Journal of Infrared and Millimeter Waves

ESIT 2024: Gathering of Global Minds to Hangzhou for Cutting-Edge Infrared and Terahertz Innovation
Welcome to our new Editorial Board Members Prof. Manijeh Razeghi
Welcome to our new Editorial Board Members Dr. He Zhiping
Welcome to our new Editorial Board Members Dr. Jun Ge
Welcome to our new Editorial Board Members Dr. Ye Zhenhua
Welcome to our new Editorial Board Members Dr. Chen Fansheng

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Research on the Characteristics of Absorption Coefficient in the Low Absorption Region of InAs and GaSb Substrates Based on FTIR Spectroscopy Technology

Wangxiaozhen, TAN Zhi-yong, ZHANG Qing-ling-yun, LI Jian-mei, CHEN Yi-qiao, CAO Jun-cheng

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GaSb and InAs demonstrate significant potential photoelectric applications in mid-wave infrared (3-5 μm) and long-wave infrared (8-12 μm) spectral regions. However, their weak optical absorption properties hinder accurate determination of absorption coefficients via conventional transmission spectroscopy due to multi-pass transmission effects. This study introduces a combined reflection-transmission analysis method based on Fourier-transform infrared spectroscopy (FTIR), achieving enhancement in measurement accuracy within the low-absorption regime (α<10 cm?1). For samples with doping concentrations of ND=2.46×1016^cm-3^{(InAs) and}ND=8.76×1016^cm^-3 (GaSb), the analysis reveals that free carrier absorption in the 8-18 μm range is predominantly governed by acoustic phonon scattering and ionized impurity scattering. Notably, GaSb exhibits significantly enhanced scattering intensity compared to InAs, with a 10-fold increase in ionized impurity scattering coefficient and a 450-fold amplification in acoustic phonon scattering coefficient. The developed methodology provides a technical framework for determining absorption coefficients in low-absorption materials.
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Shortwave Infrared Polarization-based Aerial Small-UAV Target Detection via a Scale-Adaptive Local Extreme Measure

YANG Zheng-Ye, GONG Jin-Fu, XIN Jian-Qiao, WANG Shi-Yong, WU Ying-Yue, KANG Hua-Chao

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Unmanned aerial vehicle (UAV) detection holds significant value in both civilian and military domains, however, conventional infrared detection systems remain vulnerable to background clutter interference. Infrared polarization imaging technology offers a novel solution by integrating polarization data with infrared imaging. However, the differences between polarization and infrared images introduces new problems to target extraction. Therefore, we propose a new detection algorithm based on scale-adaptive local extreme measure (ALEM). The algorithm introduces an enhanced SUSAN operator to quickly extract regions of interest (ROIs) while estimating potential target scales within these regions. Then present the ALEM algorithm, which is specifically designed to exploit the unique characteristics of polarization images. The algorithm effectively measures contrast by analyzing pixel neighborhood features within polarization images. Experimental results based on real-world polarization image dataset demonstrate that: the signal-to-noise ratio gain of the algorithm is increased by 2.7 times, the background suppression factor is increased by 8.6 times, and it can run at 20 fps. It exhibits excellent detection performance, robustness, and the capability for real-time detection.
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Independent Development of a Silicon Ultra-stable Optical Reference Cavity with High-Finesse

JIAO Dong-Dong, GAO Jing, WU Pan, DENG Xue, WU Meng-Fan, ZHANG Lin-Bo, XU Guan-Jun, ZANG Qi, Cui Jie, Dong Rui-Fang, LIU Tao, QU Bo, ZHANG Shou-Gang

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This work presents the independent development of a silicon ultra-stable optical reference cavity with high-finesse. Silicon exhibits exceptional thermal stability, lower mechanical loss, and superior vibrational insensitivity. An optimized machining process effectively addresses key manufacturing challenges posed by silicon's brittleness and anisotropic properties. The three-stage polishing technology is utilized to achieve ultra-smooth surfaces with ? level roughness (RMS). The high-reflection film is produced using SiO2/Ta2O5 as the coating material via Ion Beam Sputter Deposition. A cavity linewidth measurement method demonstrates a finesse of ~340,000, comparable to top international counterparts. These results demonstrate China’s ability to independently develop high-performance silicon-based ultra-stable optical reference cavities. This advancement holds significance for precision applications like optical clocks and gravitational wave detection.
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A new algorithm for millimeter-wave cloud radar clutter rejection based on morphological improvement

LIU Qian-Chen, DI Hui-Ge, YUAN Yun, QUAN Chun-Hang, WANG Jia-Le, HOU Chen-Tao, HUA Deng-Xin

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An improved multi-feature fusion scheme is proposed to address the problem of edge signal loss in existing clutter filtering methods for millimeter-wave cloud radar. A discriminative model is constructed based on reflectivity, time and vertical continuity for preliminary clutter identification, and then a morphological binary expansion operation is introduced to generate cloud edge candidate regions, and an accurate edge determination is performed with the help of domain analysis. It is verified that this scheme can effectively filter out clutter while retaining cloud edge signals more completely, solving the problem of edge signal loss in the existing clutter filtering scheme, improving the quality of millimeter-wave cloud radar data, and providing more reliable data support for atmospheric physics research and weather forecasting.
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A method for enhancing the performance of infrared filters based on rate-modulated deposition of germanium films

LIU Bao-Jian, LI Da-Qi, DUAN Wei-Bo, YU De-Ming, CAI Qing-Yuan, YU Tian-Yan, JIANG Lin, YANG Yu-Ting, ZHUANG Qiu-Hui, ZHENG Yu-Xiang

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This study systematically investigated the influence of deposition rate on the structure, broadband optical properties (1.0–13.0 μm), and stress characteristics of Germanium (Ge) films. Additionally, a method for enhancing the performance of infrared filters based on rate-modulated deposition of Ge films was proposed. The optical absorption of Ge films in the short-wave infrared (SWIR) and long-wave infrared (LWIR) bands can be effectively reduced by modulating the deposition rate. As the deposition rate increases, the Ge films maintain an amorphous structure. The optical constants of the films in the 1.0–2.5 μm and 2.5–13.0 μm bands were precisely determined using the Cody-Lorentz model and the classical Lorentz oscillator model, respectively. Notably, higher deposition rates result in a gradual increase in the refractive index. The extinction coefficient increases with the deposition rate in the SWIR region, attributed to the widening of the Urbach tail, while it decreases in the LWIR region due to the reduced absorption caused by the Ge–O stretching mode. Additionally, the films exhibit a tensile stress that decreases with increasing deposition rate. Finally, the effectiveness of the proposed fabrication method for an infrared filter with Ge films deposited at an optimized rate was demonstrated through practical examples. This work provides theoretical and technical support for the application of Ge films in high-performance infrared filters.
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Measurement system calibration and radiation characteristic inversion based on infrared weak and small targets

