Journal of Infrared and Millimeter Waves

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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DIFNet: SAR RFI suppression network based on domain invariant features

LV Wen-Hao, FANG Fu-Ping

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Synthetic aperture radar (SAR) is a high-resolution two-dimensional imaging radar, however, during the imaging process, SAR is susceptible to intentional and unintentional interference, with radio frequency interference (RFI) being the most common type, leading to a severe degradation in image quality. To address the above problem, numerous algorithms have been proposed. Although inpainting networks have achieved excellent results, their generalization is unclear, and whether they still work effectively in cross-sensor experiments needs further verification. Through time-frequency analysis to interference signals, we find that interference holds domain invariant features between different sensors. Therefore, this paper reconstructs the loss function and extracts the domain invariant features to improve the generalization. Ultimately, this paper proposes a SAR RFI suppression method based on domain invariant features, and embeds the RFI suppression into SAR imaging process. Compared to traditional notch filtering methods, the proposed approach not only removes interference but also effectively preserves strong scattering targets. Compared to PISNet, our method can extract domain invariant features and holds better generalization ability, and even in the cross-sensor experiments, our method can still achieve excellent results. In cross-sensor experiments, training data and testing data come from different radar platforms with different parameters, so cross-sensor experiments can provide evidence for the generalization.
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An adaptive denoising of the photon point cloud based on two-level voxel

WANG Zhen-Hua, YANG Wu-Zhong, LIU Xiang-Feng, WANG Feng- Xiang, XU Wei-Ming, SHU Rong

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With a single-photon detector, photon-counting LiDAR (PCL) captures a large amount of background noise along with the target scattered/reflected echo signals, because of the influence of factors such as the background environment, target characteristics, and instrument performance. To accurately extract the signal photons on the ground surface from a noisy photon point cloud (PPC), this paper presents an adaptive denoising approach for PPC using two levels of voxels. First, coarse denoising is performed utilizing large-scale voxels, which are built based on the spatial distribution features of the PPC. The density of the voxel is then used to select the voxels that contained dense signal photons. Second, fine denoising with small-scale voxels is conducted. These voxels are built using the nearest neighbor distance, and a topological relationship between voxels is used to further extract voxels containing signal photons aggregated on the ground surface. Finally, this method is performed on the PPC from ATL03 datasets collected by the Ice, Cloud, and Land Elevation Satellite-2 both during daytime and at night and compared with the improved Density-Based Spatial Clustering of Applications with Noise (DBSCAN), improved Ordering Points to Identify the Clustering Structure (OPTICS), and the method used in the ATL08 datasets. The results show that the proposed method has the best performance, with precision, recall, and F1 score of 0.98, 0.97, and 0.98, respectively.
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The Research on Aircraft Altitude Estimate Method Based on Multispectral Feature Matching in Thermal Infrared

YANG Li-Feng, CHEN Zhuo, CHEN Fan-Sheng, WANG Jian-Yu

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The acquisition of aircraft altitude information is crucial for the aviation safety and traffic control applications. Infrared remote sensing technology can accurately measure the thermal radiation information of targets, which means the potential for quantitative observation of certain characteristics of aircraft target. A method for estimating the altitude of airborne targets based on infrared multi-channel feature matching is proposed in this paper. Firstly, a thermal infrared radiation characteristic observation model of aircraft is established, which based on the thermal infrared radiation characteristics of large aircraft and atmospheric radiative transfer models. Secondly, based on the observation model, a spectral database of aircrafts at different altitudes and flight states under different atmospheric condition can be obtained by simulating. Thirdly, target spectral information can be extracted from remote sensing images and the altitude information can be estimated with using spectral angle matching (SAM). Finally, verification and analysis were completed using simulation data and SDGSAT-1 in-orbit data. The results indicate that the proposed method can achieve kilometer-level estimation accuracy for aircraft at cruising altitude. This method provides a new solution for estimating the altitude of aircraft and has important application potential.
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Research on highly sensitive infrared imaging detection technology based on linear avalanche device

Lin Chang-qing, ZHOU Shuang-xi, LI Lu-fang, LIU Gao-rui, SUN Hai-bin, ZHANG Yu, LIN Jia-mu, SUN Sheng-li

