En electromagnetic wave is assimilable to a photon.
The energy of a photon is equal to its frequency (that determines its "color") multiplied by the Planck's constant (h).
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The energy is E=hf = hc/w where f is frequency, c is the velocity and w is the wavelength.
Frequency is inversely proportional to wavelength (higher frequency means a shorter wavelength). Frequency is directly proportional to the energy of the wave (higher frequencies correspond to higher energies).
The relationship between frequency and energy of electromagnetic radiation was first described by the theoretical physicist Max Planck. He stated that the energy (E) of a single photon is directly proportional to the frequency of its associated electromagnetic wave (v). The coefficient of this proportionality is the Planck Constant (h). The relationship between frequency and energy is thus defined:E = hvThe value of h is 6.62606957(29)×10−34 joule-seconds.Since the frequency of light, v, can be defined as v = c/λ, we can re-write the energy calculation as:E = (hc)/λNote that these definitions are only true for electromagnetic radiation; the proportionality of frequency and energy in other types of waves is also true, but the relationship is not defined by the Planck constant in such cases.
the higher the frequency, the higher the energy
Depends on the wave. In electromagnetic waves, a shorter wavelength means a higher frequency - and the energy of a photon is directly proportional to frequency.
The energy is E=hf = hc/w where f is frequency, c is the velocity and w is the wavelength.
Frequency is inversely proportional to wavelength (higher frequency means a shorter wavelength). Frequency is directly proportional to the energy of the wave (higher frequencies correspond to higher energies).
The relationship between frequency and energy of electromagnetic radiation was first described by the theoretical physicist Max Planck. He stated that the energy (E) of a single photon is directly proportional to the frequency of its associated electromagnetic wave (v). The coefficient of this proportionality is the Planck Constant (h). The relationship between frequency and energy is thus defined:E = hvThe value of h is 6.62606957(29)×10−34 joule-seconds.Since the frequency of light, v, can be defined as v = c/λ, we can re-write the energy calculation as:E = (hc)/λNote that these definitions are only true for electromagnetic radiation; the proportionality of frequency and energy in other types of waves is also true, but the relationship is not defined by the Planck constant in such cases.
the higher the frequency, the higher the energy
Depends on the wave. In electromagnetic waves, a shorter wavelength means a higher frequency - and the energy of a photon is directly proportional to frequency.
the higher the frequency the higher the energy
the higher the energy, the higher the frequency
Wavelength and frequency are inversely proportional. The higher the frequency, the shorter (lower) the wavelength. Energy is proportional to frequency, and higher frequency waves will have a higher energy. Mathematically, frequency = 1 divided by wavelength, or f = 1/λ Use the link below for more information, including a diagram or two to make things clearer.
High energy is high frequency.
the higher the frequency, the higher the energy (or visa versa).
In the case of electromagnetic wave, the energy of a photon is directly proportional to the frequency. For other types of waves, the situation may be different.
The energy in one photon of any electromagnetic radiation is directly proportionalto its frequency, so that would be inversely proportional to its wavelength.Note: There is no energy in the protons of light, since light has no protons.