A photon is generated when an electron falls back into a lower orbit. It got kicked there by energy that was imparted to it.
The energy of a photon depends on it's frequency
The wavelength λ of a photon can be calculated using the energy of the photon E and the speed of light c, where λ = c/E. The energy of the photon depends on the emission process that released it.
When a photon strikes an object, it can be absorbed, reflected, or transmitted through the material. The interaction of the photon with the object depends on factors such as the material's composition, surface properties, and the energy of the photon.
The energy of one photon in yellow light depends on the specific shade of yellow, as it corresponds to a range of wavelengths. Generally, for yellow light with a wavelength around 580 nanometers, the energy of one photon is approximately 2.14 electronvolts.
The energy of a photon is inversely propotional to its wavelength. The wavelength of a blue photon is less than that of a red photon. That makes the blue photon more energetic. Or how about this? The energy of a photon is directly proportional to its frequency. The frequency of a blue photon is greater than that of a red photon. That makes the blue photon more energetic. The wavelength of a photon is inversely proportional to its frequency. The the longer the wavelength, the lower the frequency. The shorter the wavelength, the higher the frequency.
The energy of a photon depends on it's frequency
The wavelength λ of a photon can be calculated using the energy of the photon E and the speed of light c, where λ = c/E. The energy of the photon depends on the emission process that released it.
It's (double the photon's energy) divided by (the speed of light squared). The photon's energy depends on its frequency, and is (frequency) times (Planck's konstant).
When a photon strikes an object, it can be absorbed, reflected, or transmitted through the material. The interaction of the photon with the object depends on factors such as the material's composition, surface properties, and the energy of the photon.
The energy of one photon in yellow light depends on the specific shade of yellow, as it corresponds to a range of wavelengths. Generally, for yellow light with a wavelength around 580 nanometers, the energy of one photon is approximately 2.14 electronvolts.
It depends on the wavelength of the photon. Energy of each photon is hc/λ, where h = Planck's constant = 6.626x1034 Js, c = speed of light = 3x108 m/s, and λ = wavelength of the photon
A packet of light energy is called a photon.
The energy of a photon is inversely propotional to its wavelength. The wavelength of a blue photon is less than that of a red photon. That makes the blue photon more energetic. Or how about this? The energy of a photon is directly proportional to its frequency. The frequency of a blue photon is greater than that of a red photon. That makes the blue photon more energetic. The wavelength of a photon is inversely proportional to its frequency. The the longer the wavelength, the lower the frequency. The shorter the wavelength, the higher the frequency.
The opposite of a photon is an antiphoton.
Photon flux can be calculated using the formula: photon flux = v * E, where v is the frequency of the photons and E is the energy of each photon. By multiplying the frequency of the photons by the energy of each photon, you can determine the photon flux.
tata photon plus is ratan tata and Javed Siddiqui is houner of PHoton whiz..............
. . . photon.