Your search keyword '"infrared detectors"' showing total 9,496 results

1. Native point defects in HgCdTe infrared detector material: Identifying deep centers from first principles.

Author

Chen, Wei, Rignanese, Gian-Marco, Liu, Jifeng, and Hautier, Geoffroy

Subjects

*POINT defects, *SPIN-orbit interactions, *MERCURY, *INFRARED detectors, *FUNCTIONALS

Abstract

We investigate the native point defects in the long-wavelength infrared (LWIR) detector material H g 0.75 C d 0.25 Te using a dielectric-dependent hybrid density functional combined with spin–orbit coupling. Characterizing these point defects is essential as they are responsible for intrinsic doping and nonradiative recombination centers in the detector material. The dielectric-dependent hybrid functional allows for an accurate description of the bandgap (E g) for Hg 1 − x Cd x Te (MCT) over the entire compositional range, a level of accuracy challenging with standard hybrid functionals. Our comprehensive examination of the native point defects confirms that cation vacancies V Hg (Cd) are the primary sources of p -type conductivity in the LWIR material given their low defect formation energies and the presence of a shallow acceptor level (− /0) near the valence-band maximum. In addition to the shallow acceptor level, the cation vacancies exhibit a deep charge transition level (2 − / −) situated near the midgap, characteristic of nonradiative recombination centers. Our results indicate that Hg interstitial could also be a deep center in the LWIR MCT through a metastable configuration under the Hg-rich growth conditions. While an isolated Te antisite does not show deep levels, the formation of V Hg –Te Hg defect complex introduces a deep acceptor level within the bandgap. [ABSTRACT FROM AUTHOR]

Published

2024

2. Structural properties and defect formation mechanisms in MBE-grown HgCdTe on InSb (211)B substrates.

Author

Pan, Wenwu, Ma, Shuo, Sun, Xiao, Gu, Renjie, Faraone, Lorenzo, and Lei, Wen

Subjects

*MOLECULAR beam epitaxy, *INFRARED detectors, *THIN films, *TRANSMISSION electron microscopy, *X-ray diffraction, *REFLECTANCE spectroscopy

Abstract

This work investigates the structural properties of HgCdTe thin films grown on InSb (211)B substrates using molecular beam epitaxy (MBE). The Cd composition of thin films is accurately determined using non-destructive approaches based on x-ray diffraction (XRD) and reflectance infrared spectroscopy. The as-grown HgCdTe thin films exhibit characteristic surface defects with a size of 7–10 μm and density of ∼105 cm−2, resulting in an additional spread in XRD full width at half maximum. Cross-sectional transmission electron microscopy results indicate that these defects are caused by surface In droplet formation during the oxide removal process of InSb substrate, which subsequently results in the formation of In4Te3 inclusions and extended defects in MBE-grown HgCdTe. Our findings provide additional confirmation that suppressing thermally induced damage of the InSb substrate is necessary for fabricating high-performance infrared detectors using HgCdTe grown on InSb substrates. [ABSTRACT FROM AUTHOR]

Published

2023

3. Parallel coupling of gas chromatography to mass spectrometry and solid deposition Fourier transform infrared spectroscopy: an innovative approach to address challenging identifications.

Author

Coppolino, Carmelo, Trovato, Emanuela, Salerno, Tania M. G., Cucinotta, Lorenzo, Sciarrone, Danilo, Donato, Paola, and Mondello, Luigi

Subjects

*INFRARED detectors, *MASS spectrometry, *HYDROCARBON analysis, *ZINC selenide, *CHEMICAL libraries

Abstract

The request for novel hyphenated instruments and techniques, capable of affording exhaustive information and results, is a focus continuously watched out. In this context, the present work aimed at the development of an integrated system combining gas chromatographic (GC) separation with mass spectrometry (MS) and (solid deposition) Fourier transform infrared spectroscopy (FTIR) detection. An external transfer line was designed in the lab for the parallel coupling of the two detectors, in such a way to obtain complementary analytical information consisting of an MS spectrum, an IR spectrum and linear retention indices (LRI), within a single analysis. The instrument performance was demonstrated for the analysis of a commercial mixture consisting of 139 hydrocarbons, comprising linear, branched, unsaturated and aromatic compounds. A 100-m poly(dimethylsiloxane) column was employed for the separation, and the outlet flow was split 95:5 between the IR and MS detectors using two uncoated capillaries. The IR spectra were acquired from solid deposits on a zinc selenide disc (−90 °C), over a spot (detector area) of about 0.1 mm2, in the range of 4000–700 cm−1 and at a resolution of 4 cm−1. Final identification of the separated compounds by a library search was achieved by excluding incorrect results, sequentially using a three-filter approach (85% similarity against reference MS and IR library spectra and ±10 LRI unit tolerance). Based on these preliminary results, the GC-MS/sd-FTIR system is a promising tool for the characterization of complex matrix constituents, for which identification is cumbersome, by using only one detection technique. [ABSTRACT FROM AUTHOR]

Published

2024

4. Nb/Mn co‐doping enhances the pyroelectric properties of Na0.5Bi4.5Ti4O15 ceramics for infrared detection.

Author

Fan, Mingzhi, Cen, Fangjie, Gao, Ruisi, Pan, Yangsheng, Shen, Meng, Zhang, Haibo, Jiang, Shenglin, Li, Kanghua, and Zhang, Guangzu

Subjects

*PYROELECTRIC detectors, *CURIE temperature, *INFRARED detectors, *INFRARED imaging, *SMART homes

Abstract

The pyroelectric effect has wide applications in various fields, such as infrared imaging, detection, alarms, and the expanding field of smart homes. The rapid advancement of smart systems, focusing on miniaturization and integration, requires pyroelectric infrared detectors with high pyroelectric coefficients and Curie temperatures to meet the requirements of integrated processes. However, the Curie temperature of commercial lead zirconate titanate is limited to <230°C, urgently looking for a breakthrough. Here, we explore pyroelectricity in Na0.5Bi4.5Ti4O15 (NBT) ceramics, characterized by a high Curie temperature (∼660°C). We systematically examined the crystal structure modifications and defect dipole effects of the Nb/Mn‐co‐doped NBT. The lattice expansion, distortion of the TiO6 octahedra, and structural transformation tendency from the orthorhombic to tetragonal phase facilitate dipole movements with increasing temperature. Furthermore, the Mn and Nb elements result in the formation of MnTi"–VO·· and NbTi·–MnTi" –NbTi· defect dipoles, inducing additional polarization changes in response to temperature variations. Finally, a significantly improved pyroelectric coefficient of 110 µC m2 K–1 and remarkable temperature stability from 25°C to 300°C is achieved in NBTM‐5Nb ceramics. This co‐doping strategy for enhancing pyroelectric performance can be expanded to other systems and substantially contribute to advancing high‐performance materials for infrared detection. [ABSTRACT FROM AUTHOR]

Published

2024

5. Optimized TCR and MR of La0.67Ca0.33-xSrxMnO3: Ag0.15 ceramics by Sr doping.

Author

Hou, Ruiting, Wang, Shaozheng, Tian, Lanlan, Zhang, Hui, Chen, Qingming, and Li, Yule

Subjects

*TEMPERATURE coefficient of electric resistance, *TRANSITION temperature, *INFRARED detectors, *MAGNETIC properties, *SOL-gel processes

Abstract

Herein, in order to successfully create high-density La 0.67 Ca 0.33- x Sr x MnO 3 : Ag 0.15 (LCSMO: Ag) ceramics (0 ≤ x ≤ 0.05), this research combines sol-gel and solid-phase processes. LCSMO: Ag ceramics electrical transport and magnetic properties were thoroughly investigated. XRD verified that the high-purity orthorhombic perovskite structure (space group Pnma) was produced. As Sr doping rises, the grain size grows, the single electron bandwidth increases, the metal-insulator transition temperature (T MI) continues to climb, and temperature coefficient of resistance (TCR) and magnetoresistance (MR) steadily drop. When x = 0.04, the T MI reaches 302.2 K. At this time, the TCR peak (TCR peak) reaches 24.0 %·K−1 and the MR peak reaches 49.2 %. These results demonstrate that Sr may effectively raise the T MI of LCMO: Ag ceramics to room temperature while maintaining high TCR and MR Values, which benefits the material's potential applications in devices such as uncooled infrared detectors. [ABSTRACT FROM AUTHOR]

Published

2024

6. Recent Advancements in Nanomaterials for Near‐Infrared to Long‐Wave Infrared Photodetectors.

Author

Sharma, Ravinder, Henderson, Leaford Nathan, Sankar, Pranitha, Tresa, Maydenee Maydur, Oyeku, Olusola Pelumi, Perez, Edward, and Thomas, Jayan

Subjects

*INFRARED detectors, *TECHNOLOGICAL innovations, *NIGHT vision, *PHOTODETECTORS, *OPTOELECTRONICS

Abstract

Nanomaterials have superior electronic, optical, and mechanical properties making them highly suitable for a range of applications in optoelectronics, biomedical fields, and photonics. Nanomaterials‐based IR detectors are rapidly growing due to enhanced sensitivity, wide spectral range, and device miniaturization compared to commercial photodetectors. This review paper focuses on the significant role of nanomaterials in infrared detection, an area critical for enhancing night vision and health monitoring technologies. The latest advancements in IR photodetectors that employ various nanomaterials and their hybrids are discussed. The manuscript covers the operational mechanisms, device designing, performance optimization strategies, and material challenges. This review aims to provide a comprehensive overview of the current developments in nanomaterial‐based IR photodetectors and to identify key directions for future research and technological advancements. [ABSTRACT FROM AUTHOR]

Published

2024

7. Elucidating the structural, morphological and optical properties of chalcogenide glasses within antimony-tin-selenium ternary system.