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With the development of remote sensing technology, the detection sensitivity of infrared system is increasingly required. The infrared imaging detection technology based on linear avalanche device can effectively improve the detection sensitivity in high frame frequency applications. Based on the short-wave infrared linear avalanche detector assembly of 512X512, a small-aperture and lightweight infrared imaging system is designed and its performance is tested under low reverse bias. The test results show that the increase of SNR of the imaging system based on the linear avalanche infrared detector is basically linear with the multiplication factor M under short integration time, and the SNR of the system is 3 times that of the traditional camera of the same caliber.
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Infrared aircraft few-shot classification method based on cross-correlation network

HUANG Zhen, ZHANG Yong, Gong Jin-Fu

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In response to the scarcity of infrared aircraft samples and the tendency of traditional deep learning to overfit, a few-shot infrared aircraft classification method based on cross-correlation networks is proposed. This method combines two core modules: a simple parameter-free self-attention and cross-attention. By analyzing the self-correlation and cross-correlation between support images and query images, it achieves effective classification of infrared aircraft under few-shot conditions. The proposed cross-correlation network integrates these two modules and is trained in an end-to-end manner. The simple parameter-free self-attention is responsible for extracting the internal structure of the image while the cross-attention can calculate the cross-correlation between images further extracting and fusing the features between images. Compared with existing few-shot infrared target classification models, this model focuses on the geometric structure and thermal texture information of infrared images by modeling the semantic relevance between the features of the support set and query set, thus better attending to the target objects. Experimental results show that this method outperforms existing infrared aircraft classification methods in various classification tasks, with the highest classification accuracy improvement exceeding 3%. In addition, ablation experiments and comparative experiments also prove the effectiveness of the method.
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Design and validation of RLC equivalent circuit model based on long-wave infrared metamaterial absorber

ZHAO Ji-Cong, DANG Yan-Meng, HOU Hai-Yang, LIN Ye-Fan, SUN Hai-Yan, ZHANG Kun

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In this paper, we propose an RLC equivalent circuit model theory which can accurately predict the spectral response and resonance characteristics of metamaterial absorption structures, extend its design, and characterize the parameters of the model in detail. By employing this model, we conducted computations to characterize the response wavelength and bandwidth of variously sized metamaterial absorbers. A comparative analysis with Finite Difference Time Domain (FDTD) simulations demonstrated a remarkable level of consistency in the results. The designed absorbers were fabricated using micro-nano fabrication processes, and was experimentally tested demonstrate absorption rates exceeding 90% at a wavelength of 9.28 μm. The predicted results are then compared with test results. The comparison reveals good consistency in two aspects of the resonance responses, thereby confirming the rationality and accuracy of this model.
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Dual-band narrowband thermal emitter designed based on multi-objective particle swarm optimization

QIU Qianli, ZHANG Jinguo, ZHOU Dongjie, TAN Chong, SUN Yan, HAO Jiaming, DAI Ning

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Dual-band thermal emitters with narrow bandwidths are important in various applications in the infrared field, such as in infrared sensing and infrared imaging. However, conditions for narrowband emission in different wavelengths can conflict with each other, making it difficult to achieve dual-band emitter. In this paper, a new type of lithography-free infrared dual-band thermal emitter is proposed, which consists of alternately deposited Ge and YbF3 films on Al films. The narrowband emission characteristics stem from the Tamm plasmon polaritons (TPP) that can be excited by the distributed Bragg reflector and the Al substrate under certain conditions. The geometric parameters are optimized using multi-objective particle swarm optimization. The experiment results confirm thatSdual-band emitterScan simultaneously exhibit narrowband emitter characteristics in bothSmid-wave infrared (MWIR)SandSlong-wave infrared (LWIR)Sregions. The proposed method can be used in the design of multi-band emitssion modulation applications, which can be applied in the fields of multi-gas sensing and multi-band infrared camouflage.
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Synchronous Object Detection and Matching Network Based on Infrared Binocular Vision

