfer of Microdroplets
Laser-induced forward transfer has application prospects in three-dimensional metal microstructure printing. Pulse duration is a critical factor that influences the droplet transfer behavior, but droplet generation and deposition behavior under different pulse durations are unclear at present. In this study, 500 nm copper films were used as the res
Laser & Optoelectronics Progress
  • Sep. 13, 2024
  • Vol. 60, Issue 19 (2023)
On the Cover
Novel Optically Controlled GaAs/Side-Polished Terahertz Fiber Modulator
As an important device for the application of terahertz technology, the terahertz modulator has a wide application prospect in the fields of terahertz communication, imaging, and sensing. However, current terahertz modulators exhibit problems, such as low modulation depth, narrow operating bandwidth, and poor stability. This restricts further promo
Laser & Optoelectronics Progress
  • Sep. 13, 2024
  • Vol. 60, Issue 18 (2023)
On the Cover
Continuous-Wave Terahertz In-Line Digital Holography Based on Physics-Enhanced Deep Neural Network
Terahertz (THz) in-line digital holography is a promising full-field, lens-free, and quantitative phase-contrast imaging method with an extremely compact and stable optical configuration. Hence, it is suitable for the application of THz waves. However, the inherent twin-image problem can impair the quality of its reconstructions. In this study, a n
Laser & Optoelectronics Progress
  • Sep. 13, 2024
  • Vol. 60, Issue 18 (2023)
Newest Articles
Rapid diagnosis of femtosecond laser filament by single laser shot-induced acoustic pulses [Invited]

Due to the promising applications of femtosecond laser filamentation in remote sensing, great demands exist for diagnosing the spatiotemporal dynamics of

Due to the promising applications of femtosecond laser filamentation in remote sensing, great demands exist for diagnosing the spatiotemporal dynamics of filamentation. However, until now, the rapid and accurate diagnosis of a femtosecond laser filament remains a severe challenge. Here, a novel filament diagnosing method is proposed, which can measure the longitudinal spatial distribution of the filament by a single laser shot-induced acoustic pulse. The dependences of the point-like plasma acoustic emission on the detection distance and angle are obtained experimentally. The results indicate that the temporal profile of the acoustic wave is independent of the detection distance and detection angle. Using the measured relation among the acoustic emission and the detection distance and angle, a single measurement of the acoustic emission generated by a single laser pulse can diagnose the spatial distribution of the laser filament through the Wiener filter deconvolution (WFD) algorithm. The results obtained by this method are in good agreement with those of traditional point-by-point acoustic diagnosis methods. These findings provide a new solution and idea for the rapid diagnosis of filament, thereby laying a firm foundation for femtosecond laser filament-based promising applications.show less

  • Sep.13,2024
  • Chinese Optics Letters,Vol. 22, Issue 9
  • 090010 (2024)
Experimental determination of effective light transport properties in fully anisotropic media

Structurally anisotropic materials are ubiquitous in several application fields, yet their accurate optical characterization remains challenging due to th

Structurally anisotropic materials are ubiquitous in several application fields, yet their accurate optical characterization remains challenging due to the lack of general models linking their scattering coefficients to the macroscopic transport observables and the need to combine multiple measurements to retrieve their direction-dependent values. Here, we present an improved method for the experimental determination of light-transport tensor coefficients from the diffusive rates measured along all three directions, based on transient transmittance measurements and a generalized Monte Carlo model. We apply our method to the characterization of light-transport properties in two common anisotropic materials—polytetrafluoroethylene tape and paper—highlighting the magnitude of systematic deviations that are typically incurred when neglecting anisotropy.show less

  • Sep.13,2024
  • Advanced Photonics Nexus,Vol. 3, Issue 5
  • 056017 (2024)
Multiplane quantitative phase imaging using a wavelength-multiplexed diffractive optical processor

Quantitative phase imaging (QPI) is a label-free technique that provides optical path length information for transparent specimens, finding utility in bio

Quantitative phase imaging (QPI) is a label-free technique that provides optical path length information for transparent specimens, finding utility in biology, materials science, and engineering. Here, we present QPI of a three-dimensional (3D) stack of phase-only objects using a wavelength-multiplexed diffractive optical processor. Utilizing multiple spatially engineered diffractive layers trained through deep learning, this diffractive processor can transform the phase distributions of multiple two-dimensional objects at various axial positions into intensity patterns, each encoded at a unique wavelength channel. These wavelength-multiplexed patterns are projected onto a single field of view at the output plane of the diffractive processor, enabling the capture of quantitative phase distributions of input objects located at different axial planes using an intensity-only image sensor. Based on numerical simulations, we show that our diffractive processor could simultaneously achieve all-optical QPI across several distinct axial planes at the input by scanning the illumination wavelength. A proof-of-concept experiment with a 3D-fabricated diffractive processor further validates our approach, showcasing successful imaging of two distinct phase objects at different axial positions by scanning the illumination wavelength in the terahertz spectrum. Diffractive network-based multiplane QPI designs can open up new avenues for compact on-chip phase imaging and sensing devices.show less

  • Sep.11,2024
  • Advanced Photonics,Vol. 6, Issue 5
  • 056003 (2024)
Active broadband unidirectional focusing of terahertz surface plasmons based on a liquid-crystal-integrated on-chip metadevice

Surface plasmons have been given high expectations in terahertz (THz) on-chip photonics with highly bound integrated transmission and on-chip wavefront en