liwenxiong, Shenjunli, Luzhenyu, Menshudong, Wuqingwen, Zhaoxiaoyan

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With the widespread application of infrared detection technology in fields such as military reconnaissance, aerospace monitoring, and security early warning, infrared measurement systems play a critical role in infrared detection. In response to issues such as low calibration efficiency and significant environmental interference in the calibration and radiative property inversion of infrared measurement systems, this paper proposes a calibration and radiative property inversion method based on infrared weak small targets. A small-area blackbody source is used as a controllable radiation source to project infrared targets, and deep learning networks are employed for precise identification and gray-scale extraction of infrared weak small targets. Using this, a calibration model for the measurement system is established. Experimental results show that the method demonstrates good calibration stability within the temperature range of 298 K-308 K, with the absolute error of radiative property inversion controlled within ±2 K and the relative error of inversion temperature ≤ 0.5%. Regression analysis also indicates high temperature inversion accuracy (R2>0.94). Compared to traditional methods, the proposed method balances calibration efficiency and accuracy while extending the ability to invert the temperature field of targets. This research provides an effective solution for rapid calibration and high-precision radiative property analysis of infrared weak small targets.
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Modeling and Simulation of Infrared Polarization Characteristics of Aerial Targets Based on a Hybrid Radiation Polarization Model

YAN Kun-Na, Liu Hai-Zheng, Shi Ze-Lin, Zhao Ze-Hua, Zhao Chun-Yang

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To address the need for infrared polarization detection in high-speed aerial targets, this paper presents a practical method for calculating and simulating the infrared polarization characteristics of these targets. Based on a hybrid radiative polarization model, an infrared degree of linear polarization (DoLP) calculation framework for aerial targets and an instantiation method for typical materials are developed. This model framework considers thermal emission, solar and environmental radiation reflections, and atmospheric transport effects. The deviation between the calculated and measured DoLP values for the material samples is less than 10%. Taking the high-speed SR-72 reconnaissance aircraft as an example, the simulation process is based on the reflection/radiance vector data generated by the polarization calculation model of the target material. The real-time simulation of the SR-72 target's infrared polarization characteristics is conducted with the Unity3D engine, and the image frame rate reaches 35 frames per second. The DoLP images of the SR-72 are simulated under varying conditions, including flight speed, detection band (MWIR/LWIR), and solar illumination. The variations in its polarization characteristics are subsequently analyzed. This study provides a data foundation and simulation support for infrared polarization detection and related assessment applications of aerial targets.
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Microwave/millimeter-wave multiband transmission lines, antennas, and passive components with large frequency ratios for integrated sensing and communication applications

LEl Bo-Jie, LI Jin, CHEN Si-Cheng, YAN Shu-Yao, YUAN Tao

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The fundamental concepts, operating principles, and recent advancements in integrated sensing and communication (ISAC) are presented. A comprehensive review of multiband and large-frequency-ratio micro-wave/millimeter-wave transmission lines, antennas, and passive components—primarily filters and couplers—that are currently suitable for ISAC application scenarios is provided. Various implementation strategies and fabrication techniques for these multiband and high-frequency-ratio structures are comparatively analyzed. The technical characteristics, RF performance, and respective advantages and limitations of different design approaches are systematically summarized. This review offers a diverse and in-depth reference for the continued development of high-performance microwave/millimeter-wave front-end components tailored for ISAC applications.
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The Epitaxial Growth of InAs/GaInSb Long Wavelength Infrared Superlattice materials

LI Chen, JIANG Dong-Wei, XU Ying-Qiang, NI Hai-Qiao, WANG Guo-Wei, WU Dong-Hai, HAO Hong-Yue, NIU Zhi-Chuan

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InAs/GaInSb Type-II superlattice (T2SL) materials exhibit significant advantages in long-wavelength (LWIR) and very long-wavelength infrared (VLWIR) detectors. By optimizing molecular beam epitaxy (MBE) growth parameters and interface control techniques, a 50-period short-period superlattice (SL) structure composed of 10-monolayer (ML) InAs/7ML Ga0.75In0.25Sb was successfully grown at the GaSb reconstruction transition temperature. High-resolution X-ray diffraction (HRXRD) characterization revealed a lattice constant of 6.108 ? and a period thickness of 53.53 ? for the superlattice, with deviations from theoretical design values below 0.2%. The lattice mismatch with the GaSb substrate was only 0.197%. Atomic force microscopy (AFM) measurements demonstrated a root mean square (RMS) surface roughness of 1.67 ?, while photoluminescence (PL) spectroscopy indicated a bandgap of 89.92 meV. Furthermore, a 12ML InAs/5ML Al0.8In0.2Sb superlattice barrier material was epitaxially grown, exhibiting a lattice mismatch of 0.067% with the GaSb substrate. Experimental results confirm that both the 10ML InAs/7ML Ga0.75In0.25Sb and 12ML InAs/5ML Al0.8In0.2Sb superlattices exhibit excellent lattice compatibility with the GaSb substrate. The presence of multiple satellite diffraction peaks and superior interface quality further validate the structural integrity of the materials. These findings provide a critical material foundation for the development of high-performance infrared detectors.
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Polarization angle scanning for wide-band millimeter-wave direct detection

WANG He-Yao, ZHAO Zi-Ran, QIAO Ling-Bo, GUO Da-Lu

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Millimeter-wave (MMW) technology has been widely utilized in human security screening applications due to its superior penetration capabilities through clothing and safety for human exposure. However, existing methods largely rely on fixed polarization modes, neglecting the potential insights from variations in target echoes with respect to incident polarization. This study provides a theoretical analysis of the cross-polarization echo power as a function of the incident polarization angle under linear polarization conditions. Additionally, based on the transmission characteristics of multi-layer medium, we extended the depth spectrum model employed in direct detection to accommodate scenarios involving multi-layered structures. Building on this foundation, by obtaining multiple depth spectrums through polarization angle scanning, we propose the Polarization Angle-Depth Matrix to characterize target across both the polarization angle and depth dimensions in direct detection. Simulations and experimental validations confirm its accuracy and practical value in detecting concealed weapons in human security screening scenarios.
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Study on Regulation Characteristics of Photodetectors Based on MXenes/Microstructured Silicon Heterojunctions

LIAO Lu-Lu, XU Cai-Xia, LIU Gao-Rui, LIN Chang-Qing, LI Lu-Fang, SUN Hai-bin, YANG Xing, XU Long

