Journal of Infrared and Millimeter Waves

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

Current Issue
Online First
Adopt
Most Downloaded

Archive

Select All

Display Method:: |

Select All

Display Method:: |

Select All

Display Method: |

Research on millimeter-wave ridged half-mode waveguide filter based on periodic defected ground structure

Zhou Qi-Hui, LIU Chen-Xi

Abstract: (2) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

A monolithic ridged half-mode waveguide bandpass filter with a periodic defected ground array has been successfully fabricated. Utilizing the high-pass characteristic of the waveguide and the rejection band generated by the periodic defected ground structure, an effective passband was created. The measured results show a 3 dB passband from 39.4 to 45.4 GHz, centered at 42.4 GHz with a 3-dB fractional bandwidth of 14.1%. The lowest insertion loss of 2.4 dB locates at 44.2 GHz. The suppression in upper rejection band reaches 40 dB at 58 GHz. Compared to conventional rectangular waveguide filters, the width of the proposed filter is reduced by 64%, which benefits to the integration and miniaturization. With the development of the next generation wireless communication (5G) towards millimeter-wave band, the miniaturized millimeter-wave filter has promising potential for 5G communication.
1
Highly Sensitive Graphene Terahertz Detection Driven by two-dimensional Ferroelectrics

WANG Xue-Yan, Zhang Yi-Wen, Wang Lin, Chen Xiao-Shuang

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

Abstract:

Graphene has the excellent characteristics of low defect density, easy large-area transfer and high carrier mobility. However, the zero-bandgap band structure of graphene leads to a short lifetime of photogenerated carriers, which restricts its application in highly sensitive photodetectors. In this work, ferroelectric material CuInP2S6(CIPS) was used as the top gate to control the photoelectric characteristics of graphene, and the possibility of improving the sensitivity of graphene terahertz detector was explored. The detection mechanism of graphene photothermoelectric effect and plasma wave effect under ferroelectric control was studied, and a high-performance graphene detector was obtained. At 0.12 THz, the responsivity of detector at room temperature reaches 0.5 A/W, with the response time of 6.3 μs and the noise equivalent power(NEP) of 0.81 nW/Hz1/2 under a bias voltage of 40 mV and a gate voltage of 2.12 V. At 0.29 THz, the responsivity is determined to be 0.12 A/W, and a NEP is 1.78 nW/Hz1/2. This work demonstrates the great potential of two-dimensional ferroelectric heterostuctures at THz band.
1
Relationship between radar reflectivity factor and ice water content of non-spherical cirrus ice crystals at 220 GHz

WANG Biao, HUO Yi-Wei, GUO Xing, WU Jia-Ji

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

Abstract:

For the practical needs in the data processing of terahertz radar，the discrete dipole approximation method is used to calculate the backscattering cross-section of non-spherical ice crystals with different shapes. Based on the latest refined ice cloud model, the relationship between the radar reflectivity factor Zm and ice water content I in 220 GHz is established. The calculation results show that both the shape of the non-spherical ice crystals and the ice cloud model have a particular influence on the Zm-I relationship. This study has application value for cloud parameter inversion of mid-latitude cirrus clouds, and it can be helpful for the development of terahertz radar in the detection of clouds.
1
Infrared image dehazing based on hierarchical subdivision superpixels and information integrity prior

LI Wei-Hua, LI Fan-Ming, MIAO Zhuang, TAN Chang, MU Jing

Abstract: (24) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Hazy weather degrades the contrast and visual quality of infrared imaging systems due to the presence of suspended particles. Most existing dehazing methods focus on enhancing global image contrast or exploit a local grid window strategy, which may lead to loss of information, halo artifacts and distortion in sky region. To address these problems, this paper proposes a novel single image dehazing model based on superpixel structure decomposition and protection of information integrity. In this model, based on the local structure information, the image is first adaptively divided into multiple objective regions using a superpixel segmentation algorithm to eliminate halo artifacts. Meanwhile, to avoid the error estimate caused by the local highlighted targets, a modified quadtree subdivision based on superpixel blocks is applied to obtain the global atmospheric light. Furthermore, a combined constraint is used to optimize the transmission map by minimizing the loss of information. Compared with state-of-the-art methods in terms of qualitative and quantitative analysis, experiments on real-world IR image data demonstrate the efficacy of the proposed method in both contrast and visibility.
1
Distortions of terahertz pulses induced by the air coherent detection technique

Du Hai-Wei, Long Jiang

Abstract: (46) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Terahertz air coherent detection technique is a broadband detection method, which has been widely used in the broadband terahertz technology after its demonstration in the experiment. The frequency response of this method is determined by the duration of the probe laser pulse. Thus, the different probe lasers might induce distortions of terahertz pulses during the detection process. In this paper, the distortions and the energy loss of the terahertz pulses induced by the air coherent detection technique are quantitatively investigated based on the simulations. The results show that the pulse distortions and the energy loss depend on the duration of the probe laser pulse and the central frequency of terahertz pulse to be detected. This work will help to estimate the influence of the air coherent detection technique in the broadband terahertz technology.
1
A Wideband Injection-Locked Frequency Tripler