Surface plasmons have been given high expectations in terahertz (THz) on-chip photonics with highly bound integrated transmission and on-chip wavefront engineering. However, most surface plasmonic coupling strategies with tailorable polarization-dependent features are challenged in broadband propagation and dynamic manipulation. In this work, a liquid crystal (LC)-integrated surface plasmonic metadevice based on arc-arrayed pair-slit resonators (APSRs) is demonstrated. The mirror-symmetry structures of this metadevice achieve the spin-selective unidirectional achromatic focusing, of which the broadband characteristic is supported by containing multiple APSRs with slits of different sizes corresponding to different excitation frequencies. Moreover, arc radii are precisely designed to meet the phase matching condition of constructive interference, so that the operating frequency of this on-chip metadevice is broadened to 0.33–0.60 THz. Furthermore, the LC integration provides the active energy distribution between the left and right focal spots, and the actual modulation depth reaches up to 73%. These THz active, wideband, on-chip manipulation mechanisms and their devices are of great significance for THz-integrated photonic communication, information processing, and highly sensitive sensing.show less

  • Sep.09,2024
  • Photonics Research,Vol. 12, Issue 10
  • 2148 (2024)
Advanced Photonics Photonics Insights

In this paper, to reduce the damage or absorption caused by radiation to optical fibers, lightweight and flexible anti-radiation films based on optical precision deposition technology are studie

In this paper, to reduce the damage or absorption caused by radiation to optical fibers, lightweight and flexible anti-radiation films based on optical precision deposition technology are studied. At first, anti-radiation composite thin films based on Kapton, ITO and Cu (or Al) are designed and home-made with different structures. Subsequently, polarization-maintaining (PM) Yb-doped fiber samples protected by these different kinds of anti-radiation films are irradiated with a dose of ∼150 kGy. At last, we comparatively investigate: 1) their radiation-induced attenuation (RIA) of these PM Yb-fiber samples, and 2) the lasing performance (threshold and slope efficiency) and gain peformance of 1064 nm fiber laser and amplifier using these irradiated PM Yb-fibers as gain medium, respectively. The results show that such film can reduce the RIA of the irradiated Yb-fiber by up to 3.26 dB/m and increase the output power by up to 75.3% at most. In addition, we also studies the optical recovery of the PM Yb-fibers after radiation.show less

  • Sep.13,2024
  • Chinese Optics Letters,Vol. 23, Issue 3
  • (2025)

Range-gated imaging has the advantages of long imaging distance, high signal-to-noise ratio, and good environmental adaptability. However, conventional range-gated imaging utilizes a single lase

Range-gated imaging has the advantages of long imaging distance, high signal-to-noise ratio, and good environmental adaptability. However, conventional range-gated imaging utilizes a single laser pulse illumination modality, which can only resolve single depth of ranging in one shot. Three-dimensional (3D) imaging has to be obtained from multiple shots, which limits its real-time performance. Here, an approach of rangegated imaging using a specific double-pulse sequence is proposed to overcome this limitation. With the help of calibrated double-pulse range-intensity profile, the depth of static targets can be calculated from measurement of a single-shot. Moreover, the double-pulse approach is beneficial for real-time depth estimation of dynamic targets. Experimental results indicate that, compared to conventional approach, both the depth of field and depth resolution are increased by 1.36 and 2.20 times, respectively. It is believed that the proposed double-pulse approach provides a potential new paradigm for range-gated 3D imaging.show less

  • Sep.13,2024
  • Chinese Optics Letters,Vol. 23, Issue 3
  • (2025)

In this work, we propose pattern self-referenced single-pixel common-path holography (PSSCH), which can be realized using either the digital-micromirror-device (DMD) based off-axis scheme or the

In this work, we propose pattern self-referenced single-pixel common-path holography (PSSCH), which can be realized using either the digital-micromirror-device (DMD) based off-axis scheme or the DMD-based phase-shifting approach, sharing the same experimental setup, to do wavefront reconstructions. In the method, each modulation pattern is elaborately encoded to be not only utilized to do the sampling of the target wavefront but also used to dynamically introduce the reference light for the single-pixel common-path holographic detection. As such it does not need to intentionally introduce a static reference light, resulting in it making full use of the pixel resolution of the modulation patterns and suppressing dynamically varying noises. Experimental demonstrations show that the proposed method not only can obtain a larger FOV than that of the peripheral-referenced approach but also can achieve a higher imaging resolution than that of the checkerboard-referenced approach, and the phase-shifting PSSCH performs better than the off-axis PSSCH on imaging fidelity while the imaging speed of the latter is several times faster. Further, we demonstrate our method to do wavefront imaging of a biological sample as well as to do phase detection of a physical lens, and the experimental results suggest its effectiveness in the applications.show less

  • Sep.13,2024
  • Advanced Photonics Nexus

Fiber Bragg grating-based Raman oscillators are capable of achieving targeted frequency conversion and brightness enhancement through the provision of gain via stimulated Raman scattering across

Fiber Bragg grating-based Raman oscillators are capable of achieving targeted frequency conversion and brightness enhancement through the provision of gain via stimulated Raman scattering across a broad gain spectrum. This capability renders them an exemplary solution for the acquisition of high-brightness, specialized-wavelength lasers. Nonetheless, the output power of Raman oscillators is typically limited to several hundred watts, primarily due to limitations in injectable pump power and the influence of higher-order Raman effects, which is inadequate for certain application demands. In this study, we introduce an innovative approach by employing a graded-index fiber with a core diameter of 150µm as the Raman gain medium. This strategy not only enhances the injectable pump power but also mitigates higher-order Raman effects. Consequently, we have successfully attained an output power of 1780W for the all-fiber Ramanlaser at 1130nm, representing the highest output power in Raman fiber oscillators with any configuration reported to date.show less

  • Sep.12,2024
  • High Power Laser Science and Engineering