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Surface-microstructured silicon exhibits unique optical properties, demonstrating promising potential for applications in photoelectric sensors, solar cells, and related fields. To further explore the optoelectronic modulation effects based on its surface architecture, this study presents a novel heterojunction photodetector constructed by integrating MXene (Ti3C2Tx) with microstructured silicon substrate through spin-coating and other fabrication techniques.Comparative studies were conducted on commercial silicon, microstructured silicon, and Ti3C2Tx/microstructured silicon devices under varying wavelengths and optical power densities. The current-voltage (I-V) characteristics and photoresponse performance reveal that the Ti3C2Tx/microstructured silicon photodetector exhibits significantly superior external quantum efficiency (EQE) and responsivity across a broad spectral range of 200-1750 nm compared to commercial silicon and microstructured silicon detectors. Notably, in the near-infrared region (1100-1800 nm), the device demonstrates exceptional performance, achieving EQE exceeding 1000% and responsivity greater than 10 A/W. In contrast, commercial silicon photodetector in the same spectral range shows EQE below 10% and responsivity no higher than 0.3 A/W, while microstructured silicon photodetector exhibits EQE of below 15% and responsivity limited to 0.08 A/W. Further dynamic response and bias-dependent analyses indicate that the Ti3C2Tx coating, owing to its high conductivity and the built-in electric field formed at the heterojunction with microstructured silicon, significantly enhances detection capability from the NIR to MIR. Additionally, the response time is remarkably reduced from 38 ns to 20 ns. This heterojunction holds great promise for high-speed photodetection in optical communications, LIDAR, photoelectric sensing, and other advanced optoelectronic applications.
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Analysis and optimization of imaging characteristics of segmented planar imaging system based on checkerboard sampling lens array

Li Yan, He Yan, YU Qing-Hua1, SUN Sheng-Li

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The study simulated imaging characteristics of a segmented planar imaging system. It investigated the influence of structural parameters on imaging results based on a checkerboard lens sampling array, and provided optimal parameters for the system. The work innovatively employed hyperspectral images to analyze the impact of interference spectral width on imaging quality in natural scenes, concluding that the allowable interference bandwidth in practical applications should not exceed 100 nm. The discussion on allowable bandwidth and error analysis based on real-world scenarios offered guidance for developing checkerboard-type imagers. These findings also provided universal insights applicable to all segmented planar imaging systems.
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Polarization Integrated Infrared Detector and Imaging Based on MetaLens Structure

Huang Hao-Jin, Wang Long, Zhou Jian, Wang Fangfang, Zhang Feng, Ying Xiang-Xiao, Tang Shou-Hai, Liu Yun-Meng, Chen Jian-xin, Zhou Yi

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Due to the close pixel size and working wavelength of the focal plane polarization integrated infrared detector, diffraction effects cause severe crosstalk between adjacent pixels with different polarized light. A single traditional metal grating structure cannot achieve high extinction ratio polarization detection chips. This article proposes and designs a metasurface lens stacked polarization integrated infrared detector structure, studies the optical field convergence ability of metalens for different wavelengths of infrared light waves, prepares metastructural lenses and submicron grating structures, and integrates them with infrared focal planes. The polarization extinction ratio of the device exceeds 15:1, and dynamic and variable temperature objects are selected for polarization imaging experiments, demonstrating the imaging advantages of polarization integrated devices with focal planes.
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Terahertz detector based on side-gate AlGaN/GaN HEMT for resonant detection

JIN Chen-Yang, KANG Ya-Ru, LI Ye-Ran, YAN Wei, NING Jin, ZHAO Yong-Mei, LI Zhao-Feng, YANG Fu-Hua, WANG Xiao-Dong

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In high-electron-mobility transistor (HEMT) terahertz detectors, an excessively wide gate can generate oblique modes in the channel, resulting in weakened resonant detection signals and a broadened resonance peak. To address this issue, a side-gate HEMT (EdgeFET) structure was proposed. A resonant detection model for the side-gate device was established based on the hydrodynamic equations of the two-dimensional electron gas (2DEG) in conventional HEMT. A side-gate HEMT detector was fabricated, and terahertz resonant detection experiments were conducted at 77 K. The experimental results indicated that EdgeFET demonstrated distinct resonant responses at 77 K, with the resonant responsivity reaching 3.7 times the maximum non-resonant responsivity. The experimental data were fitted using the theoretical model to validate its accuracy. These results strongly confirm the effectiveness of EdgeFET in enhancing the resonant performance of the detector, providing a new technological approach for the development of next-generation high-performance terahertz detectors.
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High-Performance Terahertz Detectors Based on Large-Area Semimetallic Platinum Telluride (PtTe2)

HUANG De-Bao, ZHOU Wei, HUANG Jing-Guo, QIU Qin-Xi, JIANG Lin, YAO Niang-Juan, GAO Yan-Qing, HUANG Zhi-Ming

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Terahertz (THz) detectors, serving as the pivotal components for photoelectric conversion, constitute one of the fundamental building blocks in modern information society. Large-area PtTe2 thin films were synthesized via chemical vapor deposition (CVD), enabling the fabrication of THz detectors with varied channel lengths. Characterization results demonstrate that the device response exhibits linear dependence on both bias voltage and incident power, while the responsivity shows an inverse proportionality to channel length and operational frequency. The observed device characteristics align well with theoretical calculations based on the electromagnetic induced well (EIW) mechanism. Notably, EIW-based devices achieve a rapid response time of ~7.6 μs, with noise equivalent power (NEP) below 7.9×10-15 W/Hz0.5 and specific detectivity (D*) exceeding 9×1010 cm·Hz0.5/W under limited bias conditions. These performance metrics surpass those of previously reported semimetallic PtTe2-based detectors.
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Millimeter Wave Imaging of Range Migration Algorithm with Adaptive Background Filtering

CHENG Zhi-Hua, ZHOU Ran, WANG Meng, YU Tao, WANG Yu-Lan, YAO Jian-Quan

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This paper proposes a novel Range Migration Algorithm (RMA) integrated with an adaptive background filtering method specifically designed for near-field millimeter-wave imaging scenarios where targets are in close proximity to background structures. This method simulate the attention distribution mode of the human visual system which is used in Artificial Intelligence (AI) and called Attention Mechanism. Based on the concept of static clutter filtering, the frequency-domain signals of the scanning aperture are divided into grid cells. Background scattering functions are established by analyzing the motion processes within each cell, and background interference is linearly filtered out. An analysis of the manifestation of background scattering interference within the algorithm is carried out, and the impact of the grid cell dimension on the imaging quality is investigated. Experimental results that the proposed method exhibits the capability to enhance the signal-to-noise ratio of both the target and the background. It effectively suppresses the background interference leading to a more prominent image, meanwhile without incurring a prohibitive computational load. The method offers a novel solution for improving the performance of millimeter-wave imaging technology in practical applications.
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Fabrication of flexible, low-loss and high-reliability PI mid-infrared hollow optical fiber and investigation of its CO2 laser transmission performances

YU Shuo-Ying, ZHU Run-Miao, LIU Sheng, ZHA Zhi-Peng, ZHANG Qing-Tian, HOU Guang-Ning, FEI Ying-Di, LIU Shao-Hua, JING Cheng-Bin, CHU Jun-Hao