Author

Khajuria, Rajni, Singh, Anoop, Rather, Mehraj ud Din, Sharma, Anshu, Angotra, Poonam, Sundramoorthy, Ashok K., Dixit, Saurav, Vatin, Nikolai Ivanovich, and Arya, Sandeep

Subjects

*BAND gaps, *INFRARED detectors, *CRYSTAL lattices, *SCANNING electron microscopy, *TERNARY system

Abstract

Antimony-Selenium-Tin (Sb-Se-Sn) is a ternary chalcogenide have wide range of potential applications, because of their high strength, various crystal lattices, and electrical characteristics. In this work, the melt quenching method was used to synthesize the nanoparticles of Sb14Se86-xSnx (x = 0, 3, 6, 9, 12) chalcogenide glasses. X-ray diffraction (XRD) and the Scanning electron microscopy (SEM) of the Sb14Se74Sn12 chalcogenide glasses ascertained the amorphous characteristics. No extra impurity was detected in any chalcogenide, and the presence of only Sb, Se and Sn was detected from the EDS spectra. The decrease in band gap is revealed with the increase of Sn content in the Sb14Se86-xSnx glasses. Lowest band gap was observed in the Sb14Se74Sn12 chalcogenide, attributed to the large crystallite size. The FTIR spectrum of the sample reveals an absorption band roughly between 500 –400 cm-1, attributed to the vibrational modes for Sb–Se, Sn–Se and Sn-Sb bonds. In the chalcogenide glasses, the Sn and Sb 3d state comprises of two peaks, corresponding to doublet state (3d5/2 and 3d3/2), while as Se has only singlet state (3d). In conclusion, in the Sb14Se86-xSnx (x = 12) chalcogenide glass, an increase in photoluminescence intensity and the decrease in band gap makes it potential candiate for the infrared detectors, and the infrared optical fibres. [ABSTRACT FROM AUTHOR]

Published

2024

8. Enhanced Pyroelectricity Over Extended Thermal Range in Flexible Polymer Thin Films.

Author

Xie, Kaili, Housseini, Joulia, Resende, Pedro M., Le Goupil, Florian, Isasa, Jean‐David, Tencé‐Girault, Sylvie, Fleury, Guillaume, Kellay, Hamid, and Hadziioannou, Georges

Subjects

*POLYMER films, *INFRARED detectors, *CORE materials, *CRYSTALLINE polymers, *TRANSITION temperature, *FERROELECTRIC polymers

Abstract

Polymer‐based pyroelectric thin films are crucial functional materials at the core of flexible and lightweight electronic devices, such as wearable monitoring sensors, energy harvesters, and infrared detectors. Nevertheless, the pyroelectric properties of the polymer films, such as poly(vinylidene fluoride‐trifluoroethylene) (P(VDF‐TrFE)), vanish when the surrounding temperature exceeds the ferroelectric‐to‐paraelectric transition temperature, and thus limits their pyroelectric performance to a low‐temperature range. Herein, to mitigate this issue by employing a new class of P(VDF‐TrFE) copolymer which has a low TrFE molar content is proposed. Fine‐tuning of the structure through thermal annealing in a vacuum environment significantly favors robust and highly polarized polymer films with a large area. Electric poling combined with an optimal annealing temperature (110–120 °C) gives highly ordered ferroelectric crystalline domains in the polymer films. Consequently, this remarkably broadens the temperature range (roughly up to 140 °C) for which the polymer film still presents high pyroelectric properties (pyroelectric coefficient 50 µC (m2K)−1). This study provides an alternative choice for pyroelectric polymer films with enhanced pyroelectricity in applications that require wider temperature ranges. [ABSTRACT FROM AUTHOR]

Published

2024

9. 2D Black Phosphorus Infrared Photodetectors.

Author

Zhu, Xianjun, Cai, Zheng, Wu, Qihan, Wu, Jinlong, Liu, Shujuan, Chen, Xiang, and Zhao, Qiang

Subjects

*INFRARED detectors, *PHOTODETECTORS, *ELECTRONIC equipment, *CHARGE carrier mobility, *PHOSPHORUS, *OPTOELECTRONIC devices

Abstract

2D black phosphorus (b‐P) possesses several remarkable properties, including ambipolar transport, high carrier mobility, in‐plane anisotropy, polarization sensitivity, a narrow direct bandgap that can be tuned with the number of layers, and highly compatible with silicon‐based technologies. These characteristics make it a promising material for photodetection in the near‐infrared to mid‐infrared range. However, to date, most of the reviews on b‐P are centered around electronic and optoelectronic devices, with few specifically addressing infrared detection. Herein, the recent research progress on b‐P infrared detectors is summarized in this review. This article introduces the principle of optoelectronic detection, the main properties of 2D b‐P, the development history of b‐P fabrication methods, presents and discusses the performance and characteristics of various infrared photodetectors based on different structures of 2D b‐P that have been researched in recent years. Finally, the challenges that may be faced by black phosphorus‐based infrared photoelectric detectors are briefly introduced, and the potential application directions are discussed from the perspective of large‐scale production and practical application. This article provides an in‐depth analysis and evaluation of the future development prospects of 2D b‐P materials as a potential excellent candidate of infrared photodetectors. [ABSTRACT FROM AUTHOR]

Published

2024

10. Infrared Photodetectors: Recent Advances and Challenges Toward Innovation for Image Sensing Applications.

Author

Saleem, Muhammad Imran, Kyaw, Aung Ko Ko, and Hur, Jaehyun

Subjects

*INFRARED detectors, *SEMICONDUCTOR nanocrystals, *SPECTRAL sensitivity, *BIOLOGICAL monitoring, *DIGITAL cameras, *QUANTUM dots

Abstract

High‐resolution infrared (IR) imaging technology holds substantial significance across diverse fields including biomedical imaging, environmental surveillance, and IR digital cameras. Current IR detectors used in commercial applications are based on ultra‐high vacuum‐processed traditional inorganic semiconductors like silicon or III‐V compounds (e.g., Si, Ge, and InGaAs). However, the rapid advancements in applications such as autonomous vehicles, virtual reality, and point‐of‐care healthcare are driving an escalating need for innovative imaging technologies. This review aims to bridge the gap by exploring solution‐processed semiconductor photodetectors (PDs), which offer distinct advantages including cost‐effectiveness, tunable spectral response, and potential for multiple‐exciton generation. These characteristics make them particularly suitable for optical communication, IR imaging, and biological monitoring applications. This review provides comprehensive insights into the research trends pertaining to solution‐processed IR detectors and imagers based on colloidal quantum dots, perovskites, organic compounds, and 2D materials. The review commences with the current market worth of image sensors, the fundamental principles of single‐pixel and multipixel array IR imagers, and key parameters used to assess IR detector performance. In essence, the review concludes with a summary of recent advancements and future prospects for next‐generation IR PD devices and their potential application as an IR imager. [ABSTRACT FROM AUTHOR]

Published

2024

11. Tilted Wire Metamaterials Enabling Ultra-Broadband Absorption from Middle to Very Long Infrared Regimes.

Author

Wang, Pan, Xiao, Chengyu, Chen, Shaowen, Zhang, Mengqi, Sun, Ya, Wang, Haoyu, Zhang, Jin, and Zhou, Han

Subjects

ELECTROMAGNETIC coupling, INFRARED detectors, INFRARED absorption, ENERGY harvesting, INFRARED spectra

Abstract

Infrared metamaterial absorbers underpin many entrenched scientific and technical applications, including radiative cooling, energy harvesting, infrared detectors, and microbolometers. However, achieving both perfect and ultra-broadband absorption remains an unmet scientific challenge because the traditional metamaterial absorber strategy suffers from complex multi-sized resonators and multiple meta-element patterns. We demonstrate a simple ultra-broadband infrared metamaterial absorber consisting of tilted graphite wires and an Al reflector. The proposed tilted wires-based metamaterial (TWM) absorber exhibits absorption of above 0.95 across the middle to very long-wavelength infrared spectrum (3–30 µm). By increasing the aspect ratio, the bandwidth can be expanded and achieve near-perfect absorption in the 3–50 μm spectral range. The excellent infrared absorptance performance primarily originates from the ohmic loss induced by the electromagnetic coupling between neighboring tilted wires. Furthermore, we propose a typical three-layer equivalent model featuring a resonator/insulator/reflector configuration that requires more than 84 resonant cavities to obtain comparable infrared absorptance. Our high-performance TWM absorber could accelerate the development of next-generation infrared thermal emitters and devices and other technologies that require infrared absorption. [ABSTRACT FROM AUTHOR]

Published

2024

12. Development of a Compact NDIR CO 2 Gas Sensor for a Portable Gas Analyzer.

Author

Xu, Maosen, Tian, Wei, Lin, Yuzhe, Xu, Yan, and Tao, Jifang

Subjects

OPTICAL detectors, GAS detectors, AIR quality monitoring, LIGHT filters, OPTICAL mirrors, CARBON dioxide detectors, INFRARED detectors

Abstract

A carbon dioxide (CO2) gas sensor based on non-dispersive infrared (NDIR) technology has been developed and is suitable for use in portable devices for high-precision CO2 detection. The NDIR gas sensor comprises a MEMS infrared emitter, a MEMS thermopile detector with an integrated optical filter, and a compact gas cell with high optical coupling efficiency. A dual-ellipsoid mirror optical system was designed, and based on optical simulation analysis, the structure of the dual-ellipsoid reflective gas chamber was designed and optimized, achieving a coupling efficiency of up to 54%. Optical and thermal simulations were conducted to design the sensor structure, considering thermal management and light analysis. By optimizing the gas cell structure and conditioning circuit, we effectively reduced the sensor's baseline noise, enhancing the overall reliability and stability of the system. The sensor's dimensions were 20 mm × 10 mm × 4 mm (L × W × H), only 15% of the size of traditional NDIR gas sensors with equivalent detection resolution. The developed sensor offers high sensitivity and low noise, with a sensitivity of 15 μV/ppm, a detection limit of 90 ppm, and a resolution of 30 ppm. The total power consumption of the whole sensor system is 6.5 mW, with a maximum power consumption of only 90 mW. [ABSTRACT FROM AUTHOR]

Published

2024

13. Erprobung einer miniaturisierten Infrarotspektroskopie zur Messung von Alterungseffekten in Öl.

Author

Uebel, Julian, Stiemcke, Yvo, Huber, Maximilian E., Rheinländer, Carl, Thielen, Stefan, Koch, Oliver, Wehn, Norbert, and Seewig, Jörg

