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It becomes longer
Energy increases as the wavelength decreases.
Shorter wavelength indicates higher frequency and higher energy per photon.
With a water wave, an increase in the length of the wavelength will result in a decrease in the frequency of the wave. We could say that there is an inverse relationship between the frequency and the wavelength. As one increases, the other decreases, and as one decreases, the other increases.
No the resolution would increase as wavelength of the illuminating light decreases.
It becomes longer
Energy increases as the wavelength decreases.
The wavelength is inversely proportional to its frequency. That is, as the frequency increases, the wavelength decreases and vice versa.
Increasing the frequency of any electromagnetic wave ... or of any wave for that matter ... decreases its wavelength.
Shorter wavelength indicates higher frequency and higher energy per photon.
The wavelength gets shorter. If the propagation speed remains the same, the wavelength (L) decreases by the inverse of the frequency f. For electromagnetic waves c = fL is a constant.
In Electromagnetic radiation when the wavelength increases the energy transmitted by the wave decreases. E=hf where h is a constant and f is the frequency.
That's correct.When you multiply the frequency times the wavelength , the result isalways the same number. So when either one decreases, the other onehas to increase.
With a water wave, an increase in the length of the wavelength will result in a decrease in the frequency of the wave. We could say that there is an inverse relationship between the frequency and the wavelength. As one increases, the other decreases, and as one decreases, the other increases.
No the resolution would increase as wavelength of the illuminating light decreases.
When the wavelength of a wave increases, the frequency decreases. When the wavelength decreases, the frequency decreases. These two values are said to be inversely proportional. Here is the equation for velocity of a wave: v = f λ where v = velocity (usually 3.0 x 108 meters/second2, which is the speed of light) f = frequency (usually in Hertz or 1/seconds) λ = wavelength (usually in nm or nanometers)
The product of (wavelength) x (frequency) of any wave phenomenon is alwaysthe same number ... the speed of the wave. So if wavelength changes, thenfrequency must change by exactly the same factor in the opposite direction,in order for their product to remain constant.