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Hollow optic fiber delivery of CO2 and other mid-infrared lasers still faces several challenges in terms of transmission loss, bending flexibility and reliability, which limits its applications in laser medicine, flexible industrial processing, and intelligent sensing. A flexible, low-loss mid-infrared hollow fiber with enhanced PI/Ag/AgI interfacial bonding strength has been developed by utilizing plasma activation of polyimide (PI) structural tubing and a dynamic liquid-phase deposition process. The results showed that after plasma treatment, the N-C bonds on the surface of PI were converted to N-O bonds and active groups such as carboxyl were formed. This results in enhancement of surface hydrophilicity and the interfacial bonding strength between PI and Ag/AgI layers (from level 0 to level 2) without noticeably increasing surface roughness. The as-fabricated PI hollow fiber (ID=2 mm) exhibited a low-loss transmission window within 8~15 μm wavelength range, achieving a linear transmission loss as low as 0.05 dB/m at 10.6 μm. When bent 180° with a radius of 20 cm, the loss increased only to 0.55 dB/m. The fiber could deliver a 30 W CO2 laser beam for 300 s at 150°C without damage. After 400 min of vibration testing and 120 min of high-low temperature aging (-196°C/150°C), the transmission loss remained stable, showing its value for practical applications.
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Peak Separation and Small Signal Modeling Analysis of Abnormal Shift in the transconductance curve in InAs Composite Channel HEMT

GONG Yong-Heng, CHEN Yu-Xuan, SHI Jing-Yuan, ZHANG Da-Yong, SU Yong-Bo, DING Wu-Chang, JIN Zhi, Ding Peng

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In this work, 100 nm gate-length InP-based high electron mobility transistors (HEMTs) with a composite InGaAs/InAs/InGaAs channel are fabricated. DC measurements indicate that the InAs channel enhances transconductance but shifts the peak point toward lower?Vgs?under high?Vds?bias. Peak separation analysis reveals the DC transconductance curve is composed of two components: the gate-controlled transconductance and the impact-ionization-induced additional transconductance. Further analysis demonstrates that the anomalous shift originates from channel impact ionization intensity variation, which is caused by changes in the gate-drain electric field rather than carrier density in the channel. Two additional current sources were introduced in the small-signal model to characterize the impact-ionization-induced transconductance, and the numerical variation trends of their parameters are consistent with the peak separation results, which validates the mechanism's correctness. RF measurements confirm that the DC transconductance enhancement does not effectively improve RF characteristics, which is attributed to the ionization-induced transconductance having a time constant significantly larger than that of conventional transconductance components. These findings provide a theoretical foundation for controlling impact-ionization and improving effective transconductance, ultimately optimizing InAs channel HEMT design.
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Room-temperature Highly sensitive Bi₂Te₃ Terahertz Detector Based on Hot-carrier Photothermoelectric Effect

CAI Miao, WANG Xing-Jun, GUO Xu-Guang

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High-performance uncooled terahertz (THz) detectors have a wide range of applications in many technological fields, such as high-rate data communications, real-time imaging, spectroscopy and sensing. However room-temperature THz detectors with high sensitivity and fast response capability are still rare. In recent years, the hot-carrier photothermoelectric (PTE) effect in two-dimensional (2D) materials has been found to be useful for room-temperature, high-speed, and highly sensitive photodetection in the THz and long-wave infrared radiation. In this study, the authors constructed a room-temperature THz detector based on the high-performance 2D layered thermoelectric material Bi2Te3, which employs a bow-tie antenna as an asymmetric light coupler and utilizes the hot-carrier PTE effect to achieve THz detection in zero-bias mode. The results show that the Bi2Te detector exhibits excellent THz detection performance, with a responsivity and noise equivalent power (NEP) of 0.45 A/W, 17 pW/Hz^1/2, and a fast response time of 12 μs under 100 GHz radiation, respectively. This work demonstrates the promising application of Bi2Te3 THz detectors based on the hot-carrier PTE effect in realizing high-performance uncooled THz detectors.
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Continuous Wave Operation of Terahertz Quantum Cascade Wire Lasers with Dual Coupled Gratings

TAN Cheng, ZOU Ting-Ting, ZANG Shan-Zhi, WANG Kai, GAN Liang-Hua, CAO Chen-Tao, CHEN Bing-Qi, CHEN Hong-Tai, ZHANG Yue-Heng, FANG Yu-Long, XU Gang-Yi

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We demonstrate terahertz quantum cascade (THz-QC) wire lasers based on dual coupled gratings that achieve continuous-wave (CW) operation near liquid nitrogen temperatures with a low-divergence Gaussian-like beam profile. Our configuration circumvents the effective refractive index constraint, significantly enhancing fabrication efficiency while retaining the key advantages of low power consumption and high heat dissipation efficiency. By engineering the photonic band structure of the coupled gratings, the laser operates on two supermodes. For Supermode #1, grating 1 serves as the master oscillator while grating 2 functions as a phased antenna array, featuring a collimated beam. For Supermode #2, grating 2 is the main oscillator and simultaneously provides a collimated beam, while grating 1 offers high reflectivity. Both supermodes exhibit high cavity quality factors and low beam divergence, achieved with a significantly reduced gain area. Experimentally, both supermodes were observed, and the optimized laser produces a collimated Gaussian beam with divergence angles of 12°×18° and an optical power of 1.04 mW. The threshold power consumption and thermal resistance are as low as 2.62 W and 8.5 mK/W/cm2, respectively, resulting in a maximum CW operating temperature of 78.0 K. This work offers a more accessible route for low-divergence, low-power-consumption, high-thermal-dissipation-efficiency THz-QCLs with enhanced CW operation at elevated temperatures.
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Field-Enhanced Ge-Based PIN Structured Blocked Impurity Band Infrared Detectors in Weakly Ionized Regions

Liu Chixian, Tianye-Chen, Zexin-Wang, Qingzhi-Hu, Wei-Dou, Xiaoyan Liu, Jingwei-Ling, Changyi-Pan, Jiaqi-Zhu, Peng-Wang, Huiyong-Deng, Hong-Shen, Ning-Dai

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A novel germanium （Ge） based blocked-impurity-band （BIB） infrared detector with a planar PIN structure was developed, using near-surface processing technique to fabricate the target and electrode contact regions. The detector demonstrates significant rectifying characteristics, exhibiting extremely low dark current under reverse bias, and its working temperature is extended to 15 K. At this temperature, the detector maintains a stable detectivity of 6 × 1012 cm·Hz1/?·W?1 within the reverse bias voltage range of 0 to -5 V. Through band structure analysis, the dark current mechanism and the impact of temperature variation on optical response were discussed in detail, and the working principle based on the low-temperature weak ionization region was proposed. Additionally, tests of the detector’s blackbody response current and detectivity were systematically measured, and the mechanism of maintaining high performance at elevated working temperatures was clarified. The result provides innovative insights for enhancing the temperature performance of Ge-based BIB detectors and offers theoretical and experimental support for the design and application of future infrared detectors.
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Effect of mixed-period gratings on the photoresponse bandwidth of long-wavelength quantum well infrared photodetectors