Subjects

INFRARED detectors, ENERGY futures, SOOT, PETROLEUM, DETECTORS, LUBRICATING oils

Abstract

Copyright of Technisches Messen is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

14. The Tobin Coefficient: A Relevant Photodetector Performance Metric for IR Imaging.

Author

Gravrand, Olivier, Kerlain, Alexandre, Sam-Giao, Diane, Soria, Maxence, and Rothman, Johan

Subjects

PINK noise, INFRARED detectors, IMAGE converters, PHOTODIODES, DIODES

Abstract

The well-known Rule07 is a simple thus efficient way to compare available technologies for IR imaging detectors in terms of dark current. The noise is then often estimated using a shot noise approximation on the dark current. Both II–VI and III–V communities use this rule of thumb as a reference for well-performing IR photodiodes. For HOT applications, a dark current close to this rule07 is considered a necessary condition but not a sufficient one to obtain a high-performance IR imager. Indeed, when limited by shot noise, rule07 describes well the noise behavior of the considered device. However, when considering low-frequency noise, it fails to describe the expected performances. In this paper, we focus on another figure-of-merit, dedicated to detector low-frequency noise rather than dark current. Systemic 1/f noise investigation in an IR detector was first reported by Tobin et al. in 1980. There is today a relative consensus on the fact that measured 1/f noise is proportional to the dark current. The ratio between the amplitude of the 1/f noise and the dark current of the same devices may therefore be used as a figure-of-merit for a given technology. This ratio (called the Tobin factor α T ) therefore appears adequate to compare different technologies as a figure-of-merit qualifying 1/f noise properties. This dimensionless ratio can also be very useful for optimizing a particular technology or process. However, in order to be relevant, this figure-of-merit must be estimated carefully as it appears, for instance, pixel pitch-dependent. Different examples of Tobin coefficient extraction are presented in this paper. We show that, depending on the technologies, the values of the Tobin coefficient can spread over several orders of magnitude. However, only low values result in high-quality IR imagers. Today, the best results we obtained show that α T = 10 - 5 is a state-of-art value to be compared with. [ABSTRACT FROM AUTHOR]

Published

2024

15. Temperature Dependence of the Defect States in LWIR (100) and (111)B HgCdTe Epilayers for IR HOT Detectors.

Author

Murawski, Krzysztof, Majkowycz, K., Sobieski, J., Kopytko, M., and Martyniuk, P.

Subjects

CHEMICAL vapor deposition, ACTION spectrum, INFRARED detectors, DENSITY of states, BAND gaps

Abstract

HgCdTe epilayers grown by chemical vapor deposition (MOCVD) on GaAs substrates operating in the long-wave infrared range were characterized by the photoluminescence (PL) method. Photodiode and photoconductor designs, both (100) and (111)B crystallographic, were analyzed. Spectral current responsivity (RI) and a PL signal approximated by a theoretical expression being the product of the density of states and the Fermi–Dirac distribution were used to determine the fundamental transition (energy gap, Eg). For all the samples, an additional deep-level-related transition associated with mercury vacancies (VHg) were observed. The energy distance of about 80 meV above the valence band edge was observed for all the samples. Moreover, measurements at low temperature showed shallow acceptor-level (AsTe and VHg as acceptors) transitions. In HgCdTe(100), due to the higher arsenic activation, AsTe was the dominant acceptor dopant, while, in HgCdTe(111)B, the main acceptor level was formed by the neutral VHg. The determined activation energies for AsTe and VHg dopants were of about 5 meV and 10 meV, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

16. Pyro‐Phototronic Effect Induced Circularly Polarized Light Detection with a Broadband Response.

Author

Guan, Qianwen, Zhu, Zeng‐Kui, Ye, Huang, Zhang, Chengshu, Li, Hang, Ji, Chengmin, Liu, Xitao, and Luo, Junhua

Subjects

*PEROVSKITE, *INDUCTIVE effect, *SPINTRONICS, *OPTOELECTRONICS, *DETECTORS, *INFRARED detectors

Abstract

Photopyroelectric‐based circularly polarized light (CPL) detection, coupling the pyro‐phototronic effect and chiroptical phenomena, has provided a promising platform for high‐performance CPL detectors. However, as a novel detection strategy, photopyroelectric‐based CPL detection is currently restricted by the short‐wave optical response, underscoring the urgent need to extend its response range. Herein, visible‐to‐near‐infrared CPL detection induced by the pyro‐phototronic effect is first realized in chiral‐polar perovskites. Specifically, chiral‐polar multilayered perovskites (S‐BPEA)2FAPb2I7 (1‐S, S‐BPEA = (S)‐1‐4‐Bromophenylethylammonium, FA = formamidinium) with spontaneous polarization shows intrinsic pyroelectric and photopyroelectric performance. Strikingly, combining its merits of the pyro‐phototronic effect and intrinsic wide‐spectrum spin‐selective effect, chiral multilayered 1‐S presents efficient photopyroelectric‐based broadband CPL detection performance spanning 405–785 nm. This research first realizes photopyroelectric‐based infrared CPL detection and also sheds light on developing high‐performance broadband CPL detectors based on the pyro‐phototronic effect in the fields of optics, optoelectronics, and spintronics. [ABSTRACT FROM AUTHOR]

Published

2024

17. Room‐Temperature Band‐Aligned Infrared Heterostructures for Integrable Sensing and Communication.

Author

Xiao, Kening, Zhang, Shi, Zhang, Kaixuan, Zhang, Libo, Wen, Yuanfeng, Tian, Shijian, Xiao, Yunlong, Shi, Chaofan, Hou, Shicong, Liu, Changlong, Han, Li, He, Jiale, Tang, Weiwei, Li, Guanhai, Wang, Lin, and Chen, Xiaoshuang

Subjects

*INFRARED detectors, *TOPOLOGICAL insulators, *REMOTE sensing, *OPTICAL communications, *CHARGE carrier mobility, *INFRARED absorption

Abstract

The demand for miniaturized and integrated multifunctional devices drives the progression of high‐performance infrared photodetectors for diverse applications, including remote sensing, air defense, and communications, among others. Nonetheless, infrared photodetectors that rely solely on single low‐dimensional materials often face challenges due to the limited absorption cross‐section and suboptimal carrier mobility, which can impair sensitivity and prolong response times. Here, through experimental validation is demonstrated, precise control over energy band alignment in a type‐II van der Waals heterojunction, comprising vertically stacked 2D Ta2NiSe5 and the topological insulator Bi2Se3, where the configuration enables polarization‐sensitive, wide‐spectral‐range photodetection. Experimental evaluations at room temperature reveal that the device exhibits a self‐powered responsivity of 0.48 A·W−1, a specific directivity of 3.8 × 1011 cm·Hz1/2·W−1, a response time of 151 µs, and a polarization ratio of 2.83. The stable and rapid photoresponse of the device underpins the utility in infrared‐coded communication and dual‐channel imaging, showing the substantial potential of the detector. These findings articulate a systematic approach to developing miniaturized, multifunctional room‐temperature infrared detectors with superior performance metrics and enhanced capabilities for multi‐information acquisition. [ABSTRACT FROM AUTHOR]

Published

2024

18. Achieving Ultra‐High Background‐Limited Detectivity by a Brillouin Zone Folding Induced Quasi‐Bound State in the Continuum.

Author

Zhu, Tianyun, Jing, Wenji, Deng, Jie, Wang, Bo, Wang, Ruowen, Ye, Tao, Shi, Mengdie, Ye, Jiexian, Cui, Tianyuan, Shen, Jinyong, Li, Fangzhe, Ning, Jun, Zhou, Jing, and Chen, Xiaoshuang

Subjects

*BRILLOUIN zones, *BACKGROUND radiation, *HEAT radiation & absorption, *PHOTODETECTORS, *DOPING agents (Chemistry), *INFRARED detectors

Abstract

During infrared detection, the thermal radiation from the background generates substantial photon noise and thus severely limit the capability of an infrared detector to identify a target. Going beyond this limitation has been a long‐standing challenge in the development of infrared detectors. This paper proposes to break this limitation by creating a narrow photoresponse band with a high peak responsivity to reject the background radiation and enhance the responsivity to the target with characteristic emission lines. This scheme is numerically demonstrated in a dimerized grating integrated quantum well infrared photodetector, based on critical coupling with a Brillouin zone folding induced quasi‐bound state in the continuum (BIC). The asymmetric deformation of the grating structure folds the photonic band and generates a quasi‐BIC with a tunable high radiation Q factor (QR) at the Γ point. By reducing the doping concentration of the quantum wells for a high absorption Q factor (QA) and tuning the QR to make QR = QA for critical coupling, a narrowband photoresponse with a high peak responsivity is achieved and the background‐limited specific detectivity of 4.55 × 1012 cm Hz1/2 W−1 is obtained for a 2π field of view, surpassing the ideal‐photoconductor limit by 92 times. [ABSTRACT FROM AUTHOR]

Published

2024

19. Blocking layer of dark current for Si-based short-wave infrared photodetection.

Author

Yu, Liang, Wu, Li, Dai, Xiyuan, Yang, Yanru, Yan, Zhongyao, Liu, Kaixin, Ma, Fengyang, Lu, Ming, and Sun, Jian

Subjects

*CONDUCTION bands, *ELECTRON transport, *DETECTORS, *ZINC oxide, *WAVELENGTHS, *PHOTODETECTORS, *INFRARED detectors

Abstract

Effective suppression of dark current is essential for improving the performance of bulk defect-mediated absorption (BDA) photodetectors. Blocked impurity band (BIB) infrared detectors have been developed and utilized from mid-infrared to far-infrared wavelength regions for low noise. In this work, a blocking layer of dark current was applied to a BDA short-wave infrared (SWIR) photodetector, emulating the concept of BIB detectors. ZnO was chosen as the blocking layer to impede the transport of electrons from the bulk defect levels due to its wide bandgap and to allow the photocurrent to remain nearly unaffected by proper positioning of the conduction band minimum. After introducing the ZnO blocking layer, the dark current density of the photodetector was reduced by two orders of magnitude, and the specific detectivity was enhanced by one order of magnitude. The effects of TiO2 and WO3 as blocking layers were also investigated and compared with ZnO. This work offers an effective method for enhancing detectivity in SWIR BDA photodetection by suppressing the dark current efficiently. [ABSTRACT FROM AUTHOR]

Published

2024

20. Blackbody‐Sensitive Uncooled Infrared Detector with Ultra‐Broadband and Ultrafast Photoresponse Based on Te/WTe2 Heterostructure.

