Both a wave with long wavelength and a wave with short wavelength can have a lot of energy, or little energy.Specifically in the case of electromagnetic waves, a short wavelength corresponds to high energy - but this is only the energy PER PHOTON. But note that each of such waves usually consists of a lot of photons.
To create the bumpiest waves, you would want a combination of high wave height, short wavelength, and short wave period. High wave height will produce bigger peaks and troughs, while a short wavelength will create more frequent crests and troughs. A short wave period will make these crests and troughs arrive more rapidly, enhancing the bumpiness of the waves.
Low amplitude
The product of (frequency) x (wavelength) is always the same number ... the speedof the wave. So the lower frequencies must have longer wavelengths.
A wave with a loud high pitch would have a high frequency and short wavelength. It would appear as a rapid series of crests and troughs close together. In terms of sound, it would be like a shrill, piercing tone.
Both a wave with long wavelength and a wave with short wavelength can have a lot of energy, or little energy.Specifically in the case of electromagnetic waves, a short wavelength corresponds to high energy - but this is only the energy PER PHOTON. But note that each of such waves usually consists of a lot of photons.
High frequency.
To create the bumpiest waves, you would want a combination of high wave height, short wavelength, and short wave period. High wave height will produce bigger peaks and troughs, while a short wavelength will create more frequent crests and troughs. A short wave period will make these crests and troughs arrive more rapidly, enhancing the bumpiness of the waves.
Low amplitude
The product of (frequency) x (wavelength) is always the same number ... the speedof the wave. So the lower frequencies must have longer wavelengths.
A wave with a loud high pitch would have a high frequency and short wavelength. It would appear as a rapid series of crests and troughs close together. In terms of sound, it would be like a shrill, piercing tone.
A wave with low frequency will have a longer wavelength. Frequency and wavelength are inversely proportional: as frequency decreases, wavelength increases.
If the wavelength of an electromagnetic wave is too long, it may not interact efficiently with objects or materials that are small compared to its wavelength. If the wavelength is too short, it may not penetrate materials or be easily absorbed by certain substances. This can affect the transmission and reception of the wave in different mediums.
Wave velocity in general = frequency x wavelength As the velocity of the wave remains constant then frequency and wavelength are inversely related So as the wavelength becomes shorter then frequency becomes larger or higher
Yes, the shorter the wavelength, the higher the energy. Gamma waves have the shortest wavelengths of all the electromagnetic radiation waves and carry the greatest energy. Radio and TV waves have the longest wavelengths and carry the least energy.
A wave with a high frequency has a short wavelength. The relationship between frequency and wavelength is inverse, meaning as frequency increases, the wavelength decreases. This relationship is described by the equation: speed of wave = frequency x wavelength.
When a wave has high frequency, the wavelength is short. This is because frequency and wavelength are inversely proportional in waves. A higher frequency means more waves pass a given point in a given time, resulting in shorter wavelengths.