THz Direct Detector and Heterodyne Receiver Arrays in Silicon Nanoscale Technologies

Grzyb, Janusz; Pfeiffer, Ullrich R.

doi:10.1007/s10762-015-0172-6

Cited by 42 publications

(16 citation statements)

References 51 publications

(102 reference statements)

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“…At present, the low speed of silicon transistors and the issues related to efficient THz signal escape [31] constitute an ongoing research challenge for both technology development and IC design. Over time, silicon technology has undergone a steady scaling and an improvement of device parasitics, recently achieving an f max of 500 GHz in commercially available 0.13-μm SiGe BiCMOS technology [32].…”

Section: Introductionmentioning

confidence: 99%

Terahertz Imaging and Sensing Applications With Silicon-Based Technologies

Hillger

Grzyb

Jain

et al. 2019

IEEE Trans. THz Sci. Technol.

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288

108

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Traditional terahertz (THz) equipment faces major obstacles in providing the system cost and compactness necessary for widespread deployment of THz applications. Because of this, the field of THz integrated circuit (THz IC) design in CMOS and SiGe HBT technologies has surged in the last decade. An interplay of advances in silicon process technology, design technique, and microelectronic packaging promises to narrow the gap between the requirements and the reality of system cost and performance of THz components. Furthermore, the scalability, reconfigurability, and signal processing features of silicon technology have initiated research in complex THz ICs that expand the functionality of THz systems; this has enabled new applications, methods, and algorithms. This paper reviews the progress in THz IC research and investigates several realizations of THz imaging and sensing applications with silicon-based components regarding their motivation, system performance, and challenges. THz computed tomography, broadband multicolor imaging, high-resolution FMCW radar imaging, subwavelength resolution near-field imaging, and compressed sensing are presented.

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Section: Introductionmentioning

confidence: 99%

Terahertz Imaging and Sensing Applications With Silicon-Based Technologies

Hillger

Grzyb

Jain

et al. 2019

IEEE Trans. THz Sci. Technol.

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288

108

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“…Further details on the rectification effect can be found elsewhere [10], [11]. To date, FET rectifiers reach NEPs in the range of 14 to 20 pW/ √ Hz at 720 and 590 GHz [12], [13] with narrow band designs. While this is still higher than the NEPs of Schottky diodes, the NEP of THz-tailored FETs has improved by 4 to 5 orders of magnitude within the last 10 years.…”

Section: Introductionmentioning

confidence: 99%

Broadband Terahertz Detection With Zero-Bias Field-Effect Transistors Between 100 GHz and 11.8 THz With a Noise Equivalent Power of 250 pW/$\sqrt{\text{Hz}}$ at 0.6 THz

Regensburger

Mukherjee

Schönhuber

et al. 2018

IEEE Trans. THz Sci. Technol.

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We demonstrate UV contact-lithographically fabricated III-V field effect transistors examined over a bandwidth of 100 GHz to 11.8 THz. The zero-bias device reaches a noise equivalent power as low as 250 pW/ √ Hz at 0.6 THz which then increases as f 4 at higher frequencies. The responsivity is modeled by a simple equivalent circuit, showing good agreement over the frequency range of 2 decades. The FETs have been characterized using a photomixer, a quantum cascade laser and a free electron laser, proofing the versatility and large applicability of the detection concept.

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“…pixel pitch of 50 μm, which was incorporated into THz camera shown in Fig.6(b) [34,35] . For references, CMOS THz camera shown in Fig.6(c) was developed, which contained antenna-coupled 32x32 CMOS FPA (pixel pitch: 80 μm) and covered the spectral frequency range of 0.3-1.3 THz [12,17,36] . Sub-THz camera shown in Fig.6(d) was also developed, which contained 64x64 sub-THz FPA (pixel pitch: 1.5 mm) made of GaAs high-mobility heterostructure, and covered the spectral frequency range of 0.05-0.7 THz [25] .…”

Section: Thz and Sub-thz Camerasmentioning

confidence: 99%

“…In this section, the MDP values per pixel for the MB-THz-FPAs [26,31,32,34] are compared with those of other THz detectors, such as antenna-coupled CMOS-THz-FPAs [12,13,15,16,36,44] and antenna-coupled detectors based on III-V compound semiconductor technologies [18][19][20][22][23][24] . Table 2 summarizes the parameters of these THz detectors.…”

Section: Comparison Of Performances For Different Detectorsmentioning

confidence: 99%

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Technology trend in real-time, uncooled image sensors for sub-THz and THz wave detection

Oda

2016

SPIE Proceedings

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The author summarizes development of uncooled microbolometer terahertz (THz) focal plane arrays (FPAs) and real-time cameras for sub-THz and THz wave detection. The array formats are 320x240 and 640x480, and the cameras have several functions, such as lock-in imaging, external-trigger imaging, image processing (pixel binning and frame integration), beam profiling and so on. The FPAs themselves are sensitive to sub-THz, THz and infrared radiations.Active imaging systems based on the imagers are described. One of them is a real-time transmission-type THz microscope which contains a THz camera and a quantum cascade laser (QCL). The other one is an active sub-THz imaging system, where a transmission imaging mode and a reflection imaging mode can be switched with one-touch operation. Strong THz emitters, such as far-infrared gas lasers and QCLs, are strongly coherent and often produce interference fringes in an image. A method of reducing the interference fringes (beam homogenizing) is described.Microbolometer FPAs developed by other groups, antenna-coupled CMOS FPA, array detectors based on GaAs high-mobility heterostructure and so on are also summarized, which operate in real-time and at room temperature. A fair method of evaluating performance of detectors with different sizes and at different wavelengths is explained and the performances of the detectors are compared.

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THz Direct Detector and Heterodyne Receiver Arrays in Silicon Nanoscale Technologies

Cited by 42 publications

References 51 publications

Terahertz Imaging and Sensing Applications With Silicon-Based Technologies

Terahertz Imaging and Sensing Applications With Silicon-Based Technologies

Broadband Terahertz Detection With Zero-Bias Field-Effect Transistors Between 100 GHz and 11.8 THz With a Noise Equivalent Power of 250 pW/$\sqrt{\text{Hz}}$ at 0.6 THz

Technology trend in real-time, uncooled image sensors for sub-THz and THz wave detection

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