TIAN Ya-Ping, LI Zhi-Feng, LI Ning, LI Xiang-Yang, XU Jin-Tong

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The expansion of response bandwidth is an important direction in the development of quantum well infrared photodetectors. Using quantum well material with the peak response wavelength at 10.55 μm, the diffraction grating structure in the 30 μm center distance quantum well infrared detector is optimized, and six different combinations of the mixed-period gratings are obtained by mixing three grating structures with the period of 2.80, 3.50, and 4.25 μm within a single photosensitive pixel. Photoresponse spectroscopy tests show that the response bandwidth of the mixed-period grating can be broadened from 1.20 μm to 1.91 μm by up to 60% compared to a single-period grating, while the blackbody responsivity decreases by only 12%.
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The Study of Electrical Properties of Type-II InAs/GaSb Superlattices

xiangtaiyi, WANG NAN, HUANG MING, CHAI Xu-Liang, CHEN Jian-Xin

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In order to investigate the electrical properties of InAs/GaSb type-II superlattices, a lattice-matched AlAsSb electrical isolation layer was grown between the GaSb substrate and the InAs/GaSb type-II superlattice epitaxial material to suppress the conductive effect of the substrate. Temperature-dependent Hall measurements revealed that the undoped superlattice exhibited N-type conductivity. As the P-type doping concentration increased, a compensation doping phenomenon was observed, with the occurrence of conductivity type transitions at 95 K and 230 K, respectively. Below the transition temperatures, P-type conductivity was exhibited, while above the transition temperatures, the material exhibited N-type conductivity. The phenomenon was analyzed using the Fermi level model, and the results indicated that the transition temperature for conductivity type changes increased with increasing doping concentration.
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High-Resolution Defect Detection in Optoelectronic Device via Scanning Imaging Technique

HU Er-Tao, LIU Jia-Wei, SHAO Peng, XIN Hao, CAI Qing-Yuan, DUAN Wei-Bo, CHEN Liang-Yao

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Photocurrent scanning imaging (mapping) technology is a key technique in the research of solar cells and photodetectors. However, traditional galvanometer-driven beam scanning methods are limited by a restricted scanning range and image distortion. To address these shortcomings and meet the need for testing the photocurrent uniformity of large-area optoelectronic devices, an automated photocurrent mapping testing system has been developed based on optical component scanning. This system offers a large imaging range, high spatial resolution, high stability, and low cost. With its high-precision mode, it can achieve sub-micron geometric positioning (subdivision number 6400, scanning step size 0.625 μm), fulfilling both large-area scanning requirements and providing high-resolution testing. Moreover, its simple structure greatly reduces the overall cost of the mapping system. Using a silicon solar cell sample with surface covered by a “南” (south) character paper or a encoder strip mask, it was demonstrated that the scanning range exceeds 10×10 mm2, with a spatial resolution of 0.6 μm. The system was also used to characterize the surface photocurrent images of Cu?ZnSnS? and Cu?ZnSn(S,Se)? solar cells. The results show that the Cu?ZnSnS? cell contains more defects, while the Cu?ZnSn(S,Se)? cell exhibits a more uniform surface photocurrent response with fewer defects. These findings contribute to the optimization of solar cell fabrication processes.
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Research on stress adaptability of InAs/GaSb type Ⅱ superlattice long-wave focal plane infrared detectors

XUE Yong, XU Qing, HUANG Min, WANG Zhen, LIANG Zhao-Ming, XU Qing-Qing, BAI Zhi-Zhong, CHEN Jian-Xin

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The superlattice long-wavelength infrared focal plane detectors operate at low-temperatures. The differences in the thermal expansion coefficients among the various material layers of the detectors can lead to deformation and generate thermal stress, which in turn affects the optoelectrical performances of the detector. This study designed two structural modules to achieve the regulation of stress in the superlattice detectors. The changes in dark current and spectral response of InAs/GaSb type II superlattice long-wave infrared focal plane detectors under different stress conditions were explored. The research indicates that within the stress range of -10.7 MPa to 131.9 MPa, the variations in the optoelectrical performance of the detector is small. The detector was subjected to a temperature shock test, and it demonstrated high reliability. Our research results provide guidance for the structural design of InAs/GaSb type II superlattice long-wave infrared focal plane detectors and offer a basis for their performance and reliability assessment.
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Study on the performance and parameters of interdigitated GaAs photoconductive terahertz radiation source

ZHANG yu-song, Shi Wei, LI yi-fan, Hou Lei, LI huan-lin

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Abstract:

Optimizing the substrate material and electrode structure of photoconductive antennas is crucial to improving their performance in radiating terahertz waves. Compared with traditional photoconductive antennas (PCA), interdigitated photoconductive antennas (IPCA) can build multiple array elements in a smaller photosensitive area and have superior radiation performance. In this paper, six types of IPCA with different number of array elements and electrode gaps were designed and developed. The reverse electric field between adjacent electrodes was eliminated by blocking metal layers. The radiation characteristics and polarization characteristics of IPCA were compared with traditional PCA (parallel electrode antenna and bowtie antenna). The changes of the radiation characteristics of IPCA with the number of array elements, electrode gap, pump light energy and bias electric field were further studied. Experimental results show that the THz pulse radiation amplitude of the 40-element IPCA is 30 times higher than that of a single antenna.
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A Multi-Attention Mechanism U-Net Neural Network for Image Correction of PbS Quantum Dot Focal Plane Detectors

Hanting Wang, Di Yun-Xiang, Xingyu Qi, Yingzhe Sha, Yahui Wang, Lingfeng Ye, Weiyi Tang, Ba Kun, Wang Xu-Dong, Huang Zhang-Cheng, Chu Jun-Hao, Shen Hong, Wang Jian-Lu

Abstract: (82) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Near-infrared image sensors are widely used in fields such as material identification, machine vision, and autonomous driving. Lead sulfide colloidal quantum dot-based infrared photodiodes can be integrated with silicon-based readout circuits in a single step. Based on this, we propose a photodiode based on an n-i-p structure, which removes the buffer layer and further simplifies the manufacturing process of quantum dot image sensors, thus reducing manufacturing costs. Additionally, for the noise complexity in quantum dot image sensors when capturing images, traditional denoising and non-uniformity methods often do not achieve optimal denoising results. For the noise and stripe-type non-uniformity commonly encountered in infrared quantum dot detector images, a network architecture has been developed that incorporates multiple key modules. This network combines channel attention and spatial attention mechanisms, dynamically adjusting the importance of feature maps to enhance the ability to distinguish between noise and details. Meanwhile, the residual dense feature fusion module further improves the network"s ability to process complex image structures through hierarchical feature extraction and fusion. Furthermore, the pyramid pooling module effectively captures information at different scales, improving the network"s multi-scale feature representation ability. Through the collaborative effect of these modules, the network can better handle various mixed noise and image non-uniformity issues. Experimental results show that it outperforms the traditional U-Net network in denoising and image correction tasks.
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Design and fabrication of pixel-level infrared metalens arrays for light field control

