Resumen

El espectro electromagnético abarca por completo al universo, desde la mínima presencia de materia (y por tanto posee energía) hasta los rayos cósmicos (que son los más energéticos) pasando por varios matices como las ondas a frecuencias de kilo, mega y giga hertz utilizadas principalmente en telecomunicaciones y llegando hasta los rayos X y rayos Gamma en aplicaciones médicas (entre otras), sin embargo existe un segmento de ese espectro conocido como el segmento o “gap” de los terahertz que ha sido poco explorado (y por ende explotado) y del que las recientes investigaciones han revelado que posee enormes potenciales en aplicaciones tan diversas como la espectroscopía, astronomía, medicina, telecomunicaciones, imagenología, etc. En el presente trabajo se exponen los fundamentos de la tecnología de terahertz, así como su estado de la técnica.

Palabra(s) Clave(s): Comunicaciones a Terabit, Nanoantenas, Terahertz.

Abstract

The electromagnetic spectrum completely covers the universe, from the minimal presence of matter (and therefore has energy) to the cosmic rays (which are the most energetic) going through several nuances like the waves at frequencies of kilo, mega and giga hertz used Mainly in telecommunications and reaching up to X-rays and Gamma rays in medical applications (among others), however there is a segment of that spectrum known as the terahertz segment that has been little explored (and therefore exploited) And recent research has revealed that it has potential standards in applications as diverse as spectroscopy, astronomy, medicine, telecommunications, imaging, etc. In the present work the fundamentals of the technology of terahertz, as well as its state of the art are exposed.

Keyboards: Terabit Communications, Nanoantennas, Terahertz.

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