A sensor is exposed for time t to a lamp of power P placed at a distance l. The sensor has an opening that is 4d in diameter. Assuming all energy of the lamp is given off as light, the number of photons entering the sensor if the wavelength of light is `lambda` is:

A sensor is exposed for 0.1 s to a 200 W lamp 10m away The sensor has an opening that is 20 mm in diameter. How many photons enter the sensor if the wavelength of light is 600nm? Assume that all the energy of the lamp is given off as light.

In a photo electric effects set-up, a point source of light of poewer 3.2xx10^(-3) W emits mono energetic photons of energy 5.0 Ev. The source is located at a distance of 0.8m from the centre of a stationary metallic sphere of work function 3.0 Ev & of radius 8.0xx10^(6) m. The efficiency of photo electric emission is one of every 10^(6) incident photons. Assume that the sphere is isolated and initially neutral, and that photo electrons are instantly swept awy after emission. (a) Calculate the number of photo electrons emitted.per second. (b) Find the ratio of the wavelength of incident light to the de-Broglie wave length of the fastest photo electrons emitted. ltbr. (c) It is observed that the photo electron emission stops ata certain time tafter the light source is switched on. Why ? (d) Evaluate the time t.

A modern 200 W sodium street lamp emits yellow light of wavelength 0.6 mum . Assuming it to be 25% efficient in converting electrical energy to light, the number of photons of tellow light it emits per second is

A point source is emitting 0.2 W of ultravio- let radiation at a wavelength of lambda = 2537 Å . This source is placed at a distance of 1.0 m from the cathode of a photoelectric cell. The cathode is made of potassium (Work function = 2.22 eV ) and has a surface area of 4 cm^(2) . (a) According to classical theory, what time of exposure to the radiation shall be required for a potassium atom to accumulate sufficient energy to eject a photoelectron. Assume that radius of each potassium atom is 2 Å and it absorbs all energy incident on it. (b) Photon flux is defined as number of light photons reaching the cathode in unit time. Calculate the photon flux. (c) Photo efficiency is defined as probability of a photon being successful in knocking out an electron from the metal surface. Calculate the saturation photocurrent in the cell assuming a photo efficiency of 0.1. (d) Find the cut – off potential difference for the cell.

A point source of light of power P_(0) is placed at a distance of 4 m from the centre of a thin hemispherical shell as shown in the figure, The shell has a radius of 3 m and it behaves like a perfect black body. If the temperature of the hemisphere is related to the power of the sourcec as T^(4)=(p_(0))/(n pi sigma) where sigma is the stefan's constant, then find the value of (n)/(10) .

A small plate of a metal (work function =1.7eV ) is placed at a distance of 2m from a monochromatic light source of wavelength 4.8xx10^(-7)m and power 1.0watt. The light falls normally on the plate. Find the number of protons striking the metal plate per square metre per second. If a constant magnetic field of strength 10^(-4)T is applied parallel to the metal surface, find the radius of the largest circular path followed by the emitted photoelectron. (use h=6.63xx10^(-34)Js , mass of electron= 9.1xx10^(-31)kg , charge of electron= 1.6xx10^(-19)C

A lamp mainly emits light of wavelength lambda . The lamp is rated at P watt and 8% of the energy is emitted as visible light. (i) How many photons of light are emitted by the lamp per second? (ii) How many photons are falling per second on a square whose length of each side is a, held perpendicular to the incident photons at a distance r from the lamp.

A sodium vapour lamp is placed at the center of a large sphere that aborbs all the light reaching it. The rate at which the lamp emits energy is 100 W, assume that the emission is entirely at a wavelength of 590 nm. At what rate are photons absorbed by the sphere?

Two separate monochromatic light beams A and B of the same intensity (energy per unit area per unit time) are falling normally on a unit area of a metallic surface. Their wavelength are lambda_(A) and lambda_(B) respectively. Assuming that all the the incident light is used in ejecting the photoelectrons, the ratio of the number of photoelectrons from beam A to that from B is