WAN Cao, XUE Quan

Abstract: (29) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

A wideband injection-locked frequency tripler (ILFT) is proposed. Based on the conventional injection method, the tripler used a push-push differential pair to double the frequency of the input signal and coupled the generated second harmonic to the source common mode node of the injectors through a transformer, which enhanced the second harmonic at the source common mode node of the injectors. Since the injection current is generated by mixing the injected signal with the second harmonic at the source common mode node, the injection current is also enhanced, thereby increasing the locking range. In addition, the tripler adopted a fourth-order resonator, as a result, the phase of the resonant impedance is flattened at the zero-crossing point, then the locking range is further increased. The tripler is implemented in a standard CMOS 65nm process with a chip area of 720×670 um2, and the power consumption is 15.2 mW under a 1.2-V power supply. With 0 dBm power injection, the locking range is 19.2-27.6 GHz, and the corresponding fundamental suppression ratio is greater than 25 dB, and the second harmonic counterpart is beyond 35 dB. The proposed ILFT is capable of the requirements of the oscillation source in the 5G transceiver.
1
Study on the multi-modes, multi-harmonics behavior of a THz large-orbit gyrotron

ZHAO Qi-Xiang, MA Meng-Shi, LI Xiang, LV You, ZHANG Tian-Zhong, Peng Lin, WANG E-Feng, FENG Jin-Jun

Abstract: (79) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

—The large-orbit gyrotrons (LOGs) in the THz range are attractive for the great potential of reducing the required external magnetic field by enabling the high-harmonics operation. In this paper, a LOG capable of operating from the 4^th to the 9^th harmonic is designed and investigated. With the assistance of the 3-D particle-in-cell simulation, the key features of the designed LOG, beam-wave interaction dynamics and high-harmonic operation regimes are studied. It is shown that by tuning the external magnetic field intensity, successive excitation of the oscillation at a number of neighboring harmonics can be achieved, corresponding to radiation frequencies between 240 GHz to 460 GHz with the maximum radiation power of 19 kW. Then, a detailed study of the competition among the 7^th, 8^th and 9^th harmonics are conducted, providing an insight into the multi-modes, multi-harmonics behavior of the high-harmonic LOG. Following that, the methods to stabilize the beam-wave interaction and enable single mode operation at high harmonics are discussed. Additionally, the characterization of the ohmic loss power at different operation harmonics is conducted.
1
Anisotropic tunable multi-order strong coupling in black phosphorous nanodisk-sheet plasmonic system

HAN Li, XING Huai-Zhong

Abstract: (50) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Black phosphorus supports anisotropic surface plasmons, which can be used to design principle devices with more functions. The hybridization behavior of different plasmon modes in the sheet-disk-sheet system based on black phosphorus in the mid-infrared to far-infrared waveband is numerically simulated by the finite-difference time-domain method. By dynamically adjusting the carrier concentration in the black phosphorus, the generation and control of the strong coupling phenomenon in the two lattice directions can be realized. Analyzing and calculating the coupling between different modes, the Rabi splitting energy in the absorption spectrum can be as high as 42.9 meV. In addition, the influence of the polarization angle on the strong anisotropic coupling is also calculated, which can achieve up to 6 absorption bands. The proposed model provides a basis for the construction of compact anisotropic plasmonic devices based on two-dimensional materials that will work in the mid-to-far infrared bands in the future.
1
Nonlinearity correction of FY-3E HIRAS-II in pre-launch thermal vacuum calibration tests

YANG Tian-Hang, GU Ming-Jian, SHAO Chun-Yuan, WU Chun-Qiang, QI Cheng-Li, HU Xiu-Qing

Abstract: (60) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The High-spectral Infrared Atmospheric Sounder II (HIRAS-II) is a Fourier transform spectrometer onboard the world’s first civil early-morning-orbiting FengYun 3E (FY-3E) meteorological satellite, the FY-3E/HIRAS-II focus on a number of upgrades such as the sensitivity of the detector, the accuracy of spectral calibration and radiometric calibration, with the designed and manufactured processing based on the first Chinese hyperspectral infrared (IR) sounder FY-3D/HIRAS-I. We conducted a comprehensive pre-launch thermal vacuum (TVAC) calibration tests for HIRAS-II, including the nonlinearity (NL) correction which consist an essential part of radiometric calibration, the NL correction has considerable effects on radiometric accuracy. According to the HIRAS-II nonlinear behavior of the detectors for long-wave (LW) and mid-wave (MW) infrared spectral bands, the NL correction of raw data in the spectral domain is a scaling of the observed spectrum, the NL correction coefficients are derived by the methods of minimizing the spread of the responsivity functions with varying temperature, or minimizing the spread of the bias of brightness temperature among calibration targets with varying temperature. The bias of spectral brightness temperature is assessed by comparing the NL correction and the non-NL correction radiometric calibration data, the results show that, the radiometric accuracy has been significantly improved via NL correction.
1
Ka&W dual-frequency millimeter-wave cloud radar at Yangbajing ---Performance and comparison