Author

Yu, Yu, Dai, Zhiyuan, Guan, Haibiao, Wang, Ruowen, Ye, Tao, Bu, Yonghao, Deng, Jie, Shi, Mengdie, Sun, Liaoxin, Xin, Rui, Li, Tianxin, Shu, Haibo, Chen, Xiaoshuang, and Zhou, Jing

Subjects

*INFRARED detectors, *PHOTODETECTORS, *CONDUCTION bands, *VALENCE bands

Abstract

Blackbody‐sensitive uncooled infrared photodetectors with ultra‐broadband and ultrafast photoresponse have a profound impact on many areas of modern science and technology. However, it is a big challenge for both traditional photodetectors and emerging low‐dimensional ones to simultaneously have all the above characteristics. Here, this challenge is addressed by establishing a Te/WTe2 heterostructure photodetector. The built‐in field of the heterostructure and the crossing conduction and valence bands of WTe2 jointly result in a high responsivity and a visible‐to‐long‐wavelength‐infrared photoresponse range. The peak responsivity (at the 3.3 µm wavelength) reaches 914 mA W−1 at zero bias and 8.51 A W−1 at 2 V bias. Further, the joint action coupled with the high mobility of Te and WTe2 promotes the 3‐dB bandwidth to 153 kHz. The self‐powered blackbody responsivity and specific detectivity reach 235.7 mA W−1 and 1.1 × 108 cm Hz1/2 W−1, respectively. The former increases to 5.82 A W−1 at 1 V bias. Moreover, this device is polarization‐sensitive with a contrast ratio of 2. This work reveals the potential of the Te/WTe2 heterostructure for high‐performance room‐temperature infrared photodetectors. [ABSTRACT FROM AUTHOR]

Published

2024

21. Rapid photothermal assay for ultrasensitive point-of-care detection of tumor markers based on a filter membrane.

Author

Liu, Shendong, Chen, Xinlian, Zhao, Hong, Lin, Tianran, Hou, Li, and Zhao, Shulin

Subjects

*CARCINOEMBRYONIC antigen, *MEMBRANE filters, *INFRARED detectors, *POINT-of-care testing, *TEMPERATURE detectors

Abstract

An ultrasensitive photothermal assay was designed for point-of-care testing (POCT) of tumor markers based on a filter membrane. Firstly, Cu2-xSe was successfully encapsulated in liposome spheres with biotin on the surface and connected to carcinoembryonic antigen (CEA) aptamer with 3'end modified biotin by streptavidin. Secondly, the CEA antibody was successfully modified on the surface of the nitrocellulose membrane through simple incubation. Finally, the assay process was completed using a disposable syringe, and the temperature was recorded using a handheld infrared temperature detector. In the range 0–50 ng mL−1, the temperature change of the nitrocellulose membrane has a strong linear relationship with CEA concentration, and the detection limit is 0.097 ng mL−1. It is worth noting that the entire testing process can be easily performed in 10 min, much shorter than traditional clinical methods. In addition, this method was successfully applied to the quantitative determination of CEA levels in human serum samples with a recovery of 96.2–103.3%. This rapid assay can be performed by "one suction and one push" through a disposable syringe, which is simple to operate, and the excellent sensitivity reveals the great potential of the proposed strategy in the POCT of tumor biomarkers. [ABSTRACT FROM AUTHOR]

Published

2024

22. Graphene–Liquid Crystal Synergy: Advancing Sensor Technologies across Multiple Domains.

Author

Adeshina, Mohammad A., Ogunleye, Abdulazeez M., Lee, Hakseon, Mareddi, Bharathkumar, Kim, Hyunmin, and Park, Jonghoo

Subjects

*LIQUID crystals, *POLLUTANTS, *INFRARED detectors, *ENVIRONMENTAL monitoring, *THERMAL properties

Abstract

This review explores the integration of graphene and liquid crystals to advance sensor technologies across multiple domains, with a focus on recent developments in thermal and infrared sensing, flexible actuators, chemical and biological detection, and environmental monitoring systems. The synergy between graphene's exceptional electrical, optical, and thermal properties and the dynamic behavior of liquid crystals leads to sensors with significantly enhanced sensitivity, selectivity, and versatility. Notable contributions of this review include highlighting key advancements such as graphene-doped liquid crystal IR detectors, shape-memory polymers for flexible actuators, and composite hydrogels for environmental pollutant detection. Additionally, this review addresses ongoing challenges in scalability and integration, providing insights into current research efforts aimed at overcoming these obstacles. The potential for multi-modal sensing, self-powered devices, and AI integration is discussed, suggesting a transformative impact of these composite sensors on various sectors, including health, environmental monitoring, and technology. This review demonstrates how the fusion of graphene and liquid crystals is pushing the boundaries of sensor technology, offering more sensitive, adaptable, and innovative solutions to global challenges. [ABSTRACT FROM AUTHOR]

Published

2024

23. Optical Characterization of the Interband Cascade LWIR Detectors with Type-II InAs/InAsSb Superlattice Absorber.

Author

Murawski, Krzysztof, Majkowycz, Kinga, Kopytko, Małgorzata, Manyk, Tetiana, Dąbrowski, Karol, Seredyński, Bartłomiej, Kubiszyn, Łukasz, and Martyniuk, Piotr

Subjects

*ENERGY levels (Quantum mechanics), *INFRARED detectors, *MOLECULAR beam epitaxy, *SPECTRAL sensitivity, *BAND gaps

Abstract

The long-wave infrared (LWIR) interband cascade detector with type-II superlattices (T2SLs) and a gallium-free ("Ga-free") InAs/InAsSb (x = 0.39) absorber was characterized by photoluminescence (PL) and spectral response (SR) methods. Heterostructures were grown by molecular beam epitaxy (MBE) on a GaAs substrate (001) orientation. The crystallographic quality was confirmed by high-resolution X-Ray diffraction (HRXRD). Two independent methods, combined with theoretical calculations, were able to determine the transitions between the superlattice minibands. Moreover, transitions from the trap states were determined. Studies of the PL intensity as a function of the excitation laser power allowed the identification of optical transitions. The determined effective energy gap (Eg) of the tested absorber layer was 116 meV at 300 K. The transition from the first light hole miniband to the first electron miniband was red-shifted by 76 meV. The detected defects' energy states were constant versus temperature. Their values were 85 meV and 112 meV, respectively. Moreover, two additional transitions from acceptor levels in cryogenic temperature were determined by being shifted from blue to Eg by 6 meV and 16 meV, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

24. Performance analysis of four-stage thermoelectric cooler for focal plane infrared detectors.

Author

Sun, Yuetong, Zhou, Lin, Meng, Fankai, and Wang, Zhipeng

Subjects

*INFRARED detectors, *THERMOELECTRIC generators, *FOCAL planes, *LEAK detectors, *HEAT pipes, *PARETO optimum, *HEAT transfer

Abstract

• Combining multistage thermoelectric cooler with infrared detectors for analysis. • Finite rate heat transfer irreversibility is considered and a finite time thermodynamic model of a heat-pipe-type four-stage thermoelectric cooler is developed. • New evaluation indexes are proposed: module utilization coefficient and coordination performance coefficient. • Heat pipe is used to enhance heat transfer and improve the performance of the thermoelectric cooler. • Large temperature difference cooling to meet the requirements of detectors is achieved. A cooler provides a low-temperature working environment for refrigerated infrared detection chips and is an indispensable component in infrared detectors that ensures their smooth operation. In this paper, a thermodynamic model of a heat-pipe-type four-stage thermoelectric cooler with a large temperature difference applied to a focal plane infrared detector is constructed. The heat leakage of the detector is calculated using the model. The performance indexes of the coordination performance coefficient and module utilization coefficient are used to unify the cooling capacity and economic performance of the device. The impression of the working current, heat pipe parameters, and cross-sectional area of the thermoelectric leg on the performance of cooler are analyzed. A Pareto optimal solution is obtained using an NSGA-II algorithm and TOPSIS decision. A low cooling temperature is obtained using a multistage thermoelectric cooler to achieve a large cooling temperature difference. When the working current is 5.65 A and the cross-sectional area is 4.5 mm2, the maximum cooling temperature difference reaches 110.6 °C, and the lowest cooling temperature reaches -83.6 °C. When the working temperature of the detector is -60 °C, the current and cross-sectional area corresponding to the optimal solution of cooling capacity-COP-power consumption are 1.51 A and 2.74 mm2, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

25. Analysis of CdTe detectors via alpha and gamma spectrometry.

Author

Kotorová, Soňa, Šagátová, Andrea, and Zaťko, Bohumír

Subjects

*METAL-semiconductor-metal structures, *SEMICONDUCTOR materials, *OHMIC contacts, *INFRARED detectors, *GAMMA rays, *ALPHA rays

Abstract

Cadmium telluride (CdTe) plays a pivotal role in both renewable energy (solar cells) and radiation detection (infrared and X-ray/gamma-ray detectors). This semiconductor has a bandgap energy of approximately 1.5 eV, allowing devices based on it to operate at room temperature. Its high density and available large thickness of high-quality crystals facilitates exceptional gamma ray and X-ray absorption among other semiconductor materials. In this paper, CdTe detectors with metal-semiconductor-metal structure were investigated. The structure featured an In/Ti Schottky contact on one substrate side and an ohmic Pt contact on the opposite side. Spectra of alpha particles generated with 238Pu 239Pu 244Cm triple source and 241Am gamma spectra were measured under various reverse bias voltages applied on detector. Analyzing gamma and alpha spectra, we extracted valuable information about the quality of investigated CdTe detectors. Charge collection efficiency was evaluated and compared for alpha particle detection. [ABSTRACT FROM AUTHOR]

Published

2024

26. Quantum state-resolved methane scattering from Ni(111) and NiO(111) by bolometer infrared laser tagging: The effect of surface oxidation.