ZENG Chang-Wen, YANG Zhi-Yu, DAI Zuo-Xiao, GU Ming-Jian

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The three-dimensional perception of road objects in challenging environments is crucial for the development of autonomous vehicles capable of operating in all conditions, at all hours. Infrared binocular vision mimics the human binocular system, facilitating stereoscopic perception of objects in challenging conditions such as dim or zero-light environments. The core technology for stereoscopic perception in binocular vision systems lies in accurate object detection and matching. In response to the inefficiency of the sequential implementation of object detection and matching, a synchronous object detection and matching network (SODMNet) is proposed, which is capable of synchronous detection and matching of infrared objects. SODMNet innovatively combines a object detection network with a object matching module, leveraging the deep features from the classification and regression branches as inputs for the object matching module. By concatenating these features with relative position encodings from the feature maps and processing them through a convolutional network, the network generates feature descriptors for the left and right images. The object matching is then achieved by calculating the Euclidean distances between these descriptors, thus facilitating synchronous object detection and matching in binocular vision. In addition, a novel nighttime infrared binocular dataset, annotated with targets such as pedestrians and vehicles, is presented to support the development and evaluation of the proposed network. Experimental results indicate that SODMNet achieves a significant improvement of over 84.9% in object detection mean average precision (mAP) on this dataset, with a object matching average precision (AP) of 0.5777. These results demonstrate that SODMNet is capable of high-precision, synchronized object detection and matching in infrared binocular vision, marking a significant advancement in the field.
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Wideband and High Power 3D Heterogeneous Integration Photoreceiver

XU Xiangqian, GONG Guangyu, SUN Lei, LI Yu, Kang Xiaochen, LI Simin, PAN Shilong

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In this study, we present an innovative three-dimensional (3D) heterogeneously integrated photoreceiver, which is optimized for analog microwave optical links that demand both wide bandwidth and high input optical power. The key of this design is the uni-traveling-carrier photodiode (UTC-PD), which has been flip-chip integrated onto a microwave integrated circuit submount. This integration approach enhances the photoreceiver"s overall performance, making it ideally suitful for applications requiring wide bandwidth and high power handling capabilities. The material doping and epitaxial processes of the UTC photodiode were optimized to augment its power endurance. Meanwhile, the responsivity of the photodiode was improved through the adoption of an integrated back-illuminated lens complemented by the addition of a metallic reflective layer. By establishing a precise model of the photodiode, we have refined the bandwidth characteristics of the photoreceiver using impedance compensation and broadband matching circuit design techniques. Flip-chip bonding the photodiode chip onto the microwave integrated circuit chip has substantially mitigated the impact of interconnect circuits on high-frequency performance. Furthermore, the thermal conductivity and high-power resilience of the detector chip were enhanced via gold-tin alloy micro-bump interconnections and the design of a high thermal conductivity substrate layer. The three-dimensional heterogeneous integrated photoreceiver features a 1-dB bandwidth of 42 GHz, an RF return loss exceeding 11 dB, a responsivity surpassing 0.85 A/W, a dark current below 50 nA, and a saturated input optical power of over 120 mW.By leveraging the distinctive properties of the UTC-PD, our three-dimensional (3D) heterogeneous integrated photoreceiver design achieves superior efficiency and responsiveness, positioning it as a leading solution for cutting-edge microwave photonics applications.
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High Polarization Extinction Ratio Achieved base on thin-film lithium niobate

YANG Yong-Kang, GUO Hong-Jie, CHEN Wen-Bin, QU Bai-Ang, Tan Man-Qing, GUO Wen-Tao, Yu Zhi-Guo, Liu Hai-Feng

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This article introduces a method of achieving high polarization extinction ratio using a subwavelength grating structure on a lithium niobate thin film platform, and the chip is formed on the surface of the lithium niobate thin film. The chip, with a length of just 20 micrometers, achieved a measured polarization extinction ratio of 29dB at a 1550nm wavelength. This progress not only proves the possibility of achieving a high extinction ratio on a lithium niobate thin film platform, but also offers important technical references for future work on polarization beam splitters, integrated fiber optic gyroscopes, and beyond.
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Semi-Floating Gate Ferroelectric Phototransistor Optoelectronic Integrated Devices

SHANG Jia-Le, CHEN Yan, YAN Hao-Ran, DI Yun-xiang, HUANG Xin-Ning, Lin Tie, MENG Xiang-Jian, WANG Xu-Dong, CHU-Jun-Hao, WANG Jian-Lu