ZHANG Feng, WANG Fang-Fang, ZHOU Jian, YING Xiang-Xiao, ZHOU Yi, CHEN Jian-Xin

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Abstract:

Metalenses，with their unique optical field modulation characteristics and remarkable advantages of high integration and miniaturization, have broad applications in the integrated imaging system of lightweight and small-sized optoelectronic chips. In this paper, a metalens structure for pixel-level integrated infrared focal plane applications was designed. The preparation of the structure adopted a method combining stepper lithography technology and Inductively Coupled Plasma (ICP) etching process. Through a systematic optimization of etching parameters, including gas flow rate, working pressure, and power, the loading effect was effectively suppressed and the standard deviation of the etching rate was decreased from 0.205% to 0.073%. Finally, a highly uniform metalens array was fabricated, with a pixel center distance of 30 μm, an array of 640×512, and a maximum aspect ratio of 3.42 of Si pillars. The focusing distance for 4.3 μm wavelength infrared light is 35 μm. The measured optical field convergence efficiencies, within radial ranges of 10 μm and 20 μm in the centra area at the focal length, are 66.4% and 84.9%, respectively. The optical field energy is increased by 5.98 times and 1.91 times, respectively, compared with that without the integrated metalens within the same area range. This study will provide the structural design and processing foundation for the integration of pixel-level metalens arrays with infrared chips.
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High performance multifunction integrated optic circuits base on thin-film lithium niobate

Qu Baiang, GUO Hong-Jie, YANG Yong-Kang, CHEN Wen-Bin, GUO Wen-Tao, TAN Man-Qing

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Abstract:

This paper introduces an innovative Multifunction Integrated Optic Circuit (MIOC) design utilizing thin-film lithium niobate, surpassing traditional bulk waveguide-based MIOCs in terms of size, half-wave voltage requirements, and integration capabilities. By implementing a sub-wavelength grating structure, we achieve a Polarization Extinction Ratio (PER) exceeding 29 dB. Furthermore, our electrode design facilitates a voltage-length product (VπL) below 2 V·cm, while a double-tapered coupling structure significantly reduces insertion loss. This advancement provides a pivotal direction for the miniaturization and integration of optical gyroscopes, marking a substantial contribution to the field.
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Moving Mirror Speed Compound Control of the Fourier Transform Spectrometer Based on T-method

HUANG Ying, DUAN Juan, GUO Qian, DING Lei, HUA Jian-Wen

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Abstract:

The Fourier transform spectrometer (FTS) is a precision infrared detection instrument. It adopts Michelson interference splitting, and the moving mirror is one of the core components. The uniformity and stability of the moving mirror’s speed directly affect the quality of the subsequent interferogram, so it is necessary to carry out high-precision motion control of the moving mirror. For some FTS with moving mirror in low-speed motion, the traditional M-method can no longer meet the requirements of speed measurement accuracy. In addition, when the moving mirror moves at a low speed, the speed stability is more easily affected by external mechanical disturbance. Based on the stability requirement of the low-speed moving mirror, this paper studies the motion control of the moving mirror based on the T-method measuring speed. It proposes a high-precision algorithm to obtain the measured and expected value of the velocity. By establishing the mathematical model and dynamic equation of the controlled object, the speed feedforward input is obtained, and then the compound speed controller based on the feedforward control is designed. The control algorithm is implemented by the FPGA hardware platform and applied to the FTS. The experimental results show that the error of the peak-to-peak velocity is 0.0182, and the error of the root mean square (RMS) velocity is 0.0027. To test the anti-interference ability of the moving mirror speed control system, 5mg sine excitation force is applied in the motion direction of the moving mirror on the FTS for frequency-fixed scanning. The frequency range is 2-200Hz. The experimental results show that under the excitation, the maximum error of the peak-to-peak velocity is 0.0679, and the maximum error of the RMS velocity is 0.0205. The speed stability of the moving mirror can still meet the performance requirements of the FTS. This design provides a technical means for realizing the speed control of the moving mirror with low speed and high stability. Also it makes the FTS have wider applications.
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Aircraft contrail detection based on satellite-borne hyperspectral images

XIE Shu-Xin, LI Peng-Fei, ZHAO Si-Wei, LIAN Xiao-Ying, SUN De-Xin

Abstract: (82) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Existing methods for detecting aircraft contrails primarily relied on the radiance or temperature differences between specific channels in multispectral images. However, they did not fully exploit the potential of spectral features. The advancement of satellite-borne hyperspectral imaging technology has provided a new data foundation for aircraft contrail detection. This study explored a detection algorithm for potential aircraft contrails using shortwave infrared hyperspectral images from the GF-5 AHSI. A spatial-spectral feature extraction method was proposed, which leveraged the complementary nature of spatial and spectral information in hyperspectral images. The method achieved an accuracy of over 97% and a false alarm rate of less than 2% on GF-5 hyperspectral image data. This work offers valuable insights for future research.
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Bound States in the Continuum for Encoded Imaging

HOU Shuai-Xing, YANG Si-Jia

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Abstract:

Artificial structures known as metasurfaces are used extensively to control the propagation, phase, amplitude, and polarization of light by finely adjusting the characteristics of electromagnetic waves on a sub-wavelength scale. In this work, we suggest a Bound States in the Continuum (BIC) structure based on a metallic metasurface. We were able to achieve a notable BIC peak at a frequency of 0.8217 terahertz (THz) by carefully modifying the metallic structures utilizing CST and COMSOL tools.We discovered through multi-level expansion analysis that the electric dipole (ED) is primarily responsible for this structure's resonant characteristic. We created and put into operation an image system that operates at 0.8217 THz by utilizing the features of BIC. According to experimental data, the imaging system offers outstanding sensitivity and resolution, indicating great promise for terahertz imaging. In addition to offering fresh concepts for the creation of metasurface-based BIC structures, our research gives useful references for the advancement of high-performance terahertz imaging technologies.
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Cavity-enhance absorption spectroscopy for the measurement of Oxygen concentration

SONG Jun-Ling, RAO Wei, WANG Lin-Yan, ZHU Xiao-Hui, WANG Dian-Kai, FENG Gao-Ping

Abstract: (38) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

A high-performance oxygen detection system enables real-time online monitoring of critical parameters such as oxygen concentration and flow velocity within the engine, ensuring optimal operational efficiency. In flow field tests for engines such as scramjet and aviation engines, the complex environment characterized by high temperatures, pressures, and velocities, along with limited measurement space, poses significant challenges for accurate flow field diagnostics. To address these challenges, a device for measuring oxygen component concentration based on cavity-enhanced absorption spectroscopy (CEAS) was developed. The device features an embedded optical probe design and incorporates multi-directional adjustment mechanisms at both the transmitting and receiving ends to facilitate precise optical path alignment, enhancing its applicability in engineering experiments. Experimental results demonstrated that, in a static environment, the measured oxygen concentration was 20.846?0.97%.. In shock tube experiments, the system successfully captured three distinct states: before the arrival of the incident shock wave, after the passage of the incident shock wave but before the reflected shock wave arrived, and after the passage of the reflected shock wave. The measured oxygen concentration data were consistent with theoretical predictions.
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Silicon valley photonic crystal Mach-Zehnder thermo -optic modulator