Bi Yong-Heng, HUO Juan, LYU Daren, SU Tao, WANG Xue-rong, LIU Bo

Abstract: (46) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

This paper introduced a new dual-frequency millimeter-wave Doppler radar (YBJ-DFDR, W band 94 GHz, wavelength 3.2 mm, Ka-band 35 GHz, wavelength 8.6 mm) situated at Yangbajing in the Tibet Plateau and presented detailed analysis of the detection capability through calculations and comparisons. The analysis results show that the DFDR has a high sensitivity with -39.2 dBZ and -33 dBZ at 10 km for the W-band radar and Ka-band radar, respectively. It is shown that the radar equivalent reflectivity factor measured by Ka- and W- band radar illustrates various distribution characteristics for different cloud types. When rainfall occurs, W-band radar suffers much more attenuations by precipitation than the Ka-band radar (the difference between them reaches up to 30 dB in some cases), further, the attenuations may cause the loss of the reflectivity of W-band radar. On the other hand, when the cloud particles are mostly ice particles, the attenuation effect significantly decreased, and W-band radar shows stronger detection ability than the Ka-band radar with higher reflectivity values. In addition, it is also found that Ka-band radar is prone to miss more cloud edge areas than the W-band radar, such as the cloud top and cloud bottom area, resulting in underestimation of the cloud top height but overestimation of the cloud bottom height. The main reason is that the cloud particles in these areas are small and number concentration is generally low, which has weak reflectivity lower than the sensitivity of the Ka-band radar
1
High birefringence hollow-core anti-resonant terahertz photonic crystal fiber with ultra-low loss

HUI Zhan-Qang

Abstract: (50) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

An ultra-low loss and high birefringence hollow core anti-resonant terahertz photonic crystal fiber based on cyclic olefin copolymer (COC) is proposed. The cladding of the fiber consists of two groups (six in total) nodeless embedded sleeves. The guided wave characteristics are analyzed by using the finite difference time domain method combined with the perfectly matched layer boundary conditions. The simulation results show that the total transmission loss is less than 0.1 dB/m, birefringence is more than 2.12 × 10-5 within the range of 0.8 THz - 1.35 THz, dispersion in ± 0.027 ps/THz/cm. At 1.12 THz, the minimum total transmission loss is only 0.543 × 10-2 dB/m, birefringence value 2.06 × 10-4. The bending performance of the fiber is analyzed. It is shown that in y direction, when the bending radius is more than 19 cm, the bending loss is less than 0.1 dB/m, and the bending performance is good.
1
Analysis and verification of the positioning accuracy of a flat-panel detector used for precision pointing in space optical communication

WANG Xu, Tu Cheng-Xiang, ZHANG Liang, WANG Jian-Yu

Abstract: (128) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

To realize a high-precision link in space optical communication, we analyzed key factors that affect the accuracy of flat-panel detectors in terms of target positioning. The error of the centroid algorithm was analyzed from the mechanism and the necessity of satisfying the spatial lossless sampling condition was verified by using a simulation. The defined NU value served as an indicator in quantifying the nonuniformity of the detector. As the NU value increased linearly, the positioning error of the centroid continued to increase, whereas the speed reduced. When the NU value was 0.005, the maximum positioning error was 0.043 pixels. Considering that the light intensity of the target incident on the optical system varies constantly, the smaller the NU value, the closer the centroid is to the true position of the light spot. Furthermore, the pixel response of a typical complementary metal oxide semiconductor (CMOS) detector was experimentally tested under different illumination intensities. Based on the response curve, a mathematical model for the nonuniformity of the pixel response was established. It can be determined that the NU value fluctuates from 0.0045 to 0.0048 within the linear response range. The experimental results of the spot centroid positioning accuracy verify that the absolute positioning error is less than 0.05 pixels, which satisfies the requirements of high-precision links. Therefore, the effectiveness of the theory and simulation presented in this study can be validated.
1
Retrieval of supercooled water in convective clouds over Nagqu of the Tibetan Plateau using Millimeter-wave radar measurements

Ren Tao, ZHENG Jia-Feng, LIU Li-Ping, ZOU Ming-Long, CHEN Shao-Jie, HE Jing-Shu, LI Jian-Jie