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In the realm of optoelectronics, photodetectors play a pivotal role, with applications spanning from high-speed data communication to precise environmental sensing. Despite the advancements, conventional photodetectors grapple with challenges with response speed and dark current. In this study, we present a photodetector based on a lateral MoTe₂ p-n junction, defined by a semi-floating ferroelectric gate. The strong ferroelectric field and the depletion region of the p-n junction in the device are notably compact, which serves to diminish the carrier transit time, thereby enhancing the speed of the photoelectric response. The non-volatile MoTe₂ homojunction, under the influence of external gate voltage pulses, can alter the orientation of the intrinsic electric field within the junction. As a photovoltaic detector, it achieves an ultra-low dark current of 20 pA, and a fast photo response of 2 μs. The spectral response is extended to the shortwave infrared range at 1550 nm. Furthermore, a logic computing system with light/no light as binary input is designed to convert the current signal to the voltage output. This research not only underscores the versatility of 2D materials in the realm of sophisticated photodetector design but also heralds new avenues for their application in energy-efficient, high-performance optoelectronic devices.
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Progressive spatio-temporal feature fusion network for infrared small-dim target detection

ZENG Dan, WEI Jian-Ming, ZHANG Jun-Jie, CHANG Liang, HUANG Wei

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To avoid the accumulation of estimation errors from explicitly aligning multi-frame features in current infrared small-dim target detection algorithms, and to alleviate the loss of target features due to network downsampling, a progressive spatio-temporal feature fusion network is proposed. The network utilizes a progressive temporal feature accumulation module to implicitly aggregate multi-frame information and utilizes a multi-scale spatial feature fusion module to enhance the interaction between shallow detail features and deep semantic features. Due to the scarcity of multi-frame infrared dim target datasets, a highly realistic semi-synthetic dataset is constructed. Compared to the mainstream algorithms, the proposed algorithm improves the probability of detection by 4.69% and 4.22% on the proposed dataset and the public dataset, respectively.
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Visible to near-infrared photodetector based on organic semiconductor single crystal

LI Xiang, HU Jin-Han, ZHONG Zhi-Peng, CHEN Yu-Zhong, WANG Zhi-Qiang, SONG Miao-Miao, WANG Yang, ZHANG Lei, LI Jian-Feng, HUANG Hai

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Organic semiconductor materials have shown unique advantages in the development of optoelectronic devices due to their ease of preparation, low cost, lightweight, and flexibility. In this work, we explored the application of the organic semiconductor Y6-1O single crystal in photodetection devices. Firstly, Y6-1O single crystal material was prepared on a silicon substrate using solution droplet casting method. The optical properties of Y6-1O material were characterized by polarized optical microscopy, fluorescence spectroscopy, etc., confirming its highly single crystalline performance and emission properties in the near-infrared region. Phototransistors based on Y6-1O materials with different thicknesses were then fabricated and tested. It was found that the devices exhibited good visible to near-infrared photoresponse, with the maximum photoresponse in the near-infrared region at 785 nm. The photocurrent on/off ratio reaches 10², and photoresponsivity reaches 16 mA/W. It was also found that the spectral response of the device could be regulated by gate voltage as well as the material thickness, providing important conditions for optimizing the performance of near-infrared photodetectors. This study not only demonstrates the excellent performance of organic phototransistors based on Y6-1O single crystal material in near-infrared detection but also provides new ideas and directions for the future development of infrared detectors.
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Serialized orthogonal matching pursuit fusing image domain information for attributed scattering center extraction in SAR images

LONG Bo, WANG Feng

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Aiming to address the issue of high complexity in estimating the parameters of the Attribute Scattering Center Model (ASCM) in Synthetic Aperture Radar (SAR) images, a sparse representation parameter estimation method that integrates information from the image domain is proposed. Firstly, the improved watershed algorithm is used to segment the scattering centers of different regions. Subsequently, based on the segmentation results, the frequency domain sparse representation dictionary is decoupled and applied in a serialized manner for scattering center parameter estimation using orthogonal matching pursuit to reduce algorithm complexity. Based on simulated data and measured MSTAR data, the effectiveness and efficiency of the proposed parameter extraction method were validated, and the optimization of theoretical complexity was analyzed. The results indicate that this method can significantly reduce the time and space complexity of the algorithm while achieving results close to those of the conventional orthogonal matching pursuit algorithm. The proposed method can be used for the efficient extraction of scattering center parameters in SAR images.
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Correlation Between the whole small recess offset and Electrical Performance of InP-based HEMTs

