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Verified by Toppr. Photoelectric effect depends on the frequency (or wavelength) of the light not intensity of the light. So, the light which has less wavelength less than threshold will lead to emission of photoelectrons and the one above that will not.
The threshold wavelength, related to threshold frequency by the wave equation, is defined as: The longest wavelength of incident electromagnetic radiation that would remove a photoelectron from the surface of a metal. Threshold frequency and wavelength are properties of a material, and vary from metal to metal.
Threshold Wavelength (λ th) During the emission of electrons, a metal surface corresponding to the greatest wavelength to incident light is known as threshold wavelength. λ th = c/γ th. For wavelengths above this threshold, there will be no photoelectron emission. For λ = wavelength of the incident photon, then
When a metal surface is exposed to a monochromatic electromagnetic wave of sufficiently short wavelength (or equivalently, above a threshold frequency), the incident radiation is absorbed and the exposed surface emits electrons.
The threshold wavelength, related to threshold frequency by the wave equation, is defined as: The longest wavelength of incident electromagnetic radiation that would remove a photoelectron from the surface of a metal
Define the threshold wavelength in the photoelectric effect. Solution. The photoelectric effect is a phenomenon of the ejection of electrons from the surface of a metal when the light of a suitable frequency is allowed to fall on it. The electrons released are known as photoelectrons.
Sep 12, 2022 · When a metal surface is exposed to a monochromatic electromagnetic wave of sufficiently short wavelength (or equivalently, above a threshold frequency), the incident radiation is absorbed and the exposed surface emits electrons. This phenomenon is known as the photoelectric effect.
This minimum frequency is also called the threshold frequency, and the value of ν 0 depends on the metal. For frequencies greater than ν 0 , electrons would be ejected from the metal. Furthermore, the kinetic energy of the photoelectrons was proportional to the light frequency.
You can see for yourself that the threshold wavelength is 458 nm (blue light). This means that if calcium metal were used in a light meter, the meter would be insensitive to wavelengths longer than those of blue light.
Feb 20, 2022 · There is a threshold frequency below which no electrons are ejected, because the individual photon interacting with an individual electron has insufficient energy to break it away. Above the threshold energy, \(KE_e\), increases linearly with \(f\), consistent with \(KE_e = hf - BE\).
