Speed = frequency x wavelength.
frequency = speed of light/wavelength
matter and energy
electricity and mass
inequality
There's no relationship between the frequency and the medium. The frequency of a wave is determined by the source. Once the wave leaves the source and sets out on its journey, the frequency doesn't change, regardless of what kind of stuff the wave encounters and has to travel through.
Speed of the wave = frequency x wavelength
Speed = (wavelength) x (frequency) Wavelength = (speed)/(frequency) Frquency = (speed)/(wavelength)
Frequency is the number of wavelenghts passing though a given point in one second. Wavelength is the distance between two crest or troughs. The relationship between wavelenght and frequency is given by f = 1/wavelength. where f = frequency
wavelenght is the distance between the 2 peaks in sound waves and can be calculated by Wavelenght is = wave speed/ frequency or wave speed __________ frequency
E=hv where E is energy, v is frequency, and h is 6.626x10^-34 relates the energy of a photon to the photon's frequency.
it is a distance between repeating units of a propagating wave of a given frequency..
frequency = speed of light/wavelength
I suppose you're talking about small wavelenght or large wavelength. In this case, the answer is that a wave with lower wavelenght has more energy than a wave with higher wavelenght.You have to consider that the energy associated to an electromagnetic wave is, according to de Broglie:E = hfwhere h is the Planck constant (which is, more or less, h = 6.626·10-34 Js) and f is the frequency of the wave. The relationship between frequency and wavelenght is given byf = c/lambdawhere c is the speed of light and lambda the wavelenght. So finally you haveE = hc/lambdaAccording to this equation, the higher the wavelenght, the lower the energy.
I suppose you're talking about small wavelenght or large wavelength. In this case, the answer is that a wave with lower wavelenght has more energy than a wave with higher wavelenght.You have to consider that the energy associated to an electromagnetic wave is, according to de Broglie:E = hfwhere h is the Planck constant (which is, more or less, h = 6.626·10-34 Js) and f is the frequency of the wave. The relationship between frequency and wavelenght is given byf = c/lambdawhere c is the speed of light and lambda the wavelenght. So finally you haveE = hc/lambdaAccording to this equation, the higher the wavelenght, the lower the energy.
I suppose you're talking about small wavelenght or large wavelength. In this case, the answer is that a wave with lower wavelenght has more energy than a wave with higher wavelenght.You have to consider that the energy associated to an electromagnetic wave is, according to de Broglie:E = hfwhere h is the Planck constant (which is, more or less, h = 6.626·10-34 Js) and f is the frequency of the wave. The relationship between frequency and wavelenght is given byf = c/lambdawhere c is the speed of light and lambda the wavelenght. So finally you haveE = hc/lambdaAccording to this equation, the higher the wavelenght, the lower the energy.
Energy,E=h*c/Wavelength h is Planks const.,c is velocity of light
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