GONG Hang, ZHOU Fu-Gui, FENG Rui-Ze, FENG Zhi-Yu, LIU Tong, SHI Jing-Yuan, SU Yong-Bo, JIN Zhi

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In this work, we investigate the impact of the whole small recess offset on DC and RF characteristics of InP high electron mobility transistors (HEMTs). Lg = 80 nm HEMTs are fabricated with a double-recessed gate process. We focus on their DC and RF responses, including the maximum transconductance (gm_max), ON-resistance (RON), current-gain cutoff frequency (fT), and maximum oscillation frequency (fmax). The devices have almost same RON. The gm_max improves as the whole small recess moves toward the source. However, a small gate to source capacitance (Cgs) and a small drain output conductance (gds) lead to the largest fT, although the whole small gate recess moves toward the drain leads to the smaller gm_max. According to the small-signal modeling, the device with the whole small recess toward drain exhibits an excellent RF characteristics, such as fT = 372 GHz and fmax = 394 GHz. This result is achieved by paying attention to adjust resistive and capacitive parasitics, which play a key role in high-frequency response.
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Research on error analysis and instrument parameter configuration of emissivity measurement of multispectral radiometric method based on slow-change assumption

Luan Yi-Fei, Wang Xiang, Gu Luo, Lin Yue, Yang Qiu-Jie, He Zhi-Ping

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Emissivity, as a key parameter to characterize the radiation properties of an object, and its accurate measurement is of great value for high-temperature target identification, characterization of material modification, and regulation of metal smelting process. The emissivity measurement by multispectral radiation method has become a research hotspot because of its advantages of non-contact and fast measurement speed, and its measurement accuracy is determined by the solution accuracy of the underdetermined system of equations. At present, the research on the solution accuracy of the underdetermined system of equations mainly focuses on the error of the equation solving algorithm, ignoring the measurement error of the spectrometer itself, which leads to the failure of controlling the system error in a reasonable way. In this paper, based on the assumption of retardation with wide application range and high measurement accuracy, the influence of the number of spectral channels and signal-to-noise ratio on the emissivity measurement error under different conditions is simulated, the parameter configurations of the spectrometer under the corresponding conditions are determined, and the effect of emissivity measurement is experimentally verified. The experimental results show that, using the multispectral radiation method based on the slow-change assumption, the number of spectral channels of the spectrometer should be not less than 400 and the signal-to-noise ratio should not be less than 1000 in order to make the blackbody emissivity measurement error less than 1%; for the targets with complex emissivity changes, the spectrometer should have at least 1,000 spectral channels and signal-to-noise ratios of more than 1,200 in order to make the measurement error less than 1%. Comprehensive consideration of the algorithm error and spectrometer parameter matching relationship is the key to rationally control the system error, and more accurate emissivity measurement results can be obtained, which provides a new basis and solution for the application of multispectral radiation method to accurately measure the emissivity, which is of great significance for the accurate identification of high-temperature targets and the application of the related fields.
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Enhancement of mid-wavelength infrared absorbance by alkane-grafted Ti₃C₂T_x MXene flakes

赵振宇, Hideaki Kitahara, Zhang Chen-Hao, Masahiko Tani

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An enhancement of mid-wavelength infrared absorbance is achieved via a cost-effectively chemical method to bend the flakes by grafting two types of alkane octane (C₈H₁₈) and dodecane (C₁₂H₂₆) onto the surface terminals respectively. The chain-length of alkane exceeds the bond-length of surface functionalities Tx (=O,-OH,-F) so as to introduce intra-flake and inter-flake strains into Ti₃C₂T_x MXene. The electronic microscopy (TEM/AFM) shows obvious edge-fold and tensile/compressive deformation of flake. The alkane termination increases the intrinsic absorbance of Ti₃C₂T_x MXene from no more than 50% down to more than 99% in the mid-wavelength infrared region from 2.5 μm to 4.5 μm. Such an absorption enhancement attribute to the reduce of infrared reflectance of Ti₃C₂T_x MXene. The C-H bond skeleton vibration covers the aforementioned region and partially reduce the surface reflectance. Meanwhile, the flake deformation owing to edge-fold and tensile/compression increase the specific surface area so as to increase the absorption as well.
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Study on Multi-wavelength Thin Film Thickness Determination Method

