A potential difference created between the two plates in the photoelectric experiment setup helps to accelerate the photoelectrons, so that all of them reach the collector plate and contribute to the current. In the absence of such an accelerating potential, will there be any photocurrent at all? (Assume the photoelectrons come out perpendicular to the emitter plate.)

Yes, but only if the intensity of light is extremely high

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Yes, but only if the frequency of light v is extremely high

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Yes, as long as $h v > ϕ$

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No, there needs to be a pull from the collector plate for current to exist, just like any battery driven circuit

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Solution

The correct option is C
Yes, as long as $h v > ϕ$

When a photon is absorbed, the electron gains an energy hν, ν being the frequency of the light. If this energy is greater than the work function $(h ν > ϕ)$ the electron may get ejected out of the metal surface.

Of course, the electron might lose energy due to collisions and not come out at all, but given that there is a very large number of free electrons available (remember that one molar mass of a metal will contain ~ $10^{23}$ electrons), there will definitely be a few electrons which will manage to not lose the gained energy and come out with some kinetic energy.

Assuming the ejected electrons come out perpendicular to the surface (or maybe, as with many experimental setups, the collector plate spherically surrounds the emitter plate), as long as the photoelectrons have some kinetic energy, they will make it to the collector plate in some time due to their speeds, and create a detectable photocurrent.

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Similar questions

A potential difference created between the two plates in the photoelectric experiment setup helps to accelerate the photoelectrons, so that all of them reach the collector plate and contribute to the current. In the absence of such an accelerating potential, will there be any photocurrent at all? (Assume the photoelectrons come out perpendicular to the emitter plate.)

Q. In an experiment on photoelectric effect, light of wavelength 400 nm is incident on a cesium plate at the rate of 5.0 W. The potential of the collector plate is made sufficiently positive with respect to the emitter, so that the current reaches its saturation value. Assuming that on average, one out of every 10⁶ photons is able to eject a photoelectron, find the photocurrent in the circuit.

Q. In an experiment on photoelectric effect, light of wavelength

400 nm

is incident on a caesium plate at the rate of

5.0 W

. The potential of the collector plate is made sufficiently positive with respect to the emitter so that the current reaches its saturation value. Assuming that on the average, one out of every

10^{6}

photons is able to eject a photoelectron, find the photocurrent in the circuit.
[Use

h c = 1240 eV (nm)

]

Q. In a photoelectric experiment, if the potential difference across the electrodes is equal to the stopping potential and the emitter plate is held at negative potential with respect to the collector plate mark the correct statement :

Q. In a photoelectric experiment, the collector plate is at 2.0 V with respect to the emitter plate made of copper (φ = 4.5 eV). The emitter is illuminated by a source of monochromatic light of wavelength 200 nm. Find the minimum and maximum kinetic energy of the photoelectrons reaching the collector.

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