Author

Reilly, Christopher S., Floß, Patrick, Chen, Bo-Jung, Auerbach, Daniel J., and Beck, Rainer D.

Subjects

*BOLOMETERS, *MOLECULAR rotation, *MID-infrared lasers, *INFRARED lasers, *TUNABLE lasers, *INFRARED detectors, *INELASTIC scattering

Abstract

We describe a novel ultrahigh vacuum state-to-state molecule/surface scattering apparatus with quantum state preparation of the incident molecular beam and angle-resolved quantum state detection of the scattered molecules. State-resolved detection is accomplished using a tunable mid-infrared laser source combined with a cryogenic bolometer detector and is applicable to any molecule with an infrared-active vibrational transition. Results on rotationally inelastic scattering of CH4 methane from a Ni(111) surface and NiO(111)/Ni(111) oxide film, obtained by the new apparatus, are presented. Molecules scattering from the oxidized surface, compared to those scattering from the bare nickel surface, are more highly excited rotationally and scatter into a broader distribution of angles. The internal alignment of molecular rotation is in addition found to be stronger in molecules scattering from the bare surface. Furthermore, the maxima of the state-resolved angular distributions shift toward and away from surface normal with increasing rotational quantum number J for the oxidized and bare surface, respectively. Finally, the rotational state populations produced in scattering from the oxidized surface are well-described by a Boltzmann distribution, while those produced in scattering from the bare surface exhibit large deviations from their best-fit Boltzmann distributions. These results point toward a marked enhancement in molecule–surface collisional energy exchange induced by oxidation of the nickel surface. [ABSTRACT FROM AUTHOR]

Published

2023

27. Theoretical design and simulation of uncooled PbSe/Ge mid-wavelength infrared avalanche photodetector.

Author

Liu, Yun, Su, Leisheng, Fu, Yu, Luo, Yingmin, Yang, Yiming, and Qiu, Jijun

Subjects

*BREAKDOWN voltage, *QUANTUM efficiency, *ELECTRIC fields, *STRUCTURAL design, *PHOTODETECTORS, *INFRARED detectors

Abstract

To comply with SWaP3 specifications in infrared detectors, a novel uncooled mid-wavelength infrared avalanche photodetector (MWIR-APD) architecture based on PbSe/Ge heterojunction was proposed. A maximum high gain of 40.8 was achieved, which is comparable with cooled MWIR-APDs, including HgCdTe, and type II superlattices. The theoretical simulation shows that it is the significant difference in permittivity between PbSe and Ge that results in a sufficient electric field contrast between the absorption and multiplication layers, which facilitates the structural design of this APD. Additionally, a structural parameter limit was established by investigating the variation in the punch-through and breakdown voltages. Furthermore, the decreasing PbSe thickness will improve the device's gain but at the expense of decreasing frequency response and quantum efficiency. This PbSe/Ge APD architecture provides a new solution for the MWIR detection at room temperature. [ABSTRACT FROM AUTHOR]

Published

2025

28. Role of growth temperature on microstructural and electronic properties of rapid thermally grown MoTe2 thin film for infrared detection.

Author

Gartia, Anurag, Pradhan, Diana, Sahoo, Kiran K, Biswal, Sameer R, Sabat, Somesh, and Kar, Jyoti P

Subjects

*SILICON films, *INFRARED detectors, *SUBSTRATES (Materials science), *THIN films, *ROOT-mean-squares

Abstract

In the field of electronic and optoelectronic applications, two-dimensional materials are found to be promising candidates for futuristic devices. For the detection of infrared (IR) light, MoTe2 possesses an appropriate bandgap for which p-MoTe2/n-Si heterojunctions are well suited for photodetectors. In this study, a rapid thermal technique is used to grow MoTe2 thin films on silicon (Si) substrates. Molybdenum (Mo) thin films are deposited using a sputtering system on the Si substrate and tellurium (Te) film is deposited on the Mo film by a thermal evaporation technique. The substrates with Mo/Te thin films are kept in a face-to-face manner inside the rapid thermal-processing furnace. The growth is carried out at a base pressure of 2 torr with a flow of 160 sccm of argon gas at different temperatures ranging from 400 °C to 700 °C. The x-ray diffraction peaks appear around 2 θ = 12.8°, 25.5°, 39.2°, and 53.2° corresponding to (002), (004), (006), and (008) orientation of a hexagonal 2H-MoTe2 structure. The characteristic Raman peaks of MoTe2, observed at ∼119 cm−1 and ∼172 cm−1, correspond to the in-plane E1g and out-of-plane A1g modes of MoTe2, whereas the prominent peaks of the in-plane E12g mode at ∼234 cm−1 and the out-of-plane B12g mode at ∼289 cm−1 are also observed. Root mean square (RMS) roughness is found to increase with increasing growth temperature. The bandgap of MoTe2 is calculated using a Tauc plot and is found to be 0.90 eV. Electrical characterizations are carried out using current–voltage and current–time measurement, where the maximum responsivity and detectivity are found to be 127.37 mA W−1 and 85.21 × 107 Jones for a growth temperature of 600 °C and an IR wavelength illumination of 1060 nm. [ABSTRACT FROM AUTHOR]

Published

2024

29. High-speed mid-wave infrared holey photodetectors.

Author

Wang, Yinan, Nordin, Leland, Dev, Sukrith, Allen, Monica, Allen, Jeffery, and Wasserman, Daniel

Subjects

*PHOTODETECTORS, *INFRARED detectors, *SURFACE recombination, *COPLANAR waveguides, *DETECTORS

Abstract

We demonstrate high-speed mid-wave infrared photoconductive detectors leveraging a lattice-mismatched, epitaxially grown InSb absorber material patterned with nanometer-scale hole arrays. We show that the nano-scale hole patterns allow for post-growth control over the detector response time by introducing recombination surfaces to increase non-radiative recombination. The photoconductive pixels are integrated into a microwave coplanar waveguide for high frequency characterization. The detector response is characterized as a function of temperature and hole-array dimensions. We show a detector response with characteristic time scales of tens of picoseconds and bandwidths up to 7 GHz at room temperature. The presented detectors offer a mechanism for engineering response times in long wavelength detectors for potential applications in high-speed sensing/imaging, free-space communication, ranging, or dual-comb spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2023

30. Capacitance–voltage modeling of mid-wavelength infrared nBn detectors.

Author

Carrasco, Rigo A., Newell, Alexander T., Alsaad, Zinah M., Logan, Julie V., Duran, Joshua M., Ariyawansa, Gamini, Pinkie, Benjamin, Morath, Christian P., and Webster, Preston T.

Subjects

*INFRARED detectors, *SCHOTTKY barrier diodes, *SEMICONDUCTOR doping, *SEMICONDUCTOR junctions, *FINITE element method, *ELECTRIC capacity, *QUANTUM cascade lasers

Abstract

Capacitance–voltage measurements are a powerful technique to determine doping profiles of semiconductor pn junctions and Schottky barrier diodes. The measurements were recently extended to III-V-based mid-wavelength nBn infrared detectors, and absorber doping densities have been extracted using the widely accepted Schottky approximation, where the potential drop across the device is assumed to be across the depleting absorber layer. However, this approach is limited to when the absorber region of the nBn is under high reverse bias and thus is only able to extract the absorber region doping profile. Here, we introduce a semi-analytical model that is capable of extracting barrier dopant polarity, doping concentration, and thickness, as well as contact and absorber layer doping concentrations, all from a capacitance–voltage measurement. Rather than solely considering the potential drop across the depleting layers, it considers the potential drop across the accumulating layer as well. This negative charge accumulation occurs for the contact and absorber layers in the case of reverse and forward biases, respectively. This allows for a single model to be applied to a capacitance–voltage curve at forward and reverse biases and it can provide regions of bias where the absorber transitions from depletion to accumulation. We compare the agreement of the semianalytical model with modeling results from commercially available finite element method software and experimental capacitance–voltage data. Finally, we show that the method is consistent with the Schottky approximation of extracting absorber doping densities at high reverse bias and discuss the model's limitations. [ABSTRACT FROM AUTHOR]

Published

2023

31. Simultaneously achieving superior pyroelectric performance and ultrahigh depolarization temperature in NaNbO3-based ceramics.

Author

Lv, Zhongqian, Guo, Shaobo, Liu, Zhen, Yao, Chunhua, and Wang, Genshui

Subjects

*LEAD-free ceramics, *INFRARED detectors, *PHASE transitions, *CERAMIC materials, *INDUSTRIAL electronics

Abstract

Pyroelectric materials have been widely studied because of their important role in infrared detectors, sensors, thermal imaging, and other applications, among which, lead-based ceramics are extensively adopted. However, the environmental problems caused by lead-based compounds in production and processing are becoming increasingly serious. Meanwhile, the surface mounting technology is extensively employed in the electronics industry for device miniaturization and integration. However, due to its high processing temperature (∼260 °C), it makes most pyroelectric ceramic materials unsuitable for this process. Therefore, it is of great significance to develop novel high-performance lead-free pyroelectric ceramics with high depolarization temperature (>260 °C). In this work, we report the Na0.995Ag0.005NbO3-0.1%Mn (NANM) pyroelectric ceramics. The antiferroelectric–ferroelectric phase transition field and coercive field of NaNbO3 ceramics were reduced by the introduction of AgNbO3 and Mn, making it easier to induce the ferroelectric phase and realize poling in NANM ceramics. The NANM ceramics exhibited an excellent pyroelectric coefficient of 2.55 × 10−4 C m−2 K−1 and figures of merit as Fi = 0.93 × 10−10 m/V, Fv = 6.46 × 10−2 m2/C, and Fd = 2.92 × 10−5 Pa−1/2 at room temperature. More importantly, a high depolarization temperature of 280 °C was achieved, ensuring the ability to withstand high temperature during production and operation. The NANM ceramics with excellent pyroelectric properties and high depolarization temperature are expected to be a promising lead-free candidate for uncooled infrared detector applications. [ABSTRACT FROM AUTHOR]