SHI Ce, XIE Mao-Bin, ZHENG Wei-Bo, JI Ruo-Nan, WANG Shao-Wei, LU Wei

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This work introduces a novel method for measuring thin film thickness, employing a multi-wavelength method that significantly reduces the need for broad-spectrum data. Unlike traditional techniques that require several hundred spectral data points, the multi-wavelength method achieves precise thickness measurements with data from only 10 wavelengths. This innovation not only simplifies the process of spectral measurement analysis but also enables accurate real-time thickness measurement on industrial coating production lines. The method effectively reconstructs and fits the visible spectrum (400-800 nm) using a minimal amount of data, while maintaining measurement error within 7.1%. This advancement lays the foundation for more practical and efficient thin film thickness determination techniques in various industrial applications.
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75-110 GHz wideband Frequency Tripler Chip Based on Planar Schottky Diode

CHEN Yan, MENG Fan-Zhong, XUE Hao-Dong, ZHANG Ao, GAO Jianjun

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Based on GaAs planar Schottky diode process, a W band wideband frequency tripler MMIC is designed with a reverse parallel diode pair in this paper. By combining of finite element method and equivalent circuit method, an accurate equivalent circuit model of the planar Schottky diode is built in the frequency range of 10~280GHz. The nonlinear harmonic balance tool is utilized to achieve the optimal frequency tripler design in W band. The measurement results show that the frequency multiplication loss is less than 15dB under 17dBm driving power, efficiency up to 6.7%. The chip size is 0.80mm×0.65mm×0.05mm．
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Research of power improvement of a LD directly-pumped mid-infrared pulse solid-state laser

ZHANG Meng, YANG Xi, GUO Jia-Wei, CAI He, WU Xin-Yang, HAN Ju-Hong, WANG Shun-Yan, WANG You

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A LD directly-pumped solid-state laser is considered to be one of the most promising mid-infrared light sources because of its simple principle, small size, and compact structure for the generation of mid-infrared (MIR) lasers in the 3~5 μm band. However, the quantum defect of LD directly-pumped MIR solid-state lasers will be much larger than that of ordinary near-infrared LD pumped solid-state lasers, which may lead to thermal damage and limit their development. In order to solve this problem, the methods of reducing the specific surface area of the crystal and improving the thermal energy released by the crystal structure are discussed, and the optimal length of the laser crystal is determined. The cooling structures of barium yttrium fluoride laser crystals (Ho3+^:BY2F8) of different lengths were studied by thermal simulation using COMSOL software. The experimental results show that the output power can be increased and the thermal stress in the laser crystal can be alleviated by using the laser crystal whose length is slightly shorter than that of the cooler. The final experiment shows that when the pump repetition rate is 15 Hz and the pulse width is 90 μs, the output wavelength of the laser is about 3.9 μm and the single pulse energy is 7.28 mJ, which is about 3 times that of the crystal-I. Such results should be another breakthrough of our team since the first directly-pumped solid-state MIR laser was realized more than a year ago. It might pave the way for the construction of a feasible MIR laser in the near future.
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Deep Plug-and-Play Self-Supervised Neural Networks for Spectral Snapshot Compressive Imaging

Zhang Xing-Yu, Zhu Shou-Zheng, Zhou Tian-Shu, Qi Hong-Xing, Wang Jian-Yu, Li Chun-Lai, Liu Shi-Jie