Abstract: (104) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Abstract: Supercooled water in convective clouds has always been a difficult point in meteorological detection. In this paper, based on Doppler spectra of a Ka-band millimeter-wave radar used in the third Tibetan Plateau Atmospheric Experiment and relevant radiosonde data, an algorithm for identifying and retrieving supercooled water in convective clouds over Nagqu of the Tibetan Plateau was proposed. Subsequently, retrieval effects of the algorithm were analyzed using two convective cases (including stratocumulus, cumulus humilis, and altocumulus clouds), and verified by comparing with measurements from a co-located microwave radiometer (MWR). Finally, two useful empirical relations of effective radius–radar reflectivity (R_e–Z_e) and liquid water content–radar reflectivity (LWC–Z_e) for the supercooled water in convective clouds over Nagqu were presented. The main findings are as follows: The stratocumulus, cumulus congestus, and altocumulus clouds over Nagqu are dominated by updrafts with rapid changes on the hydrometeor phase in the vertical orientation, resulting widely distributions of the formed supercooled particles in terms of both their Z_e, R_e, and LWC. Supercooled particles in different convective cloud types also locate at different cloud body positions. The velocity of the in-cloud updraft is highly and positively correlated with the supercooled water Z_e, R_e, and LWC. They possess similar temporal variations and coincident spatial distributions. The retrieved spatial positions and microphysical parameters of the cloud supercooled water are consistent with the conclusions of previous studies and observations. The radar-derived LWP are also proved to agree well with the counterparts of MWR with similar temporal variations and value peaks. Their correlation coefficients can approach 0.63–0.79. For convective clouds of the Tibetan Plateau, R_e and Z_e of the supercooled water exhibit a confident power empirical relations, namely, R_e=195.4Z_e^1.78+8 for cloud droplets and R_e=67.8Z_e^0.3 for raindrops, respectively. Supercooled raindrops also possess a certain LWC–Z_e, that is LWC=0.024Z_e^0.82, whereas, the power-form relation for the cloud droplets is inapparent.
1
Study on the improvement of scan mirror thermal radiation correction on the calibration accuracy of FY-4A AGRI

LI Xiu-Ju, WANG Bao-Yong, WU Ya-Peng, HAN Chang-Pei, CAO Qi, ZHOU Shu-Tian, WANG Wei-Cheng, LI Pan-Pan

Abstract: (127) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The Advanced Geostationary Radiation Imager (AGRI) is one of the main payloads of Fengyun-4A (FY-4A). In order to satisfy requirements of high-precision quantitative application of AGRI long-wave infrared (LWIR) remote sensing data, the function model of scan mirror thermal radiation changing with mechanical rotation angle is constructed, and a correction algorithm for remote sensing data of on-board blackbody and earth scene observation is presented. Based on the on orbit data of FY-4A AGRI, the dependence of the model parameters on the scan mirror temperature is analyzed, and the improvement effect of the correction algorithm on the calibration accuracy of LWIR is studied and evaluated. In the stationary period of scan mirror temperature field, the calibration deviation of B11(8.0~9.0μm), B12(10.3~11.3μm), B13(11.5~12.5μm) can be improved significantly by -2.81K~+1.06K, -0.60K~+0.19K, -0.68K~+0.24K respectively. The result of cross calibration validation with IASI show that the improved on orbit calibration brightness temperature bias is better than 0.5K@290K.
1
Research on p-on-n LWIR and VLWIR HgCdTe infrared focal plane detectors technology

LI Li-Hua, XIONG Bo-Jun, YANG Chao-Wei, LI Xiong-Jun, WAN Zhi-Yuan, ZHAO Peng, LIU Xiang-Yun

Abstract: (75) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The p-on-n structure doped with As implantation has the advantages of low dark current,high R0A product, and long minority carrier lifetime,which is an important trend in the development of long-wavelength and very long-wavelength HgCdTe infrared focal plane detectors. P-on-n LWIR and VLWIR HgCdTe infrared focal plane detectors with cut-off wavelength of 9.5μm and 10.1μm at 77 K and 14.97 μm at 71 K fabricated by Kunming Institute of Physics are introduced.Test and analyze performance parameters such as the responsivity, NETD, dark current and R0A of the detectors. The test results show that the operable pixel factor of the detectors is between 99.78% and 99.9%,and the NETD of the detectors is less than 21 mK. The effective fabrication of p-on-n LWIR and VLWIR HgCdTe infrared focal plane detectors is realized.
1
THz ISAR Imaging Using GPU-Accelerated Phase Compensated Back Projection Algorithm

LIANG Mei-Yan, ZHANG Cun-Lin, ALY E FATHY

Abstract: (95) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Here, we present our implementation of two-dimensional (2D) high-resolution inverse synthetic aperture radar (ISAR) imaging using a 0.22 THz stepped-frequency (SF) radar system. The system is suitable for both near- and far-field imaging with a synthesis bandwidth of 12 GHz. The radar can provide highly accurate range and cross-range results in the near field, and its ISAR image can reach centimeter-level resolution upon using a phase-compensated Back-Projection algorithm (BP algorithm). These BP-realized results indicate that THz ISAR imaging can achieve both higher precision and finer resolution when compared to previously demonstrated range-doppler (RD) results with the same SFCW radar setup. To accelerate BP’s relatively slow image retrieval process, we employ accelerated platforms based on a graph-processing unit (GPU). Such success should pave the way for further research on near-field high-resolution radar imaging especially at THz/sub-millimeter bands.
1
Graphene-embedded waveguide with improved modulation capability

Xiliang Peng, Xin Yang

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

Abstract:

