Because the X-ray has a shorter wavelength (kuch shorter!) the energy is much greater in an X-ray. Therefore with a bigger energy, E = hv would calculate a higher frequency for x rays. As the eregy of a wave increases, so goes the frequency. Actually, it probably should be stated the other way, but I still have answered your question
FM radio has the higher frequency which is why it sounds better. AM is a lower frequency but can travel further because the waves bounce off
Radio waves have a frequency range that typically spans from about 3 kHz (kilohertz) to 300 GHz (gigahertz). The minimum frequency of 3 kHz corresponds to the very low frequency (VLF) range, while the maximum frequency of 300 GHz falls within the extremely high frequency (EHF) range. This broad spectrum allows radio waves to be utilized for various communication technologies, including AM and FM radio, television, and wireless networks.
Fm radio waves travel at various frequencies between 87.5 MHz and 108.0 MHz
Radio waves are the lowest frequency (and therefore longest wavelength) waves in the electromagnetic spectrum.
Skip distance refers to the minimum distance at which radio waves can be reflected off the ionosphere and returned to Earth, allowing for long-distance communication. This phenomenon occurs when the frequency of the radio wave is high enough to be reflected rather than absorbed by the ionosphere. The skip distance varies based on factors such as frequency, time of day, and ionospheric conditions. It is a critical concept in understanding how HF (high frequency) radio waves propagate over long distances.
Some palindromes related to radio waves could be "able was I ere I saw elba," or "a man, a plan, a canal, Panama." These phrases can be used when referencing the transmission of high-frequency radio waves.
Radio communication typically uses electromagnetic waves in the radio frequency range, specifically in the Very High Frequency (VHF) and Ultra High Frequency (UHF) bands. These waves have wavelengths that are suitable for transmitting signals over long distances and are commonly used for broadcasting, two-way radio communication, and cellular communications.
Aside from radio transmiters set up by humans. nearly every thing emenates high frequency radio waves.
The order of waves in the electromagnetic spectrum from low frequency to high frequency is: radio waves, microwaves, infrared, visible light, ultraviolet, X-rays, and gamma rays.
High frequency waves have a short wavelength and high energy. They can travel long distances and penetrate through obstacles easily. High frequency waves are commonly used in technologies like radio communication and medical imaging.
Radio waves have a relatively low frequency compared to other types of electromagnetic waves. They typically have frequencies in the range of tens of kilohertz to hundreds of gigahertz.
Sending out a pulse of high frequency radio waves involves transmitting electromagnetic radiation at a fast rate. This can be used for applications such as communication, radar systems, and medical imaging. The high frequency allows for fast transmission and reception of data or information.
High frequency refers to events that occur frequently, such as daily or hourly, while low frequency refers to events that occur infrequently, such as monthly or yearly. In terms of waves or signals, high frequency refers to waves that oscillate rapidly (e.g. radio waves), while low frequency refers to waves that oscillate slowly (e.g. sound waves).
The layer that reflects radio waves of low frequency is the ionosphere layer known as the D-layer, which is located at an altitude of approximately 50-90 kilometers. Radio waves of low frequency, such as medium frequency (MF) and lower high frequency (HF), bounce off this layer for long-distance communication.
There are such waves at that wavelength. As a radio transmission they would be known as "short waves" , or "-VHF" (very high frequency).
Radio waves are electromagnetic waves. Electromagnetic waves include waves such as X rays, ultraviolet light, visible light, infrared rays and so on, but you probably imagine radio waves to be quite different from these waves. Of the various kinds of electromagnetic waves, radio waves have a longer wave length than infrared rays, and are defined by the Radio Law as 'electromagnetic waves with a frequency of less than 3,000 GHz (3 THz)'Ultralow frequency radio wavesbelow 3kHzradio waves3kHz~3THz infrared rays3THz~380THz visible light380THz~790THz ultraviolet light790THz~105THz X rays105THz~107THz γ raysabove 107THzNames of radio waves Frequency Wave length Principal applications VLF(Very Low Frequency) 3kHz ~ 30kHz 100km ~ 10km LF(Low Frequency) 30kHz ~ 300kHz 10km ~ 1km Vessel / Airplane beacon MF(Medium Frequency) 300kHz ~ 3MHz 1km ~ 100m AM radio, Marine radio, Amateur radio HF(High Frequency) 3MHz ~ 30MHz 100m ~ 10m Shortwave broadcasting, Marine / Air radio, Amateur radio VHF(Very High Frequency) 30MHz ~ 300MHz 10m ~ 1m TV, FM, Fire radio, Police radio, Disaster PA radio network UHF(Ultra High Frequency) 300MHz ~ 3GHz 1m ~ 10cm Low power radio, Mobile-phone, Taxi radio, Amateur radio, TV, Wireless LAN SHF(Super High Frequency) 3GHz ~ 30GHz 10cm ~ 1cm Satellite broadcasting, Radar EHF(Extremely High Frequency) 30GHz ~ 300GHz 1cm ~ 1mm Satellite broadcasting, Radio astronomy, Radar submillimeter waves 300GHz ~ 3THz 1mm ~ 0.1mm
Television signals primarily rely on electromagnetic waves within the radio frequency range, specifically UHF (Ultra High Frequency) and VHF (Very High Frequency) bands. These waves are used to transmit audio and video information to TV antennas for reception by television sets.