The assumption of the previous answer is wrong. By passing them through the correct medium, the velocity at which protons travel can be reduced. This follows the theory of relativity, which only sets a maximum value for light speed, not a minimum. The equations:
E=hv
[E-energy [J] | h-Planck's constant [6.6260755 x 10¯34 Joule second] | v-frequency [Hz, sec-1]]
and
λν=c
[λ-wavelength [m] | ν-frequency [Hz, sec-1] | c-speed of light (photon) [m/s]]
still hold true however. You can re-arrange the second equation such that λ=c/v . From this equation you can see that the relationship of wavelength and photon velocity are directly proportional. That is to say as the wavelength increases, so too does it's velocity - so long as the frequency of the sinusoidal wave stays constant.
inversely related
In the work function equation, the work function is the minimum energy needed to remove an electron from a material. The relationship between the work function, wavelength, and energy of a photon is that the energy of a photon is directly proportional to its frequency, which is inversely proportional to its wavelength. This means that a photon with higher energy (shorter wavelength) can provide enough energy to overcome the work function and eject an electron from the material.
The relationship between wavelength and energy per photon is inverse: shorter wavelengths correspond to higher energy photons, according to the equation E = hc/λ, where E is energy, h is Planck's constant, c is the speed of light, and λ is wavelength.
The de Broglie wavelength of a photon remains constant as its velocity increases because a photon always travels at the speed of light in a vacuum. The wavelength of light is determined by its frequency according to the equation λ = c / f.
The relationship between photon wavelength and the behavior of light in different mediums is that the wavelength of a photon affects how it interacts with the medium it is passing through. In general, shorter wavelengths of light are more likely to be absorbed or scattered by the medium, while longer wavelengths tend to pass through with less interference. This can result in phenomena such as refraction, reflection, and absorption of light in different mediums.
The energy of a photon is inversely proportional to its wavelength. This means that as the wavelength increases, the energy of the photon decreases. Conversely, as the wavelength decreases, the energy of the photon increases.
The relationship between the wavelength of a photon and its perceived color is that shorter wavelengths correspond to colors towards the blue end of the spectrum, while longer wavelengths correspond to colors towards the red end of the spectrum. This is known as the visible light spectrum, where different wavelengths of light are perceived as different colors by the human eye.
Since the energy of a photon is inversely proportional to its wavelength, for a photon with double the energy of a 580 nm photon, its wavelength would be half that of the 580 nm photon. Therefore, the wavelength of the photon with twice the energy would be 290 nm.
As the wavelength of a photon increases, its frequency decreases. This means the energy of the photon decreases as well, since photon energy is inversely proportional to its wavelength.
The relationship between photon frequency and energy is direct and proportional. As the frequency of a photon increases, its energy also increases. This relationship is described by the equation E hf, where E is the energy of the photon, h is Planck's constant, and f is the frequency of the photon.
Transition B produces light with half the wavelength of Transition A, so the wavelength is 200 nm. This is due to the inverse relationship between energy and wavelength in the electromagnetic spectrum.
To find the wavelength of the photon, you can use the formula: wavelength = (Planck's constant) / (photon energy). Substituting the values, the wavelength is approximately 1.024 x 10^-7 meters.