We propose a graphene-embedded waveguide (GEW) with improved modulation capability, which can be over 2 times larger than that of conventional graphene-on-silicon (GOS) waveguide. More importantly, it is found that the improvement of modulation capability mainly results from the enhanced electric field confinement around graphene. Based on this finding, we propose a high-efficient method to optimize the modulation capability. By using this method, the optimization work can be reduced by an order of magnitude. Our work may promote the design of graphene-based electro-optic modulator with high modulation capability.
1
A Distributed Small Signal Equivalent Circuit Modeling Method for InP HEMT

QI Jun-Jun, LYU Hong-Liang, CHENG Lin, Zhang Yu-Ming, ZHANG Yi-Men, ZHAO Feng-Guo, DUAN Lan-Yan

Abstract: (100) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

In this paper, a distributed small signal equivalent circuit modeling method for InP HEMT is presented. The distributed capacitance effect is taken into account in the adopted model, which is characterized by adding three distributed capacitances. For accurate modeling, considering the error caused by parasitic inductance when extracting parasitic capacitance, the parasitic inductance is extracted first. The validity of the proposed small signal modeling method has been verified with excellent agreement between the measured and modeled S-parameters up to 50GHz for InP HEMT. In addition, the proposed S-parameters fitting error is less than 4% in 2~50 GHz, which also proves the applicability of the proposed modeling methods for InP HEMT.
1
Recent Progress on Natural Biomaterials Boosting High-Performance Perovskite Solar Cells

Shaobing Xiong, Qinye Bao, Junhao Chu

Abstract: (135) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Perovskite solar cells (PeSCs) have been considered as one of the most promising photovoltaic technologies due to their high efficiency, low-cost and facile fabrication process. The power conversion efficiency and stability of PeSCs highly depend on the quality of perovskite film and the interfaces in the device, which are the main sources of PeSC nonradiative recombination losses. Natural biomaterials, with the advantages of earth-abundance, non-toxicity, and biocompatibility, have shown huge potential to improve both perovskite layer and interfaces in PeSCs. Herein, the latest progress using natural biomaterials to achieve high-performance PeSCs is reviewed. We firstly discuss the roles of natural biomaterials on perovskite film in terms of morphology optimization, defect passivation and energetics modification. Meanwhile, the strategies using natural biomaterials to create superior interface between perovskite and charge transport layer, and to build stretchable, biocompatible, and biodegradable electrodes are present. Finally, an outlook on the further development of PeSCs with respect to natural biomaterials is provided.
1
Design of a novel Y-junction electro-optic modulator based on thin film lithium niobite

GuoHongjie, LIU Hai-Feng, WANG Zhen-Nuo, TAN Man-Qing, Lei Ming, LI Zhi-yong, GUO Wen-Tao, GUO Xiao-Feng

Abstract: (141) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

In recent years, the high-performance electro-optic modulator based on Thin-film lithium niobate (TFLN) platform has been receiving considerable attention due to the featuring small-footprint and low energy loss. In this paper, a novel Y-junction electro-optic modulator with a vertical electrode structure was designed based on TFLN. The relationship between the low half-wave voltage and the buffer layer thickness for the novel modulator was investigated. Meanwhile, the design parameters of Y-junction were optimized, and found that the half-wave voltage is less than 1.5 V and the insertion loss is less than 5 dB. Finally, the Y-junction electro-optic modulator was fabricated. This study not only provides insights on the design and realization of compact footprint photonic waveguides in TFLN platform, but also, experimental evidences for fabrication of electro-optic modulator with high-performance and multifunction.
1
The band gap regulation of HgxCd1-xTe quantum dots by ion exchange and their near-infrared self-absorption characteristics

FANG Shi-yu, LIU Zhen-yu, JIN Jia-jie, SHI Ji-Chao, FANG Yong-zheng, SUN Chang-hong, YE Zhen-hua, LIU Yu-feng

Abstract: (182) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The ion exchange is one of the important methods to realize the band gap regulation of alloy quantum dots. In this paper, monodispersed CdTe quantum dots are synthesized by soft chemical method. Meanwhile, mercury cadmium telluride (HgxCd1-xTe) quantum dots with the quasi continuous visible to near-infrared spectrum are prepared by ion exchange adjusting the concentration of Hg2+. The variable temperature photoluminescence and self-absorption characteristics of near-infrared Hg0.33Cd0.67Te quantum dots are deeply analyzed. The results indicate that the fluorescence intensity of HgxCd1-xTe quantum dots decreases linearly with the increase of temperature (0-100 ℃). The spectral line broad and the peak position has a red-shift (12nm). The partial overlap of absorption and emission spectra of quantum dots leads to self-absorption. The increase of self-absorption results in decrease of photoluminescence intensity while the concentration of quantum dots increases.
1
Fast moving target detection algorithm based on LBP texture feature in complex background