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The coded aperture snapshot spectral imaging system, based on compressed sensing theory, functions as an capable of efficiently acquiring compressed two-dimensional spectral data. This data is subsequently decoded into three-dimensional spectral data through a deep neural network. However, training the deep neural network necessitates a substantial amount of clean data, which is often challenging to obtain. To address the issue of insufficient training data for deep neural network, a self-supervised hyperspectral denoising neural network is proposed, leveraging the concept of neighborhood sampling. This network is integrated into the deep plug-and-play framework, enabling self-supervised spectral reconstruction. The study also examines the impact of different noise degradation models on the final reconstruction quality. Experimental results demonstrate that compared with supervised learning method, the self-supervised learning method enhances the average peak signal-to-noise ratio by 1.18dB and improves the structural similarity is improved by 0.009. Additionally, it achieves superior visual reconstruction outcomes without relying on clean data as labels.
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Study on photoelectric performance of ultra-small pixel pitch micro-mesa InGaAs detector

TIAN Yu, YU Chun-Lei, LI Xue, SHAO Xiu-Mei, LI Tao, YANG Bo, YU Xiao-Yuan, CAO Jia-Shen, GONG Hai-Mei

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The pursuit of ultra-small pixel pitch InGaAs detectors necessitates a meticulous approach to addressing challenges associated with crosstalk reduction and dark current minimization. By developing the fabrication process technology of micro-mesa InGaAs detector, a test structure featuring a micro-mesa InGaAs photosensitive chip with 10μm and 5μm pixel pitch was successfully prepared. Subsequently, a comprehensive investigation was conducted to analyze the impact of the micro-mesa structure on crosstalk and dark current characteristics of the InGaAs detector. The obtained results revealed the efficacy of the micro-mesa structure in effectively suppressing crosstalk between adjacent pixels when the isolation trench etches into the absorption layer. However, a noteworthy challenge emerged as the fabrication processes induced material damage, leading to a considerable increase in recombination current and ohmic leakage current. This adverse effect, in turn, manifested as a dark current escalation by more than one order of magnitude. The significance of these findings lies in offering a novel perspective for the manufacturing of ultra-small pixel pitch InGaAs focal plane detectors.
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GaSb-based tensile-strained Ge quantum dots for mid-infrared lasers

Cao You-Xiang, Dai Jin-Meng, Zhang Li-Yao

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Ge can be converted into direct bandgap material under tensile strain. Pyramid-shaped Ge quantum dots (QDs) on GaSb system is proposed. The strain distribution and band structures are investigated with different QD sizes. Flat Ge QDs are desirable for indirect to direct band gap conversion. Light emission from 1.8 μm to 5.8 μm can be achieved from Ge/GaSb QDs with the width ranges from 4 to 14 nm and the height ranges from 1 to 5 nm. A 3.1 μm laser with Ge/GaSb QDs with height of 3 nm and width of 12 nm is designed and the device performance is simulated at room temperature. The QD size fluctuations are also considered. Under the root mean square of QD size fluctuation of 0.22, the calculated optimal optical confinement factor, thickness of the waveguide, surface density of QDs are 0.013, 0.366 μm and 3.8×1010^cm-2^, respectively, while the minimum threshold current density is 28.98 A/cm2^.This work provides a feasible way for the fabrication of mid-infrared lasers.
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A HgTe/ZnO Quantum Dots Vertically Stacked Heterojunction Low dark current Photodetector

HUANG Xin-Ning, JIANG Teng-Teng, DI Yun-Xiang, XIE Mao-Bin, GUO Tian-Le, LIU Jing-Jing, WU Bin-Min, SHI Jing-Mei, Qin Qiang, DENG Gong-Rong, CHEN Yan, LIN Tie, SHEN Hong, MENG Xiang-jian, WANG Xu-Dong, CHU Jun-Hao, GE Jun, WANG Jian-lu