Published

2024

32. Multi-dimensional optical information acquisition based on a misaligned unipolar barrier photodetector.

Author

Zhang, Shukui, Jiao, Hanxue, Chen, Yan, Yin, Ruotong, Huang, Xinning, Zhao, Qianru, Tan, Chong, Huang, Shenyang, Yan, Hugen, Lin, Tie, Shen, Hong, Ge, Jun, Meng, Xiangjian, Hu, Weida, Dai, Ning, Wang, Xudong, Chu, Junhao, and Wang, Jianlu

Subjects

INFRARED detectors, OPTICAL polarization, BREWSTER'S angle, PHOTODETECTORS, LIGHT intensity

Abstract

Acquiring multi-dimensional optical information, such as intensity, spectrum, polarization, and phase, can significantly enhance the performance of photodetectors. Incorporating these dimensions allows for improved image contrast, enhanced recognition capabilities, reduced interference, and better adaptation to complex environments. However, the challenge lies in obtaining these dimensions on a single photodetector. Here we propose a misaligned unipolar barrier photodetector based on van der Waals heterojunction to address this issue. This structure enables spectral detection by switching between two absorbing layers with different cut-off wavelengths for dual-band detection. For polarization detection, anisotropic semiconductors like black phosphorus and black arsenic phosphorus inherently possess polarization-detection capabilities without additional complex elements. By manipulating the crystal direction of these materials during heterojunction fabrication, the device becomes sensitive to incident light at different polarization angles. This research showcases the potential of the misaligned unipolar barrier photodetector in capturing multi-dimensional optical information, paving the way for next-generation photodetectors. Multi-dimensional detection of optical information with a single device enables energy- and area-efficient sensing capabilities. Here, the authors report dual-band infrared detectors based on misaligned 2D black phosphorus and black arsenic phosphorus, sensitive to light intensity, spectrum and polarization. [ABSTRACT FROM AUTHOR]

Published

2024

33. Laser-Induced Interference to Infrared Detector Using Continuous Wave and Short-Pulse Lasers.

Author

Ma, Yingjie, Zhou, Weijing, Chang, Hao, and Jian, Zhilong

Subjects

*INFRARED detectors, *INFRARED lasers, *LASER pulses, *FREQUENCY discriminators, *POWER density

Abstract

The response of a DPbS3200 infrared detector irradiated by a nanosecond pulsed laser and CW laser has been investigated to study laser-induced interference. A laser interference experiment system was constructed to measure the time-varying response signal. A nanosecond pulsed laser and a CW laser of 10 Hz were used, with a 1064 nm wavelength and a millimeter-scale irradiation spot diameter. Firstly, the characteristics of transient interference signals induced by pulsed lasers were analyzed. Then, the characteristics of response signal interference by both CW laser and pulsed laser irradiation were further investigated. The results showed that the pulsed laser only produced transient interference. However, the CW laser led to a significant amplitude reduction of the response signal, which could continuously interfere in the operating time. For transient interferences, the amplitude of the interference signal increased linearly with the laser fluence. The relation between the pulse repetition rate of the incident laser and the operating frequency of the detector determined the numbers of transient interference signals in one response period; for the interference induced by both the CW laser and pulsed laser, CW laser interference played a leading role when CW laser power density increased to 4.1 W/cm2 or more. As the CW laser fluence reached 6.1 W/cm2, the PbS infrared detector was no longer able to detect any signal, which caused temporary blindness. In the end, a probit model was used to determine the interference threshold. [ABSTRACT FROM AUTHOR]

Published

2024

34. Extraordinary Optical Transmission Spectrum Property Analysis of Long-Wavelength Infrared Micro-Nano-Cross-Linked Metamaterial Structure.

Author

Sun, Peng, Cai, Hongxing, Ren, Yu, Zhou, Jianwei, Li, Dongliang, and Li, Teng

Subjects

*LIGHT transmission, *SPECTRUM analysis, *OPTICAL spectra, *POLARITONS, *METAMATERIALS, *INFRARED detectors, *REDSHIFT

Abstract

Filter elements based on metamaterial structure are one of the essential schemes for researching the miniaturization of spectral detection systems. The aim of this study is to meet the application requirements of different long-wave infrared signal frequency filtering and improve the detection efficiency of micro-filters. In this paper, a periodic micro-nano-cross-linked hole structure is designed, based on the surface plasmonic polariton resonance effect to realize the extraordinary optical transmission performance of 8 ~ 12 μm long-wave infrared. Based on the surface plasmonic polariton excitation mechanism of periodic micro-nano-structures, the tunable performance of the transmission spectra at five central wavelengths of 8, 9, 10, 11, and 12 μm was achieved by changing the simulation period and the overall period of the model, and the optimal peak transmittance was 88.31% with a half-wave width of 1.31 ± 0.01 μm. The present study summarizes the tuning mode and rule of the micro-nano-cross-linked structure to realize the blue/redshift under the performance of the extraordinary optical transmission, which provides an important reference for the miniaturized structure design of infrared spectral detectors and tunable filtering research and is conducive to the application of broadband filtering spectral chips. [ABSTRACT FROM AUTHOR]

Published

2024

35. Van der Waals mid-wavelength infrared detector linear array for room temperature passive imaging.

Author

Tengfei Xu, Fang Zhong, Peng Wang, Zhen Wang, Xun Ge, Jinjin Wang, Hailu Wang, Kun Zhang, Zhenhan Zhang, Tiange Zhao, Yiye Yu, Min Luo, Yang Wang, Ruiqi Jiang, Fang Wang, Fansheng Chen, Qi Liu, and Weida Hu

Subjects

*INFRARED array detectors, *FAST Fourier transforms, *INFRARED detectors, *MOLYBDENUM sulfides, *PHOTODETECTORS, *INFRARED imaging, *THEMATIC mapper satellite

Abstract

Passive imaging for mid-wave infrared (MWIR) is resistant to atmospheric pollutants, guaranteeing image clarity and accuracy. Arrayed photodetectors can simultaneously perform radiation sensing to improve efficiency. Room temperature van der Waals (vdWs) photodetectors without lattice matching have evolved rapidly with optimized stacking methods, primarily for single-pixel devices. The urgent need to implement arrayed devices aligns with practical demands. Here, we present an 8 by 1 black phosphorus/molybdenum sulfide (BP/MoS2) vdWs photodetector linear array with a fill-factor of ~77%, fabricated using a temperature-assisted sloping transfer method. The flat interface and uniform thickness facilitate carrier transport and minimize pixel nonuniformities, showing an average peak detectivity (D*) of 2.34 × 109 cm·Hz1/2·W-1 in the mid-wave infrared region. Compared to a single pixel, push-broom scanning passive imaging is eight times more efficient and further enhanced through mean filtering and fast Fourier transform filtering for strip noise correction. Our study offers guidance on vdWs arrayed devices for engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

36. Investigation of the optoelectronic properties of InAsNBi/InAs quantum confined heterostructure in the presence of hydrostatic pressure for long wavelength infrared sensing.

Author

Jain, Neelesh, Mal, Indranil, Tarek, Hidouri, and Samajdar, Dip Prakash

Subjects

*HYDROSTATIC pressure, *INFRARED detectors, *BAND gaps, *OPTOELECTRONIC devices, *OPTICAL spectra, *ELASTIC constants

Abstract

This article investigates the effect of hydrostatic pressure on the optoelectronic characteristics of the InAsNBi/InAs quantum well (QW) system using an expanded version of the standard 8-band k dot p Hamiltonian. The effect of hydrostatic pressure on important structural and electronic parameters such as elastic constants, band gap, band offset, band structure, and effective masses are investigated in this manuscript. These factors assisted in the computation of optical gain spectra for different quantum well structures. Furthermore, this study is extended to several heterostructures by including diverse barrier materials such as GaAs, GaSb, and InP with InAsNBi QW. The optical analysis of these heterostructures can help the researchers to design and fabricate optoelectronic devices that can operate in LWIR regimes owing to the narrow bandgap of quaternary InAsNBi. Additionally, we examined the optical characteristics in TE mode for variations in hydrostatic pressure. [ABSTRACT FROM AUTHOR]

Published

2024

37. Crystal Growth of Triglycine Sulfate Crystals Under 40-GHz Irradiation and the Infrared Detection of their Device Characteristics.

Author

Iwasaki, Kazuma, Fujii, Sho, Kimura, Tsuyoshi, Yamamoto, Masaya, and Tanabe, Tadao

Subjects

TRIGLYCINE sulfate, CRYSTAL growth, INFRARED equipment, INFRARED detectors, CRYSTALS

Abstract

Triglycine sulfate (TGS) crystals are pyroelectric crystals that exhibit ferroelectricity in a room-temperature environment. They have application as infrared detector elements. In this study, it was found that irradiation with 40-GHz electromagnetic waves accelerates the growth of TGS crystals, with a growth rate about 2.2 times faster than that without irradiation. This leads to a reduction in process time and therefore crystals that will be used as elements in the production of detectors can be obtained more quickly. The TGS crystals were irradiated with a CO2 laser at a wavelength of 10.6 μm. The maximum voltage value obtained was about 0.24 V, the photosensitivity was 24.7 V/W, and the noise equivalent power (NEP) was 2.7 × 10−8 W/Hz½. In addition, it was confirmed that the sensitivity increased with decreasing area of the crystal. These results show that TGS crystals grown under electromagnetic irradiation can be used as infrared detector elements. [ABSTRACT FROM AUTHOR]

Published

2024

38. Application of a Modified First-Order Plate Theory to Structural Analysis of Sensitive Elements in a Pyroelectric Detector.