QIU Li-Ya, CHEN Wei-Lin, LI Fan-Ming, LIU Shi-Jian, LI Zheng, TAN Chang

Abstract: (179) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

In the visible and infrared scenes with complex background, such as rain and snow weather, leaf swaying, shimmering water, etc., fast and accurate extraction of a complete target has always been the primary problem in moving target detection. In order to be real time and aiming at the problems of existing video foreground extraction algorithms, such as dependence on prior information, low recall rate, lack of texture and large noise, a background modeling method based on histogram statistics and improved LBP（Local Binary Pattern） texture features is proposed. Firstly, the mode of each pixel histogram is used as the reference background without prior knowledge, which saves a lot of storage space. Then, an improved S_MBLBP texture histogram is proposed to model the background with the reference background by using neighborhood compensation strategy, which eliminates most of the dynamic background and illumination changes, and realizes the accurate extraction of the target. Experimental results show that the proposed algorithm can quickly extract foreground targets in a variety of complex infrared and visible scenes, and can improve the accuracy and recall rate at the same time.
1
Preparation of epi-ready InAs substrate surface for InAs/GaSb superlattice infrared detectors grown by MOCVD

LIU Li-Jie, ZHAO You-Wen, HUANG Yong, ZHAO Yu, WANG Jun, WANG Ying-Li, SHEN Gui-Ying, XIE Hui

Abstract: (181) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Total reflection X-ray fluorescence spectroscopy (TXRF) and X-ray photoelectron spectroscopy (XPS) have been used to investigate residual impurities and oxides on polished InAs substrate surface wet cleaned by different solution combination. Metal impurities Si, K and Ca are routinely detected on the cleaned InAs surface and their concentration change with the variation of solution combination. A large quantity of particles (80nm size) are measured on the InAs substrate surface with higher residual impurity concentration. An effective wet chemical cleaning procedure is presented to prepare InAs substrate surface with less residual impurity, small particle quantity and thin oxide layer, which are beneficial to high quality epitaxial growth.
1
Study on the Influence of Hg Vacancy Control of HgCdTe Materials with Different Passivation Layers through Thermal Annealing

Shen Chuan, Liu Yang-Rong, Sun Rui-Yun, Bu Shun-Dong, Chen Lu, He Li

Abstract: (169) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The control of Hg vacancy concentration in HgCdTe grown by MBE with different passivation layer structures was studied. Higher Hg vacancy concentration in HgCdTe was obtained, which provides a basis for the subsequent research and development of new focal plane devices. It was found that the change of Hg vacancy concentration in HgCdTe varies with the structure of passivation layer during thermal annealing. The change is because the existence of the passivation layer of the HgCdTe surface layer changes the equilibrium process of the original thermal annealing. At the same time, the secondary ion mass spectrometry (SIMS) test and the corresponding theoretical fitting were verified the results.
1
Research on summer Arctic cloud detection model based on FY-3D/MERSI-II infrared data

WANG Xi, LIU Jian, YANG Bing-Yun

Abstract: (217) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Satellite is one of important observation data sources in Arctic. Due to the complex characteristics of atmospheric and underlying surface, it is extremely challenging for developing the cloud mask algorithm and the derived product accuracy in Arctic by satellite passive remote sensing. A summer cloud detection model in Arctic was studied based on FY-3D/MERSI-II (FengYun-3D/Medium Resolution Spectral Imager-II). Combined with the observations infrared cloud detection tests for the Arctic summer were proposed. The probability distribution density analysis method was adopted, and the loss rate was introduced to optimize the relevant thresholds. Meanwhile, the relevant thresholds were optimized to develop a cloud detection model based on the confidence levels. The validation results reveal that the cloud detection results are highly consistency with the matched CALIPSO observations. The high confidence levels basically represent the cloudy pixels, while the low values correspond to the clear ones. The case study shows that the ratio of cloudy pixels is 100% with confidence level higher than 0.8. When the confidence level is lower than 0.2, 10.15% of the cloudy pixels are still misjudged as clear pixels, which are primarily single-layer clouds with the cloud top heights between 4 and 6km. This may be caused Pby cirrus clouds and still need further study.
1
Accuracy Estimation of Microwave Performance for InP HBTs based on Monte-Carlo Analysis

CAO Ke-Jing, ZHANG Ao, GAO Jian-Jun

Abstract: (209) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

In order to verify the reliability of the circuit, the microwave performance for InP HBTs is analyzed based on Monte-Carlo method. The larger the fluctuation range is, the higher the accuracy of extracting intrinsic parameters is required. The allowable accuracy range can be inferred from the output performance. The microwave characteristics are composed of modeled S-parameters, current gain cut-off frequency and maximum oscillation frequency. The standard deviation of Monte-Carlo numerical analysis can be derived from the uncertainty curve of the intrinsic parameters of the π-topology small signal model. The results of Monte-Carlo analysis show that the requirements for the accuracy of measurement parameters are quite different under different frequency and bias conditions, which verifies the reliability of the circuit under different conditions.
1
A THz-TDS based Metamaterial Sensor for Sensitive Distinguishment of Food Additives

