Room-temperature nine-µm-wavelength photodetectors and GHz-frequency heterodyne receivers

Room-temperature operation is essential for any optoelectronics technology that aims to provide low-cost, compact systems for widespread applications. A recent technological advance in this direction is bolometric detection for thermal imaging, which has achieved relatively high sensitivity and video rates (about 60 hertz) at room temperature. However, owing to thermally induced dark current, room-temperature operation is still a great challenge for semiconductor photodetectors targeting the wavelength band between 8 and 12 micrometres, and all relevant applications, such as imaging, environmental remote sensing and laser-based free-space communication, have been realized at low temperatures. For these devices, high sensitivity and high speed have never been compatible with high-temperature operation. Here we show that a long-wavelength (nine micrometres) infrared quantum-well photodetector fabricated from a metamaterial made of sub-wavelength metallic resonators exhibits strongly enhanced performance with respect to the state of the art up to room temperature. This occurs because the photonic collection area of each resonator is much larger than its electrical area, thus substantially reducing the dark current of the device. Furthermore, we show that our photonic architecture overcomes intrinsic limitations of the material, such as the drop of the electronic drift velocity with temperature, which constrains conventional geometries at cryogenic operation. Finally, the reduced physical area of the device and its increased responsivity allow us to take advantage of the intrinsic high-frequency response of the quantum detector at room temperature. By mixing the frequencies of two quantum-cascade lasers on the detector, which acts as a heterodyne receiver, we have measured a high-frequency signal, above four gigahertz (GHz). Therefore, these wide-band uncooled detectors could benefit technologies such as high-speed (gigabits per second) multichannel coherent data transfer and high-precision molecular spectroscopy.

[1]  James S. Harris,et al.  Intersubband absorption saturation study of narrow III - V multiple quantum wells in the spectral range , 1997 .

[2]  Carlo Sirtori,et al.  Strong near field enhancement in THz nano-antenna arrays , 2013, Scientific Reports.

[3]  C. Bethea,et al.  Quantum cascade lasers and the Kruse model in free space optical communication. , 2009, Optics express.

[4]  W. Elsässer,et al.  Intensity noise properties of quantum cascade lasers. , 2005, Optics express.

[5]  Rainer Martini,et al.  Quantum cascade laser-based free space optical communications , 2005 .

[6]  R. S. Stepleman,et al.  Optical Properties of Metal-dielectric-metal Microcavities in the Thz Frequency Range References and Links , 2022 .

[7]  Kwong-Kit Choi,et al.  New 10 μm infrared detector using intersubband absorption in resonant tunneling GaAlAs superlattices , 1987 .

[8]  J. Faist,et al.  InP-based quantum cascade detectors in the mid-infrared , 2006 .

[9]  Hui Chun Liu,et al.  Photoconductive gain mechanism of quantum‐well intersubband infrared detectors , 1992 .

[10]  D. Howarth,et al.  The theory of electronic conduction in polar semi-conductors , 1953, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[11]  Carlo Sirtori,et al.  Patch antenna terahertz photodetectors , 2015 .

[12]  Peter Capper,et al.  Infrared Detectors and Emitters: Materials and Devices , 2001 .

[13]  M. Buchanan,et al.  Room-Temperature Heterodyne Detection up to 110 GHz With a Quantum-Well Infrared Photodetector , 2006, IEEE Photonics Technology Letters.

[14]  Christian Chardonnet,et al.  Quantum cascade laser frequency stabilization at the sub-Hz level , 2015 .

[15]  C. Sirtori,et al.  Ultra-subwavelength resonators for high temperature high performance quantum detectors , 2016 .

[16]  R. A. Wood Uncooled Microbolometer Infrared Sensor Arrays , 2001 .

[17]  Olaf Lenzmann,et al.  Status and Trends , 1991 .

[18]  Harald Schneider,et al.  High-speed infrared detection by uncooled photovoltaic quantum well infrared photodetectors , 1997 .

[19]  Y. N. Chen,et al.  Antenna-coupled microcavities for enhanced infrared photo-detection , 2014 .

[20]  J.J. Shea Materials and devices for smart systems, vol. 785 [Book Review] , 2004, IEEE Electrical Insulation Magazine.

[21]  Margaret Buchanan,et al.  Near‐Room‐Temperature Mid‐Infrared Quantum Well Photodetector , 2011, Advanced materials.

[22]  N. Fox,et al.  A comparison of the performance of a photovoltaic HgCdTe detector with that of large area single pixel QWIPs for infrared radiometric applications , 2005 .

[23]  A. Rogalski Infrared detectors: status and trends , 2003 .

[24]  Jozef Piotrowski,et al.  Near room-temperature IR photo-detectors , 1991 .

[25]  Sarath D. Gunapala,et al.  Chapter 4 Quantum Well Infrared Photodetector (QWIP) Focal Plane Arrays , 1999 .

[26]  S. M. Sze,et al.  Physics of semiconductor devices , 1969 .

[27]  Jerome Faist,et al.  Dual-comb spectroscopy based on quantum-cascade-laser frequency combs , 2014, Nature Communications.

[28]  Guido Sonnabend,et al.  Compact Setup of a Tunable Heterodyne Spectrometer for Infrared Observations of Atmospheric Trace-Gases , 2013, Remote. Sens..

[29]  Boris Mizaikoff,et al.  Mid-IR fiber-optic sensors. , 2003, Analytical chemistry.

[30]  Esther Baumann,et al.  Mid-infrared quantum cascade detectors for applications in spectroscopy and pyrometry , 2010, OPTO.

[31]  Carlo Sirtori,et al.  Distributed feedback quantum cascade lasers , 1997 .