Pages- Terahertz Imaging & Detection

Sunday, April 7, 2019

Abstract-Fast and sensitive bolometric terahertz detection at room temperature through thermomechanical transduction

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 Ya Zhang, Suguru Hosono, Naomi Nagai, Sang-Hun Song,  Kazuhiko Hirakawa

(a) Wafer structure used to fabricate the doubly clamped GaAs beam resonator. (b) Schematic illustration of the GaAs beam resonator fabricated by selective etching. (c) Microscope image of a fabricated GaAs MEMS beam resonator (100 ×30 ×1.2 μm3). The 2DEG layer and the top gates on both ends of the beam form two piezoelectric capacitors, C1 and C2. A 15-nm-thick NiCr THz absorbing layer was deposited on the beam. This metal film was also used as a heater to calibrate the thermal responsivity of the resonator. (d) The resonance spectra measured by sweeping the driving frequency at various input heating powers, Pin, from 0 μW to ∼1100 μW. The red curve is the resonance spectrum at Pin = 0. (e) Normalized frequency shift as a function of Pin.

https://aip.scitation.org/doi/abs/10.1063/1.5045256

Terahertz (THz) electromagnetic spectrum draws wide attention for nondestructive and/or biocompatible sensing. In order to be widely applicable to the THz sensing, it is of prime importance to develop THz sensors that can be operated at room temperature and have high sensitivity and fast operation speed. However, conventional room-temperature THz thermal sensors fall short of expectations in these characteristics required in various applications of THz sensing, including THz cameras. Utilizing a thermomechanical transduction scheme, we have developed an uncooled, sensitive, and fast THz bolometer by using a doubly clamped GaAs microelectromechanical system (MEMS) beam resonator as a sensitive thermistor. Owing to its ultrahigh temperature sensitivity (the noise equivalent temperature difference of ∼1 μK/√Hz), the present bolometer achieves not only high sensitivity but also an operation bandwidth of several kHz, which is more than 100 times faster than other uncooled THz thermal sensors. The obtained electrical noise equivalent power is as low as ∼90 pW/√Hz, which is close to the limit set by the thermal fluctuation noise. The MEMS bolometers are fabricated by the standard semiconductor fabrication processes and are well suited for making detector arrays for realizing THz cameras.

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