Ultra-monochromatic far-infrared Cherenkov diffraction radiation in a super-radiant regime

Abstract: Nowadays, intense electromagnetic (EM) radiation in the far-infrared (FIR) spectral range is an advanced tool for scientific research in biology, chemistry, and material science because many materials leave signatures in the radiation spectrum. Narrow-band spectral lines enable researchers to investigate the matter response in greater detail. The generation of highly monochromatic variable frequency FIR radiation has therefore become a broad area of research. High energy electron beams consisting of a long tra… Show more

“…Due to the great prospects for the use of THz radiation, many methods have been developed to effectively generate and detect THz radiation. For example, to generate THz radiation, it was proposed to use Smith-Purcell radiation [8], Cherenkov diffraction radiation [9], and coherent transition radiation [10].…”

Martin-Puplett interferometer for studying THz and subTHz radiation

“…Due to the great prospects for the use of THz radiation, many methods have been developed to effectively generate and detect THz radiation. For example, to generate THz radiation, it was proposed to use Smith-Purcell radiation [8], Cherenkov diffraction radiation [9], and coherent transition radiation [10].…”

Martin-Puplett interferometer for studying THz and subTHz radiation

Observation of quasi-monochromatic resonant Cherenkov diffraction radiation

Direct Generation of Radially Polarized X-Shape Terahertz Pulse via Focusing Cherenkov Radiation