The frequency of terahertz radiation devices falls between microwave radiation and infrared radiation. The electronic counters are not capable to measure frequency, when frequency of electromagnetic radiations converts to very high. Hence, it must be calculated with the help of proxy with the support of energy and wavelength properties. Consistently, the generation and modulation of high frequency coherent electromagnetic signals measurement is not possible with the conventional electronic devices which needs the expansion of new methods and devices by terahertz radiation technology. The terahertz radiation can be achieved through artificial and natural sources. In terahertz radiation, natural sources is discharged as a portion of the black body radiation with temperatures more than 10 kelvin. The terahertz radiation in artificial sources can be achieved over varactor multipliers, backward wave oscillator, free electron laser, organic gas far infrared laser, electronic oscillators, and synchrotron light sources created on resonant tunneling diodes.
The global terahertz (THz) radiation devices market is growing with a significant rate, due to growing popularity of techniques such as infrared (IR) and ultrasound. Terahertz radiations are used to inspect, control, monitor, the ultrasound and infrared techniques. Terahertz radiation technologies are interchanging a smaller amount of safe technologies, such as x-ray and nuclear, due to their capability of penetrating over barrier materials for executing non-contact and non-ionizing testing. Terahertz radiation technologies unwrapped the scope for many new applications in biomedical fields and telecommunications, which is further driving the development of the global terahertz radiation devices market.
Previously, the application of terahertz technology was limited to radio astronomy and laboratory applications, due to their bulky system and expensive. With the technological developments in terahertz radiation technology, it turn out to be commercialized in markets such as industrial process monitoring pharmaceuticals quality control, weapons detection, and non-destructive testing. Terahertz radiation devices can be segmented into technologies, type, application and end user. On the basis of technologies, the terahertz radiation devices market can be characterized as THz detectors, THz waveguides, lenses, THz sources, switches, THz regulators, and other devices.
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By type, the terahertz radiation devices market can be segmented as therapeutic devices, imaging systems, communication devices, sensors, computers and spectroscopes. The global terahertz radiation devices market can also be segmented on the basis of application as medical imaging, art and archaeology, astronomy, passenger screening, process or quality control, land mine and IED detection, diagnostics, compact and low-cost THz cameras, target acquisition and identification. On the basis of end users, the global terahertz radiation devices market can be segmented as security or public safety, healthcare, scientific research, manufacturing, and military or defense. Furthermore, terahertz radiation devices can be studied according to region such as North America, Europe, Asia Pacific, Middle East and Africa, and South America.
Terahertz gap creates interferences in the everyday applications of terahertz radiations. Terahertz gap refers the technologies that are essential to generate, channelize, and detect terahertz radiation visible to real-world restraints, such as cost, operating temperatures, and size. Though the recent expansions in terahertz radiation sources, waveguides, and detectors have been diminished the terahertz gap. All this is supporting for the development of the global terahertz radiation devices market in various applications, such as medical imaging, nondestructive testing, and transportation security.
Some of the competitors in the global terahertz radiation devices and systems market are Bruker Corporation, Jena-Optronik GmbH, Applied Research & Photonics Inc., Novatrans Group SA, Northrop Grumman Corporation, Menlo Systems GmbH, Del Mar Photonics Inc., LongWave Photonics LLC, Innovative Photonic Solutions, Bridge12 Technologies Inc., Digital Barriers PLC, Advantest Corporation, Lockheed Martin Corporation, and Becker Photonik GmbH.