Author

Lian, Mengmeng, Fan, Cuiying, Zhan, Xiaohan, Zhao, Minghao, Qin, Guoshuai, and Lu, Chunsheng

Subjects

PIEZOELECTRICITY, ELECTRIC potential, PYROELECTRIC detectors, INFRARED detectors, FINITE element method

Abstract

Pyroelectric materials, with piezoelectricity and pyroelectricity, have been widely used in infrared thermal detectors. In this paper, a modified first-order plate theory is extended to analyze a pyroelectric sensitive element structure. The displacement, temperature, and electric potential expand along the thickness direction. The governing equation of the pyroelectric plate is built up. The potential distributions with upper and lower electrodes are obtained under different supported boundary conditions. The corresponding numerical results of electric potential are consistent with those obtained by the three-dimensional finite element method. Meanwhile, the theoretical results of electric potential are close to that of experiments. The influence of supported boundary conditions, piezoelectric effect, and plate thickness are analyzed. Numerical results show that the piezoelectric effect reduces the electric potential. The thickness of the pyroelectric plate enhances the electric potential but reduces the response speed of the detector. It is anticipated that the pyroelectric plate theory can provide a theoretical approach for the structural design of pyroelectric sensitive elements. [ABSTRACT FROM AUTHOR]

Published

2024

39. Wafer Level Vacuum Packaging of MEMS-Based Uncooled Infrared Sensors.

Author

Demirhan Aydin, Gulsah, Akar, Orhan Sevket, and Akin, Tayfun

Subjects

WAFER level packaging, ANTIREFLECTIVE coatings, INFRARED detectors, SILICON wafers, SEMICONDUCTOR wafer bonding

Abstract

This paper introduces a cost-effective, high-performance approach to achieving wafer level vacuum packaging (WLVP) for MEMS-based uncooled infrared sensors. Reliable and hermetic packages for MEMS devices are achieved using a cap wafer that is formed using two silicon wafers, where one wafer has precise grating/moth-eye structures on both sides of a double-sided polished wafer for improved transmission of over 80% in the long-wave infrared (LWIR) wavelength region without the need for an AR coating, while the other wafer is used to form a cavity. The two wafers are bonded using Au-In transient liquid phase (TLP) bonding at low temperature to form the cap wafer, which is then bondelectrical and Electronics d to the sensor wafer using glass frit bonding at high temperature to activate the getter inside the cavity region. The bond quality is assessed using three methods, including He-leak tests, cap deflection, and Pirani vacuum gauges. Hermeticity is confirmed through He-leak tests according to MIL-STD 883, yielding values as low as 0.1 × 10−9 atm·cc/s. The average shear strength is measured as 23.38 MPa. The package pressure varies from 133–533 Pa without the getter usage to as low as 0.13 Pa with the getter usage. [ABSTRACT FROM AUTHOR]

Published

2024

40. Assessing the Potential and Limitations of PbS and HgTe Colloidal Quantum Dot Infrared Detectors for Free Space Optical Communication.

Author

Zhao, Xue, Yao, Haifeng, Qiu, Yanyan, Yan, Naiquan, Hao, Qun, and Chen, Menglu

Subjects

*FREE-space optical technology, *SEMICONDUCTOR nanocrystals, *INFRARED detectors, *TELECOMMUNICATION, *QUANTUM communication, *OPTICAL communications

Abstract

Free space optical communication with infrared light is a promising secure wireless optical communication technology, where infrared photodetectors are the core component. To date, such applications are based on epitaxial growth narrow‐band semiconductors facing the challenge of large‐area fabrication. Infrared colloidal quantum dots (CQDs) are of interest because of the high‐throughput solution processing. Here, large‐area CQD photodetectors with adjustable wavelengths covering 1.3–2.0 µm. For 1 × 1 mm2 CQD photodetector, the response time achieved within 1 µs at room temperature, responded sharply to the 25 kbps PRBS‐7 communication code is demonstrated. For 1.5 × 1.5 cm2 large‐area CQD photodetectors, a communication rate of 2 kbps is achieved. This work is a step toward the CQD application in the field of optical communications. [ABSTRACT FROM AUTHOR]

Published

2024

41. High‐Speed Short Infrared Detector Based on Vertical Gr/Se0.2Te0.8/GaAs Heterojunction.

Author

Yang, Chong, Yu, He, Lian, Yunlu, Liu, Yiming, Wu, Maoyi, Yang, Xiutao, Han, Jiayue, Dong, Xiang, Gou, Jun, Zheng, Xing, Wu, Zhiming, Jiang, Yadong, and Wang, Jun

Subjects

*INFRARED detectors, *PHOTODETECTORS, *HETEROJUNCTIONS, *TELECOMMUNICATION, *INFRARED imaging, *CHARGE carrier mobility, *OPTICAL constants

Abstract

In the domain of high‐performance short‐wave infrared (SWIR) photodetection and imaging, existing technologies predominantly utilize single‐crystal germanium and III‐V semiconductors. Despite their efficacy, these materials are encumbered by laborious synthesis and complex fabrication demands. In this study, the synthesis of large‐area, high‐crystallinity Se0.2Te0.8 thin films through a CMOS‐compatible vacuum thermal evaporation process is reported. A high‐speed, broad‐spectrum photodetector engineered with an innovative Gr/Se0.2Te0.8/GaAs vertical heterostructure is presented, which capitalizes on the augmented carrier mobility and employs graphene innovatively as both a carrier collection interface and an electrode. This configuration facilitates a remarkably swift response time of 800 ns/1 µs at the crucial 1310 nm wavelength for optical communications. Moreover, the fabrication of a 5 × 5 array device demonstrates substantial SWIR imaging capabilities at ambient conditions, marking a paradigm shift in uncooled infrared imaging and communication technologies. This work not only extends the boundaries of SWIR photodetector performance but also underscores the potential of novel material systems in high‐speed optical applications. [ABSTRACT FROM AUTHOR]

Published

2024

42. Infrared Image Super-Resolution Network Utilizing the Enhanced Transformer and U-Net.

Author

Huang, Feng, Li, Yunxiang, Ye, Xiaojing, and Wu, Jing

Subjects

*INFRARED imaging, *HIGH resolution imaging, *TRANSFORMER models, *IMAGE reconstruction, *REMOTE sensing, *INFRARED detectors

Abstract

Infrared images hold significant value in applications such as remote sensing and fire safety. However, infrared detectors often face the problem of high hardware costs, which limits their widespread use. Advancements in deep learning have spurred innovative approaches to image super-resolution (SR), but comparatively few efforts have been dedicated to the exploration of infrared images. To address this, we design the Residual Swin Transformer and Average Pooling Block (RSTAB) and propose the SwinAIR, which can effectively extract and fuse the diverse frequency features in infrared images and achieve superior SR reconstruction performance. By further integrating SwinAIR with U-Net, we propose the SwinAIR-GAN for real infrared image SR reconstruction. SwinAIR-GAN extends the degradation space to better simulate the degradation process of real infrared images. Additionally, it incorporates spectral normalization, dropout, and artifact discrimination loss to reduce the potential image artifacts. Qualitative and quantitative evaluations on various datasets confirm the effectiveness of our proposed method in reconstructing realistic textures and details of infrared images. [ABSTRACT FROM AUTHOR]

Published

2024

43. Manipulating the metal–insulator transitions and thermoelectric bi-functionality for correlated vanadium dioxide pellets.

Author

Zhou, Xuanchi, Jiao, Yongjie, and Li, Haifan

Subjects

*THERMOELECTRIC power, *METAL-insulator transitions, *TRANSITION metals, *VANADIUM dioxide, *TEMPERATURE coefficient of electric resistance, *THERMOELECTRIC materials, *INFRARED detectors, *VANADIUM, *ELECTRON configuration

Abstract

The electron correlations as triggered by on-site Coulomb repulsion within correlated vanadium dioxide (VO2) open up an emerging paradigm to explore new electronic phases and promising device applications. Apart from correlated electrical transport, the thermoelectric thermopower (S) of VO2 also undergoes abrupt variation across the critical temperature (TMIT) that sheds lights on the potential thermoelectric functionality. Nevertheless, bridging bi-functionality of VO2 associated with the thermistor and thermoelectric properties is still restricted by the limitation in improving the absolute magnitude of S and temperature coefficient of resistance (TCR). Herein, we demonstrate the widely adjustable metal–insulator transition (MIT) behavior and overlooked thermoelectric performance for Ti-substituted VO2 pellets that enable the bi-functionality strategy as combined with thermistor and thermoelectric properties. As-achieved tunable TMIT while maintaining large |TCR| is herein achieved for Ti-substituted VO2 pellets that enables practical device applications near room temperature. Apart from the well-known MIT functionality, we reveal the overlooked thermoelectric properties for VO2 via coherently co-sintering with TiO2 that introduces a new freedom (thermopower). Specifically, the largely enhanced thermopower observed for insulating V1−xTixO2 exceeds the one for pristine VO2 by five times, while the thermoelectric power factor for its metallic phase is comparable to typical organic or oxide thermoelectric materials. The presently achieved thermistor and thermoelectric bi-functionality (e.g., |S| > 100 μV/K and |TCR| > 1 K−1) for Ti-substituted VO2 pellets extends the horizons in material designs that combines such a bi-functionality to achieve both the passive and active sensing for improving the accuracy in thermal perturbations of VO2 bulk as infrared detectors near room temperature. [ABSTRACT FROM AUTHOR]

Published

2024

44. On‐Chip Room‐Temperature Operated Short‐Wavelength‐Infrared Si:S Photodetector with a Vertical Junction.

Author

Xiao, Yunlong, Deng, Ke, Zhang, Kun, Xu, Xiangbao, Li, Qing, Zhang, Tao, Guo, Jiaxiang, Lu, Hangyu, Wang, Peng, and Hu, Weida

Subjects

*PHOTODETECTORS, *INFRARED detectors, *ION implantation, *QUANTUM efficiency, *OPTICAL communications, *DETECTORS

Abstract

Silicon (Si)‐based photodetectors are cost‐effective, eco‐friendly, and compatible with on‐chip complementary metal‐oxide‐semiconductor (CMOS) technology. However, expanding their photoresponse into the short‐wavelength‐infrared region beyond 1.1 µm remains challenging because of the intrinsic bandgap of Si. In this study, an ion implantation sulfur‐doped Si‐based infrared photodetector featuring a blocked impurity band (BIB) structure is investigated. The detector achieves an extended sub‐bandgap infrared response up to 2 µm through impurity band transitions, facilitated by the artificial creation of a deep‐level impurity band within the Si bandgap. The device exhibited a competitive photodetection effect with a high responsivity of 107.3 mA W−1 and an external quantum efficiency of 10.2%. Notably, the detector yielded an enhanced response speed with a raising time of 46 µs and a decay time of 135 µs at 1310 nm under room temperature. Finally, the versatile applications of this detector is presented in a multitude of scenarios encompassing material composition identification, multi‐band imaging, and optical communication. The proposed investigation not only proposed a method for Si‐based infrared detectors but also constituted a contribution to the advancement of silicon photonics. [ABSTRACT FROM AUTHOR]