ZHANG Xin-Yan, LIN Han, FEI Hong-Ming

Abstract: (70) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Thermo-optic modulators are key components of optical communication systems, and their performance directly affects system efficiency. With the development of silicon optothermonic technology, silicon thermo-optic modulators have been widely used in optothermonic chips. Conventional silicon optical modulators are large in size and have high losses. In recent years, researchers have proposed to use the slow light effect of photonic crystals to reduce the footprint of modulators. Related studies have shown that these devices have advantages, such as small size and low driving voltage. However, the optical transmittance of thermo-optic modulators based on photonic crystals is still affected by defects caused by fabrication errors. Valley photonic crystal optical waveguides can achieve scattering-immune high-efficiency unidirectional transmission, providing a new venue for realizing high-performance photonic devices. In this paper, a new silicon thermo-optic modulator based on a valley photonic crystal Mach-Zehnder interferometer (MZI) is designed. The electrical heating mechanism is introduced on one of the waveguides of the MZI. The thermo-optic effect modulates the refractive index to achieve precise phase modulation of the transmitted light. The thermo-optic modulator device has a small footprint of only 9.26 μm × 7.99 μm, which can achieve a high forward transmittance of 0.91, an insertion loss of 0.41 dB, and a modulation contrast of 11.75 dB. It can also be experimentally fabricated using complementary metal oxide semiconductor (CMOS) technology, so it will have broad application prospects. This modulation principle can be widely used in designing different thermo-optic modulation devices.
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Study of Dual-Frequency-Band Millimeter-Wave Extended Interaction Klystron Based on Dual-2π Mode

XU Che, LU Jia-Ni, TANG Yong-Liang, TANG Xian-Feng

Abstract: (64) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

This paper proposes a novel dual-frequency-band millimeter-wave extended interaction klystron amplifier (EIKA). It is primarily based on the multimode operating mechanism of dual-2π mode. This design integrates a broadband traveling-standing-wave mode input cavity with a dual-2π standing-wave mode output cavity, resulting in a compact slow-wave structure design that efficiently operates within a total circuit length of approximately 24 mm. Particle-in-cell simulation results reveal that under a 15.6 kV, 1 A electron beam and a uniform 0.6 T magnetic field, the device achieves output power for 183-1024 W across a broadly 1.20 GHz bandwidth, spanning 93.76-94.96 GHz. Remarkably, it facilitates dual-band output in both lower-2π and upper-2π bands, delivering maximum gains of 37.09 dB (1024.10 W at 93.90 GHz) and 35.75 dB (752.20 W at 94.84 GHz), with -3 dB bandwidths of 0.33 GHz and 0.20 GHz, respectively. The effectiveness for the dual-2π mode design is further confirmed through a cold-test experiment using the perturbation method. This experiment demonstrated typical dual-2π mode field distribution profiles, affirming the design's efficacy.
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Broadband high-extinction-ratio nonvolatile optical switch based on phase change material

LIANG Kai, YUE Wen-Cheng, XU Fan, ZHU Qian-Nan, ZHANG Jian-Min, WANG Shu-Xiao, CAI Yan

Abstract: (88) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

In this paper, we present a broadband, high-extinction-ratio, nonvolatile 2×2 Mach-Zehnder interferometer (MZI) optical switch based on the phase change material Sb2Se3. The insertion loss (IL) is 0.84 dB and the extinction ratio (ER) reaches 28.8 dB at the wavelength of 1550 nm. The 3 dB bandwidth is greater than 150 nm. Within the 3 dB bandwidth, the ER is greater than 20.3 dB and 16.3 dB at bar and cross states, respectively. The power consumption for crystallization and amorphization of Sb2Se3 is 105.86 nJ and 49 nJ, respectively. The switch holds significant promise for optical interconnects and optical computing applications.
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Research progress of active metasurface for intelligent radar stealth

WANG Dong-Shu, LIU Tong-Hao, WANG Liu-Ying, LIU Gu, CHENG Hai-Qing, CHENG Meng-Zhong, GE Chao-Qun, WANG Long, WANG Bing, XU Ke-Jun

Abstract: (89) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The new active metasurface has the advantages of small size, light weight and easy integration, so it has an important application prospect in weapon radar intelligent stealth. Based on this, focusing on the requirements of radar intelligent stealth for current weapons and equipment, this paper expounds the methods, approaches and performance advantages of active metasurface in electromagnetic wave regulation, reviews the development history of various active metasurface, and summarizes the research status and future development direction of active metasurface for radar intelligent stealth. It provides the relevant theoretical basis and design reference for the wide application of active metasurface in intelligent stealth of weapon equipment radar.
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Effect of Extrinsic resistances on Noise performance for Deep Submicron MOSFET

GAO HANQI, Jin Jing, Zhou JianJun

Abstract: (66) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

This paper investigates the impact of extrinsic resistances on the noise performance of deep submicron MOSFETs using the noise correlation matrix method. Analytical closed-form expressions for calculating the four noise parameters are derived based on the small-signal and noise-equivalent circuit models. The results show strong agreement between simulated and experimental data for MOSFETs with a gate length of 40 nm and dimensions of 4×5 μm (number of gate fingers × unit gate width).
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Anisotropic Tetratellurium-Iridium-Nibium Terahertz Detector

Liu Yuan, Yang Si-Jia, XU Yong-Jiang, SHEN Yun, DENG Xiao-Hua

Abstract: (109) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Topological semimetal materials have garnered significant interest due to their distinctive electronic structures and unique properties. They serve as a foundation for exploring various physical phenomena, including the anomalous Hall effect, topological phase transitions, and negative magnetoresistance, while also offering potential solutions to the "THz Gap." This study focuses on the type-II Weyl semimetal tetratellurium iridium niobium (NbIrTe4) terahertz detector, which exhibits a responsivity of 4.36 A/W, a noise equivalent power of 12.34 pW/Hz1/2, and an anisotropic resistance ratio of 32 at room temperature. This research paves the way for achieving high-performance terahertz detection at room temperature and serves as a reference for investigating the Weyl semimetal.
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Strongly Coupled Electro-optical Tunable 780 nm Ultra-Narrow Linewidth Laser Source

Xue Kai, RONG Jia-Min, XING Guo-Hui, XUE Jun-Jie, LIU Wen-Yao, ZHOU Yan-Ru, XING En-Bo, TANG Jun, LIU Jun