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Colloidal quantum dots (CQDs) are affected by the quantum confinement effect, which makes their bandgap tunable. This characteristic allows these materials to cover a broader infrared spectrum, providing a cost-effective alternative to traditional infrared detector technology. Recently, thanks to the solution processing properties of quantum dots and their ability to integrate with silicon-based readout circuits on a single chip, infrared detectors based on HgTe CQDs have shown great application prospects. However, facing the challenges of vertically stacked photovoltaic devices, such as barrier layer matching and film non-uniformity, most devices integrated with readout circuits still use a planar structure, which limits the efficiency of light absorption and the effective separation and collection of photo-generated carriers. Here, by synthesizing high-quality HgTe CQDs and precisely controlling the interface quality, we have successfully fabricated a photovoltaic detector based on HgTe and ZnO QDs. At a working temperature of 80 K, this detector achieved a low dark current of 5.23×10-9^A cm-², a high rectification ratio, and satisfactory detection sensitivity. This work paves a new way for the vertical integration of HgTe CQDs on silicon-based readout circuits, demonstrating their great potential in the field of high-performance infrared detection.
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Angular-tunable on-chip coding metasurface enabled by phase-change material with immersion liquid

LI Xue-Nan, ZHAO Zeng-Yue, YU Fei-Long, CHEN Jin, LI Guan-Hai, LI Zhi-Feng, CHEN Xiao-Shuang

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Abstract:

Metasurfaces provide a potent platform for the dynamic manipulation of electromagnetic waves. Coupled with phase-change materials, they facilitate the creation of versatile metadevices, showcasing various tunable functions based on the transition between amorphous and crystalline states. However, the inherent limitation in tunable states imposes constraints on the multiplexing channels of metadevices. Here, this paper introduce a novel approach—a multi-functional metadevice achieved through the two-level control of the encoding phase-change metaatoms. Utilizing the phase-change material Ge2Sb2Se4Te1 (GSST) and high refractive-index liquid diiodomethane (CH2I2), this paper showcase precise control over electromagnetic wave manipulation. The GSST state governs the tunable function, switching it ON and OFF, while the presence of liquid in the hole dictates the deflection angle when the tunable function is active. Importantly, our tunable coding metasurface exhibits robust performance across a broad wavelength spectrum. The incorporation of high refractive-index liquid extends the regulatory dimension of the metadevice, enabling dynamic switching of encoding bit levels. This two-level tunable metadevice, rooted in phase-change materials, presents a promising avenue for the dynamic control of functions.
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Ion Implantation Process and Lattice Damage Mechanism of Boron Doped Crystalline Germanium

HABIBA Um E, CHEN Tian-Ye, LIU Chi-Xian, DOU Wei, LIU Xiao-Yan, LING Jing-Wei, PAN Chang-Yi, WANG Peng, DENG Hui-Yong, SHEN Hong, DAI Ning

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Abstract:

The response wavelength of the boron doped germanium (Ge:B) blocked-impurity-band (BIB) structured infrared detector can reach 200μm, which is the most important very long wavelength infrared astronomical detector. The ion implantation method greatly simplifies the fabrication process of the device, but it is easy to cause lattice damage, introduce crystalline defects, and lead to the increase of the dark current of detectors. Herein, the boron-doped germanium ion implantation process was studied, and the involved lattice damage mechanism was discussed. Experimental conditions involved using 80 keV energy for boron ion implantation, with doses ranging from 1×10^13 to 1×10^15cm^-2. After implantation, thermal annealing at 450°C was implemented to optimize dopant activation and mitigate the effects of ion implantation. Various sophisticated characterization techniques, including X-ray diffraction (XRD), Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), and secondary ion mass spectrometry (SIMS) were used to clarify lattice damage. At lower doses, no notable structural alterations were observed. However, as the dosage increased, specific micro distortions became apparent, which could be attributed to point defects and residual strain. The created lattice damage was recovered by thermal treatment, but an irreversible strain induced by implantation still existed at the high doses.
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Volume 43,2024 Issue 3

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

Remote Sensing Technology and Application

Infrared Photoelectric Technology and Application

Image Processing and Software Simulation

太赫兹与毫米波技术

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

红外光谱与光谱分析

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

红外及光电技术与应用

遥感技术与应用

红外光谱与光谱分析

图像处理及软件仿真

红外材料与器件

太赫兹与毫米波技术

图像处理及软件仿真

红外材料与器件

红外及光电技术与应用

红外材料与器件

图像处理及软件仿真

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

太赫兹与毫米波技术

红外及光电技术与应用

红外材料与器件

太赫兹与毫米波技术

Volume 43,2024 Issue 3

Infrared Spectroscopy and Spectral Analysis

Image Processing and Software Simulation

Remote Sensing Technology and Application

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

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