Spatial Terahertz-Light Modulators for Single-Pixel Cameras

Stantchev, Rayko I.; Pickwell‐MacPherson, Emma

doi:10.5772/intechopen.96691

Cited by 4 publications

(6 citation statements)

References 94 publications

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“…This of course results in carrier diffusion limiting the THz resolution; however, it greatly reduces the system size and cost as well as improving the acquisition speed (due to higher signal to noise ratio) and can still give subwavelength resolution for low THz frequencies. The interesting part of this technology is that the carrier injection/depletion in the modulator can also be achieved by electrical biasing instead of optical pumping, 98 whereby the resolution would be limited by the photo-lithographic techniques used to manufacture the modulator. However, such electrical modulator arrays are currently in heavy development with recent work showing a 16 Â 16 graphene array with a 1 kHz switch-rate.…”

Section: Microscopy and The Near-fieldmentioning

confidence: 99%

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Terahertz (THz) biophotonics technology: Instrumentation, techniques, and biomedical applications

Chen

Lindley-Hatcher

Stantchev

et al. 2022

Chemical Physics Reviews

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Terahertz (THz) technology has experienced rapid development in the past two decades. Growing numbers of interdisciplinary applications are emerging, including materials science, physics, communications, and security as well as biomedicine. THz biophotonics involves studies applying THz photonic technology in biomedicine, which has attracted attention due to the unique features of THz waves, such as the high sensitivity to water, resonance with biomolecules, favorable spatial resolution, capacity to probe the water–biomolecule interactions, and nonionizing photon energy. Despite the great potential, THz biophotonics is still at an early stage of development. There is a lack of standards for instrumentation, measurement protocols, and data analysis, which makes it difficult to make comparisons among all the work published. In this article, we give a comprehensive review of the key findings that have underpinned research into biomedical applications of THz technology. In particular, we will focus on the advances made in general THz instrumentation and specific THz-based instruments for biomedical applications. We will also discuss the theories describing the interaction between THz light and biomedical samples. We aim to provide an overview of both basic biomedical research as well as pre-clinical and clinical applications under investigation. The paper aims to provide a clear picture of the achievements, challenges, and future perspectives of THz biophotonics.

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Section: Microscopy and The Near-fieldmentioning

confidence: 99%

“…In this imaging modality, the fundamental acquisition speed is limited by the response time of the spatial modulator, and a recent overview of spatial THz modulators for single-pixel cameras is given in Ref. 98.…”

Section: Slow Imaging Speedmentioning

confidence: 99%

Terahertz (THz) biophotonics technology: Instrumentation, techniques, and biomedical applications

Chen

Lindley-Hatcher

Stantchev

et al. 2022

Chemical Physics Reviews

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“…A metallic object placed in a paper envelope is positioned in front of the modulator. The core working principle of the camera is based on compressed sensing algorithm 13,[33][34][35] . This algorithm enables the reconstruction of the spatial information of the object (X, the vector representing the transmittance of the object) by measuring a series of structured transmission patterns generated by the modulator.…”

mentioning

confidence: 99%

Very-Large-Scale Reconfigurable Intelligent Surfaces for Dynamic Control of Terahertz and Millimetre Waves

Kocabas,

Malevich,

Ergoktas

et al. 2024

Preprint

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Unlocking the potential of terahertz (THz) and millimetre (mm) waves for next generation communications1–4 and imaging 5,6 applications requires reconfigurable intelligent surfaces (RIS) with programmable elements that can manipulate the waves in real-time7. Realization of this technology has been hindered by the lack of efficient THz electro-optical materials and THz semiconductor platform. Here, by merging graphene-based THz modulators and the thin-film transistor (TFT) technology, we demonstrate mega-scale spatial light modulator arrays with individually addressable subwavelength pixels. We demonstrate electronically programmable patterns of intensity and phase of THz light over a large area with unprecedent levels of uniformity and reproducibility. To highlight the potential of these devices, we demonstrate a single pixel mm-wave camera capable of imaging metallic objects. We anticipate that these results will provide realistic pathways to structure THz waves for applications in non-invasive THz imaging and next generation THz communications.

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“…Such cameras can achieve rapid imaging rates, have reasonable costs, and can obtain subwavelength resolution (as the modulator can be placed in the near-field of the object) 2,31,32 . Today the most common spatial THz-light modulators work by modulating the conductivity of a semiconductor via optical excitation 1,2 , although electrical control of the conductivity is expected to be the long-term solution once such technology is further optimized 33 . The angle of incidence of the THz beam onto the surface where the conductivity is being controlled greatly affects the THz modulator efficiency.…”

mentioning

confidence: 99%

“…The resolution in their approach is fundamentally limited by the photocarrier diffusion dynamics, as they photoexcite silicon with an LED to alter the conductivity. However, electrical based THz modulators, whereby an applied electric field changes the conductivity, will have their resolution set by the device manufacturing techniques as opposed to carrier diffusion dynamics as is the case with optical based modulators 33 .…”

mentioning

confidence: 99%