Radioactive decay does not have a specific wavelength, as it is a process where unstable atomic nuclei lose energy by emitting radiation in the form of alpha particles, beta particles, or gamma rays. Each type of radiation has different wavelengths. The wavelength of gamma rays, which are high-energy electromagnetic radiation emitted during radioactive decay, can range from picometers to nanometers.
The length of a full cycle of a wave is called a "wavelength".
If the speed and length of a wave decrease, the frequency of the wave will also decrease. This means the wave will have a lower pitch or tone.
The color red has the largest wavelength. The color violet, on the other hand, has the shortest wavelength.
Frequency is inversely proportional to the wave length, thus saying the shorter the wave length the higher the frequency and vice versa.The frequency is the number of waves within a time period. As the frequency within that time period increases, the number of waves increases, therefore the width of each wave (wavelength) within that time period has to decrease. Therefore:As the wave length increases, the frequency decreasesAs the wave length decreases, the frequency increases
As the speed and length of a wave decrease, the frequency remains the same while the wavelength decreases. This means that the wave's energy decreases as well.
The largest wave is the R
The largest wave in an electrocardiogram is typically the R wave.
no it is not the largest.
When you shorten the wave length, you increase the amplitude.
The length of a full cycle of a wave is called a "wavelength".
Ultraviolet has the longer wave length Infrared has the lower wave length
If the speed and length of a wave decrease, the frequency of the wave will also decrease. This means the wave will have a lower pitch or tone.
I don't know what's "water length" but I do know that the deeper the water are, the faster the wave goes. If you meant wave length and not water length, then the longer the wavelength, the smaller the frequency of the wave.
No....
the length of a wave generated by a complete vibration or time period
the length of a wave generated by a complete vibration or time period
I'm glad that we are finally on the same wave length.