Convert terahertz [THz] to attohertz [aHz] Online | Free frequency-wavelength Converter

Bridging the Gap Between Microwaves and Infrared

The terahertz (THz) is a unit of frequency equal to 1 trillion hertz (10¹² Hz), or one trillion cycles per second. This frequency range lies between the microwave and infrared regions of the electromagnetic spectrum, often called the "terahertz gap" because it is challenging to generate and detect these waves efficiently.

Terahertz waves have unique properties that make them valuable for a variety of scientific, medical, and security applications. In medical imaging, terahertz radiation can penetrate clothing and other non-metallic materials without the harmful effects associated with X-rays, making it promising for non-invasive diagnostics. In security, terahertz scanners are used to detect concealed weapons and substances at airports.

In physics and material science, terahertz spectroscopy helps analyze molecular structures, chemical compositions, and semiconductor properties with high precision. The high frequency of terahertz waves also makes them useful in ultra-fast wireless communication technologies aiming to provide data transfer rates far beyond current Wi-Fi and 5G speeds.

Despite its potential, terahertz technology is still developing, with ongoing research focused on improving sources and detectors to unlock more practical and widespread applications.

Measuring Ultra-Low Frequencies

The attohertz (aHz) is an extremely small unit of frequency equal to 10⁻¹⁸ hertz, or one cycle per 10¹⁸ seconds (about 31.7 billion years). This unit is used to describe ultra-low frequency phenomena that occur on cosmic or geological timescales, far beyond everyday human experience.

Attohertz frequencies are relevant in cosmology, astrophysics, and geophysics, where they help scientists study processes that evolve over billions of years. For example, gravitational waves generated by massive cosmic events or the oscillations of the Earth’s magnetic field can be characterized by frequencies in the attohertz range. These waves have enormous wavelengths, often spanning millions or billions of kilometres.

Because the attohertz corresponds to such a long period between cycles, it is mostly used in theoretical research rather than practical applications. Understanding phenomena at this scale gives insight into the fundamental workings of the universe, including the slow evolution of cosmic structures, the expansion of space-time, and the early conditions following the Big Bang.