Abstract
Metal oxide semiconductor (MOS) capacitance within field effect transistors are of great interest in terahertz (THz) imaging, as they permit high-sensitivity, high-resolution detection of chemical species and images using integrated circuit technology. High-frequency detection based on MOS technology has long been justified using a mechanism described by the plasma wave detection theory. The present study introduces a new interpretation of this effect based on the self-mixing process that occurs in the field effect depletion region, rather than that within the channel of the transistor. The proposed model formulates the THz modulation mechanisms of the charge in the potential barrier below the oxide based on the hydrodynamic semiconductor equations solved for the small-signal approximation. This approach explains the occurrence of the self-mixing process, the detection capability of the structure and, in particular, its frequency dependence. The dependence of the rectified voltage on the bias gate voltage, substrate doping, and frequency is derived, offering a new explanation for several previous experimental results. Harmonic balance simulations are presented and compared with the model results, fully validating the model’s implementation. Thus, the proposed model substantially improves the current understanding of THz rectification in semiconductors and provides new tools for the design of detectors.
Highlights
The low-cost detection of high-frequency electromagnetic radiation, terahertz (THz) radiation, using integrated commercial electronics represents a challenging task that is pushing significant experimental and theoretical activities
The developed model offers a comprehensive description of the vector dynamics within the field is 8 nm, and the gate voltage above the flat band is VG −VFB = 0.17 V
The model presented in this paper is strictly 1D, as it focuses on an analytical description of the self-mixing process in the depletion region under the gate
Summary
The low-cost detection of high-frequency electromagnetic radiation, terahertz (THz) radiation, using integrated commercial electronics represents a challenging task that is pushing significant experimental and theoretical activities. Novel technologies promise to achieve resolved images that may eventually be colored by the interaction with material chemical bonding. The radiation spectrum of interest covers practically the entire gap between the microwave and infrared regions. As THz radiation is nonionizing and the associated power is low, it is considered safe. THz wavelengths are able to deeply scan the material under investigation. The combination of these safety and penetration characteristics is important in different applications, such as medical imaging, security/surveillance imaging, and spectroscopic applications
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