Published

2024

45. Non-volatile 2D MoS2/black phosphorus heterojunction photodiodes in the near- to mid-infrared region.

Author

Zhu, Yuyan, Wang, Yang, Pang, Xingchen, Jiang, Yongbo, Liu, Xiaoxian, Li, Qing, Wang, Zhen, Liu, Chunsen, Hu, Weida, and Zhou, Peng

Subjects

INFRARED detectors, PHOTODETECTORS, CONVOLUTIONAL neural networks, COMPUTER vision, INFRARED technology, HETEROJUNCTIONS

Abstract

Cutting-edge mid-wavelength infrared (MWIR) sensing technologies leverage infrared photodetectors, memory units, and computing units to enhance machine vision. Real-time processing and decision-making challenges emerge with the increasing number of intelligent pixels. However, current operations are limited to in-sensor computing capabilities for near-infrared technology, and high-performance MWIR detectors for multi-state switching functions are lacking. Here, we demonstrate a non-volatile MoS2/black phosphorus (BP) heterojunction MWIR photovoltaic detector featuring a semi-floating gate structure design, integrating near- to mid-infrared photodetection, memory and computing (PMC) functionalities. The PMC device exhibits the property of being able to store a stable responsivity, which varies linearly with the stored conductance state. Significantly, device weights (stable responsivity) can be programmed with power consumption as low as 1.8 fJ, and the blackbody peak responsivity can reach 1.68 A/W for the MWIR band. In the simulation of Faster Region with convolution neural network (CNN) based on the FLIR dataset, the PMC hardware responsivity weights can reach 89% mean Average Precision index of the feature extraction network software weights. This MWIR photovoltaic detector, with its versatile functionalities, holds significant promise for applications in advanced infrared object detection and recognition systems. In-sensor computing architectures can provide energy-efficient multifunctional capabilities, but their application to the mid-infrared range is challenging. Here, the authors report the realization of non-volatile MoS2/black phosphorus photovoltaic detectors, integrating near- to mid-infrared photodetection, memory and computing functionalities. [ABSTRACT FROM AUTHOR]

Published

2024

46. Thermal detector based on a suspended polyimide membrane for infrared radiation applications.

Author

Bourgault, D., Paul, G., Latargez, C., Moiroux, G., Jegouso, D., Felix, C., Guttin, C., and Garden, J.-L.

Subjects

*NEAR infrared radiation, *INFRARED detectors, *INFRARED radiation, *DETECTORS, *THIN films, *NANOFABRICATION, *INFRARED absorption

Abstract

This Letter details a pioneering study on the design and nanofabrication process of a thermoelectric infrared radiation detector using a suspended polyimide membrane. The research includes a comprehensive analysis of thermoelectric doped Bi2Te3 thin films, comparing their expected performance regarding noise and specific detectivity with other infrared detectors, particularly those in the silicon sector. Experimental results and calculations shed light on responsivity and time constants. In the absence of absorption layers, specific detectivity values for visible and near infrared radiation are measured at 9.2 × 107 and 2.9 × 107 cm Hz / W , respectively, with a time constant nearing 20 ms. Calculations show that introducing an optimized absorption layer with ε = 1 significantly improves specific detectivity, reaching 9.0 × 108 cm Hz / W. Subsequent calculations also show that further enhancement can be obtained by etching the polyimide membrane to a 1-micron thickness, resulting in an exceptional specific detectivity value of 8.4 × 109 cm Hz / W , placing it among the best in the current state-of-the-art. [ABSTRACT FROM AUTHOR]

Published

2024

47. Experimental Study on Damage Effect of Mid-Infrared Pulsed Laser on Charge Coupled Device (CCD) and HgCgTe Detectors.

Author

Liu, Yang, Zhou, Feng, Wang, Yunzhe, Zhang, Yin, Zhang, Yunfeng, Zheng, Hanyu, and Shao, Junfeng

Subjects

*MID-infrared lasers, *CHARGE coupled devices, *LASER pulses, *INFRARED detectors, *DETECTORS, *IMAGING systems, *INFRARED lasers, *PULSED lasers

Abstract

As the weak link in electro-optical imaging systems, photodetectors have always faced the threat of laser damage. In this paper, we experimentally investigated the damage mechanism of the photodetector induced by the out-of-band laser. The damage thresholds of the mid-infrared pulsed laser for Charge Coupled Device (CCD) and HgCdTe detectors were determined through damage experiments. The analysis of the damage phenomena and data for both CCD and HgCdTe detectors clearly demonstrated that out-of-band mid-infrared pulsed lasers could entirely incapacitate CCD and HgCdTe detectors. Our analysis of the damage process and data revealed that the primary mechanism of damage to CCD and HgCdTe detectors by mid-infrared pulsed lasers was primarily thermal. This study serves as a reference for further research on the mid-infrared pulsed laser damage mechanisms of CCD and HgCdTe detectors, as well as for laser protection and performance optimization in imaging systems. [ABSTRACT FROM AUTHOR]

Published

2024

48. Colloidal Quantum Dots‐Based Three‐Band Infrared Photodetector with the Bias‐Tunable Spectral Response.

Author

Zhao, Pengfei, Mu, Ge, Wen, Chong, Qi, Yawei, Lv, Hongyv, and Tang, Xin

Subjects

*SPECTRAL sensitivity, *SEMICONDUCTOR nanocrystals, *PHOTODETECTORS, *INFRARED detectors, *QUANTUM cascade lasers, *OPTICAL communications

Abstract

Multiband infrared photodetectors (PDs) have garnered considerable attention due to their potential in various fields such as biomedical applications, optical communications, and military operations. However, the lattice mismatch of mature bulk semiconductors with varying bandgaps in the same PD pixel has impeded the advancement of multiband infrared detectors. Colloidal quantum dots (CQDs), with adjustable bandgaps, wide spectral range, and easy solution processing are promising materials for the fabrication of multiband infrared detectors. Herein, HgTe CQDs are used with varying bandgaps to construct a three‐band infrared detector with short‐wave infrared of 1.7 and 2.4 μm and midwave infrared of 4 μm. The utilization of Ag2Te nanocrystals to bring in spatially stable doping is the key to achieving three‐band infrared detectors. Through adjusting bias polarity, the detectors switch between a three‐band mode and a dual‐band mode. The detector exhibits exceptional detection performance, with detectivity above 3 × 1010 Jones in three‐band mode. [ABSTRACT FROM AUTHOR]

Published

2024

49. A Tunable Blackbody Polarized Infrared Source for the B-BOP Camera.

Author

Navick, Xavier-François, Martignac, Jérôme, Poglitsch, Albrecht, Revéret, Vincent, Rodriguez, Louis, Tollet, Timothée, and Visticot, François

Subjects

*PHOTON detectors, *BOLOMETERS, *TEMPERATURE detectors, *POLARIZERS (Light), *LOW temperatures, *INFRARED detectors, *CAMERAS, *QUANTUM cascade lasers, *INFRARED cameras

Abstract

The B-BOP detector is composed of polarization sensitive bolometer arrays in the 70–350 µm spectral range with a goal sensitivity around one attoWatt/sqrt (Hz). A polarized infrared calibration set-up is required to evaluate its performances. The calibration source is based on 6-ring-shaped, concentric blackbody-like emitters that can be individually controlled. The total emitting surface is therefore tunable from 9 up to 1200 mm2. The temperature is tunable from 1 to 40 K without disturbing the dilution cryostat and the working temperature of the detector arrays. The present paper describes the source, the rotating polarizer at low temperature, the modulation means, and the complete optical tube leading polarized infrared photons for characterizing detectors down to femtowatt level. Details of the design and realization are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

50. Parallel-Plate Capacitor Titanium Nitride Kinetic Inductance Detectors for Infrared Astronomy.

Author

Perido, J., Day, P. K., Beyer, A. D., Cothard, N. F., Hailey-Dunsheath, S., Leduc, H. G., Eom, B. H., and Glenn, J.

Subjects

*TITANIUM nitride, *INFRARED detectors, *OPTICAL detectors, *ELECTRIC inductance, *CAPACITORS, *INFRARED astronomy, *SUPERCONDUCTING quantum interference devices

Abstract

The Balloon Experiment for Galactic INfrared Science (BEGINS) is a concept for a sub-orbital observatory that will operate from λ = 25 to 250 μ m to characterize dust in the vicinity of high-mass stars. The mission's sensitivity requirements will be met by utilizing arrays of 1840 lens-coupled, lumped-element kinetic inductance detectors (KIDs) operating at 300 mK. Each KID will consist of a titanium nitride (TiN) parallel strip absorbing inductive section and parallel plate capacitor deposited on a Silicon (Si) substrate. The parallel plate capacitor geometry allows for reduction of the pixel spacing. At the BEGINS focal plane, the detectors require optical NEPs from 2 × 10 - 16 to 6 × 10 - 17 W/ Hz from 25 to 250 μ m for optical loads ranging from 4 to 10 pW. We present the design, optical performance and quasiparticle lifetime measurements of a prototype BEGINS KID array at 25 μ m when coupled to Fresnel zone plate lenses. For our optical set up and the absorption efficiency of the KIDs, the electrical NEP requirement at 25 μ m is 7.6 × 10 - 17 W/ Hz for an absorbed optical power of 0.36 pW. We find that over an average of five resonators the the detectors are photon noise limited down to about 200 fW, with a limiting NEP of about 7.4 × 10 - 17 W/ Hz . Future arrays will be coupled to microlens arrays and have higher optical efficiencies. [ABSTRACT FROM AUTHOR]

Published

2024