Convert centihertz [cHz] to terahertz [THz] Online | Free frequency-wavelength Converter

The Unit for Slow Oscillations

The centihertz (cHz) is a unit of frequency equal to 10⁻² hertz, meaning one cycle occurs every 100 seconds, or approximately 1 minute and 40 seconds. This frequency range is useful in studying slow, periodic phenomena in fields like geophysics, astrophysics, and engineering.

In geophysics, centihertz frequencies often describe slow seismic waves and Earth’s natural resonances after earthquakes. These oscillations provide insights into the planet’s interior structure and the behavior of seismic waves as they travel through different layers. Monitoring these frequencies helps improve earthquake understanding and early-warning systems.

In astrophysics, centihertz frequencies correspond to certain pulsations in stars and compact objects like neutron stars. These slow oscillations help scientists probe the physical properties, rotation, and magnetic fields of such objects.

In engineering, centihertz vibrations may be important for studying the stability and resonance of large structures like bridges or skyscrapers, which can oscillate slowly under environmental forces like wind or traffic.

Centihertz frequencies represent a middle ground between very slow ultra-low frequencies and faster oscillations. By understanding these frequencies, researchers can better analyze processes that unfold over minutes, bridging time scales relevant to both natural phenomena and engineered systems.

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.