Abstract: (106) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Highly matched and precisely locked to the absorption lines of rubidium (Rb) atoms, 780 nm lasers play a crucial role in fields such as quantum computing, precision measurements, and high-sensitivity sensing, with clear requirements for strong coherence and fast tunability. In this paper, based on the self-injection locking and ultra-high quality factor Whispering gallery mode (WGM) cavity, a 780 nm narrow linewidth (23.8kHz) tunable laser with a single longitudinal mode output is verified. More importantly, benefiting from the optimized combined coupling coefficient K and via the lithium niobate electro-optic effect, the laser frequency detuning is effectively improved, with the experimental tuning range reaching 110 pm and the tuning efficiency of 6.4 pm/V. This work provides a high-performance design solution for fast-tunable narrow-linewidth lasers for applications in the near-infrared range, which is expected to play an essential role in the future.
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The Investigation of Concentrated Triple-Junction Solar Cells Based on InGaAsP

ZHANG Jicheng, GUAN Weiwei, SUN Qiangjian

Abstract: (97) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The InGaAsP material with an energy bandgap of 1.05 eV was grown on InP substrates by all-solid-state Molecular Beam Epitaxy (MBE) technique. The material had no mismatch dislocations between the substrate and the epitaxial layer, and also exhibited high interface quality and luminescent quality. Based on InGaAsP material, single-junction InGaAsP solar cells were grown on InP substrates, and GaInP/GaAs dual-junction solar cells were grown on GaAs substrates. These two separate cells were then bonded together using wafer bonding technology to fabricate a GaInP/GaAs/InGaAsP triple-junction solar cell. Under the AM1.5G solar simulator, the conversion efficiency of the GaInP/GaAs/InGaAsP wafer-bonded solar cell is 30.6%, achieving an efficiency of 34% under concentration. The results indicate that MBE can produce high-quality InGaAsP material, and room-temperature wafer bonding technology holds great potential for the fabrication of multi-junction solar cells.
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Research on the Metrological Calibration Technology Scheme of Brightness Temperature for the Space-borne Microwave Radiometer Calibration Target

GAO Qing-Song, LI De-Tian, TAO Yuan, YANG Lei, ZHANG Hu-Zhong, MA Dong-Tao, PENG Miao-Miao, JIN Ming, GUO Qiang, JIANG Shi-Chen, LI Yi-Nan, CHENG Chun-Yue, LI Xue

Abstract: (101) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

This paper addresses the application requirements for the brightness temperature calibration of the hot calibration target for spaceborne microwave radiometers. Based on the temperature gradient characteristics of the absorbing coating of the calibration target and the mechanism of brightness temperature deviation, combined with practical temperature measurement methods and experimental means, a brightness temperature metrological calibration technology solution applicable for in-orbit use is studied. Given the current background of high emissivity design and determination technology of the calibration target being basically perfected, the paper focuses on summarizing the methods for determining the temperature gradient characteristics of the calibration target coating. The goal is to construct an in-orbit available brightness temperature calibration method that uses multiple parameters, such as the temperature measurements of the metal inner cone of the calibration target and the temperature measurements near the radiation aperture of the calibration target. Based on feasible electromagnetic simulation technology, thermal simulation technology, platinum resistance and infrared temperature measurement techniques, the paper preliminarily summarizes the implementation path of the brightness temperature calibration technology system for spaceborne calibration targets. This involves first constructing a basic brightness temperature calibration model considering uniform background brightness temperature and improving the mapping relationship from the inner cone temperature of the calibration target and the equivalent background brightness temperature to the longitudinal temperature gradient of the coating. Subsequently, an application model for brightness temperature calibration considering the installation environment is constructed, improving the mapping relationship from the temperature measurements of the inner cone and the radiation aperture area of the calibration target to the brightness temperature deviation of the calibration target. Finally, the validation and application of the brightness temperature calibration model are discussed.This work serves as an important technical basis and reference for further improving the accuracy of the calibration target's brightness temperature and even developing space microwave radiometric measurement benchmarks.
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Review on infrared polarization image fusion methods

zhengjinjiang, LI Xiao-Xia, ZHAO Da-Peng, CHEN Yi, WU Meng-Xing

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Abstract:

Infrared polarization image fusion can fully utilize the polarization information of the scene, compensate for the disadvantage of infrared intensity images in describing high-frequency information such as scene contour edges and texture details, and has unique advantages in target detection and recognition, background noise suppression, and counter camouflage. The article summarized the research progress of infrared polarization image fusion technology from two aspects: single algorithm image fusion and multi-algorithm combination image fusion. It analyzed the design ideas of typical algorithms and summarized the advantages and disadvantages of each algorithm. Based on the current trend where single algorithm serves as the mainstream and multi-algorithm combination as the development trend for infrared polarization image fusion, this paper anticipates its potential future development direction.
1
Lightweight Remote Sensing Multimodal Large Language Model Based on Knowledge Distillation

ZHANG Xin-Yue, FENG Shi-Yang, WANG Bin

Abstract: (278) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Remote sensing multimodal large language models (MLLMs), which integrate rich visual-linguistic modal information, have shown great potential in areas such as remote sensing image analysis and interpretation. However, existing knowledge distillation methods primarily focus on the compression of unimodal large language models, neglecting the alignment of features across modalities, thus hindering the performance of large language models in cross-modal tasks. To address this issue, a lightweighting method for remote sensing MLLMs based on knowledge distillation is proposed. This method achieves effective alignment of multimodal information by aligning the outputs across modalities at the feature level. By introducing the reverse Kullback-Leibler divergence as the loss function and combining optimization strategies such as teacher mixed sampling and single-step decomposition, the generalization and stability of the student model are further enhanced. Experimental results demonstrate that the proposed method achieves higher accuracy and efficiency in four downstream tasks of remote sensing image scene classification, visual question answering, visual localization, and image description, significantly reducing the number of model parameters and the demand for computational resources, thereby providing a new solution for the efficient application of MLLMs in the field of remote sensing.
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Volume 44,2025 Issue 3

Infrared Physics, Materials and Devices

Millimeter Waves and Terahertz Technology

Infrared Spectroscopy and Remote Sensing Technology

Infrared Optoelectronic System and Application Technology

Interdisciplinary Research on Infrared Science

光学生物医学融合与成像技术的应用

激光雷达创新与应用

光学生物医学融合与成像技术的应用

Application of Optical-Biomedical Fusion and Imaging Technology

光学生物医学融合与成像技术的应用

Application of Optical-Biomedical Fusion and Imaging Technology

Volume 44,2025 Issue 3

Infrared Physics, Materials and Devices

Infrared Physics, Materials and Devices

Infrared Spectroscopy and Remote Sensing Technology

40th Years

Remote Sensing Technology and Application

40th Years

Interdisciplinary Research on Infrared Science

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