MA Jia-Lu, TANG Jing-Chao, WANG Kai-Cheng, GUO Liang-Hao, WANG Shao-Meng, GONG Yu-Bin

Abstract: (308) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

A sensitive terahertz (THz) metamaterial sensor for the distinguishment of common additives in the food industry is proposed. The metamaterial sensor consists of an array of split ring resonator (SRR) with double tip ends. By checking the resonate frequency shift of the sensor, the concentration and the type of the solution sample can be distinguished. The metamaterial sensor is fabricated on a quartz substrate, which is transparent for THz wave. The solutions with the concentration of 0.2, 0.4, 2 and 4mg/ml have been measured by using a terahertz time domain spectroscopy (THz-TDS). The results illustrate that the proposed metamaterial sensor can detect the concentration of the solution sample, as low as 0.2mg/ml. Meanwhile, different solutions with same concentration can also be clearly distinguished. Our study provides new insights for the application of terahertz metamaterial sensor based on SRR structure in the field of food safety.
1
Interfacial properties between Al₂O₃and In_0.7₄Al_0.2₆As epitaxial layer on MIS capacitors

WAN Lu-hong, SHAO Xiu-mei, LI Xue, GU Yi, MA Ying-jie, LI Tao

Abstract: (264) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Metal-Insulator-Semiconductor (MIS) capacitors were fabricated on In_0.7₄Al_0.2₆As/In_0.7₄Ga_0.2₆As/In_xAl_1-xAs heterostructure multilayer semiconductor materials. SiN_x and SiN_x/Al₂O₃ bilayer were applied as insulating layer to prepare MIS capacitors respectively. High-resolution transmission electron microscope (HRTEM) and X-ray photoelectron spectroscopy (XPS) measurements indicated that, compared with SiN_x deposited by inductively coupled plasma chemical vapor deposition (ICPCVD), Al₂O₃ deposited by atomic layer deposition (ALD) can effectively suppresses In₂O₃ at the interface between Al₂O₃ and In_0.74Al_0.26As. According to the capacitance-voltage (C-V) measurement result of MIS capacitors, the fast interface state density (D_it) of SiN_x/Al₂O₃/In_0.74Al_0.26As is one order of magnitude lower than that of SiN_x/In_0.74Al_0.26As. The above results are calculated using the high-low frequency method. Therefore, it can be concluded that Al₂O₃ deposited by ALD as a passivation film can effectively reduce the interface state density between Al₂O₃ and In_0.74Al_0.26As, thereby reducing the dark current of p-In_0.7₄Al_0.2₆As/i-In_0.76Ga_0.24As/n-In_xAl_1-xAs photodiodes.
1
Photonic crystal flat lens for polarization mode and light source insensitively

Liu Jian-Jun, CEN Yuan, XIE Jian-lan

Abstract: (301) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The photonic crystal (PC) flat lens has broad application prospects in the field of super-resolution imaging and it has been researched deeply, but the lenses studied in the past are only suitable for specific polarization mode or specific incident light source. To this end, we propose a kind of PC flat lens with scatterer-size gradient. This flat lens can simultaneously realize point source imaging and plane wave focusing in TM and TE polarization modes, and break through the diffraction limit in TM polarization mode, and realize sub-wavelength imaging and focusing in TE polarization mode. This flat lens can realize polarization-insensitive imaging and focusing without any additional polarization components. It is expected to be used in the design of multi-functional optical polarization-insensitive imaging and focusing devices, and can be applied to real-time biological display, high-density optical storage and microelectronic lithography, and improve the application potential of gradient PC flat lens.
1
Research progress of copper indium gallium selenide thin film solar cells

TAO Jia-Hua, CHU Jun-Hao

Abstract: (301) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

The industrialization of copper indium gallium selenide (CIGS) solar cells has attracted worldwide attention. As a thin film solar cell with high conversion efficiency, its efficiency can be compared with that of crystalline silicon solar cell, and the highest efficiency reaches 23.35% at present. For small-area laboratory solar cells, the main research focus is to accurately control the stoichiometric ratio and efficiency of absorption layer. For industrial production, besides stoichiometric ratio and efficiency, cost, reproducibility, output and process compatibility are very important in commercial production. The research progress of different preparation processes, gradient control of absorption layer composition, post-deposition treatment of alkali metal, wide band gap cadmium-free buffer layer, transparent conductive layer and flexible substrate were reviewed. From the perspective of the efficiency of CIGS solar cells, the transfer of record-breaking high-efficiency solar cell technology in the laboratory to the average industrial production level brings obvious challenges.
1
Design and Test of a Low Voltage Suspended Dual-Microstrip Meander-Line Slow Wave Structure at Ka Band

HE Teng-Long, WANG Shao-Meng, LI Xin-Yi, XU Duo, SHI Ning-Jie, WANG He-Xin, GONG Hua-Rong, LU Zhi-Gang, WANG Zhan-Liang, DUAN Zhao-Yun, GONG Yu-Bin

Abstract: (326) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

A suspended dual- microstrip meander-line (SDMML) slow wave structure (SWS) is proposed in this paper. It consists of a metal enclosure as well as a suspended dielectric substrate, on the upper and lower surfaces of which are two metal meander-lines. As there are two electron beam tunnels locating above and below the dielectric substrate, and the electromagnetic wave has symmetrical distribution, it is possible to use one electron beam in each tunnel to drive the electromagnetic wave for a higher output power. The high frequency characteristics and the beam-wave interaction results of the SDMML SWS have been investigated by using simulation software. The hot performances of this SWS show that for two identical sheet beams with a voltage of 2050 V and a current of 0.2 A, the SDMML SWS has a maximum gain of 26 dB at 36 GHz and 3-dB bandwidth of saturation power of 8 GHz. To verify the simulation result, a SDMML SWS is fabricated by using new fabrication methods including the magnetron sputtering electroplate and laser ablation. The measured reflection loss of the SDMML SWS is better than -10 dB. The transmission loss of the fabricated slow wave structure is analyzed and verified through simulation and experimental results.
1
Design and Realization of InP-based Resonant Tunneling Diode THz Oscillator

liujun, Song Ruiliang, Liu Ning, Liang Shixiong

Abstract: (392) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Above 1 THz InP-based resonant tunneling diode (RTD) oscillator was designed and realization with Si-lens package. The RTD model was build and studied using Silvaco software including the influence of the doping concentration of emitter, the thickness of the barrier layer, space layer and well layer on the DC characteristics of the device. The DC measurement of the RTD shows peak current density Jp is 359.2 kA/cm2, valley current density Jv is 135.8 kA/cm2, peak-to-valley current ratio (PVCR) is 2.64, maximum RF output power of 1.71 mW and oscillation frequency (fmax) of 1.49 THz are theoretically calculated. The oscillator with an on-chip Bow-tie antenna has been packaged with Si-lens and the measurement shows the output power of 2.57 μW at an operation frequency of above 1 THz, the DC power consumption is 8.33 mW. This is the first reported oscillator of frequency above 1 THz in domestic.
1
High performance Ge:B blocked impurity band detector developed by the near surface process technique

Pan Chang-Yi, Mou Hao, Yao Xiao-Mei, Hu Tao, Wang Yu, Wang Chao, Deng Hui-Yong, Dai Ning

Abstract: (344) HTML (0) PDF (0.00 ByteKB) (0)

Abstract:

Blocked impurity band (BIB) detectors are the start-of-art choice for far infrared astronomical observation. Ge:B BIB far infrared detector has been successfully developed using near surface process technique. The spectral response covers a wide range from 50 cm^(-1) to 400 cm^(-1). At 3.5 K and at 30 mV, the detector exhibits a highly competitive responsivity 21.46 A/W and a highly competitive detectivity of 4.34×10^14 cm?Hz1/2?W-1 at the peak response of 84.9 cm^(-1). We have studied the influence of the interfacial barriers on the spectral response. A new excitation model that the carriers in the contact regions can be excited over the interfacial barriers is proposed. A new method to enhance the relative response intensity of BIB detectors in the low wavenumber region is found.
1

Select All

Display Method:: |

Volume 40,2021 Issue 5

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

Remote Sensing Technology and Application

Infrared Photoelectric Technology and Application

Image Processing and Software Simulation

Volume 40,2021 Issue 5

40周年特邀

遥感技术与应用

Infrared Photoelectric Technology and Application

Terahertz and Millimeter Wave Technology

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

红外材料与器件

遥感技术与应用

Terahertz and Millimeter Wave Technology

红外光谱与光谱分析

Terahertz and Millimeter Wave Technology

红外光谱与光谱分析

40周年特邀

太赫兹与毫米波技术

红外材料与器件

遥感技术与应用

红外材料与器件

Terahertz and Millimeter Wave Technology

Infrared Materials and Devices

Infrared Photoelectric Technology and Application

Terahertz and Millimeter Wave Technology

红外光谱与光谱分析

红外材料与器件

Terahertz and Millimeter Wave Technology

遥感技术与应用

Infrared Materials and Devices

图像处理及软件仿真

Terahertz and Millimeter Wave Technology

遥感技术与应用

红外光谱与光谱分析

Infrared Photoelectric Technology and Application

遥感技术与应用

太赫兹与毫米波技术

图像处理及软件仿真

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

遥感技术与应用

Infrared Photoelectric Technology and Application

Terahertz and Millimeter Wave Technology

Infrared Photoelectric Technology and Application

红外光谱与光谱分析

Infrared Photoelectric Technology and Application

Infrared Materials and Devices

红外光谱与光谱分析

Infrared Materials and Devices

Volume 40,2021 Issue 5

Infrared Spectroscopy and Spectral Analysis

Image Processing and Software Simulation

Terahertz and Millimeter Wave Technology

Image Processing and Software Simulation

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

Image Processing and Software Simulation

Terahertz and Millimeter Wave Technology

UserLogin