A dye absorbs light of `lambda` = `4530` Å and then fluorescence light of `5080` Å. Assuming that under given condition `47%` of the absorbed energy is re-emitted out as flourescence, calculate the ratio of quanta emitted out to the number of quanta absorbed.

A dye obsorbs light of lambda = 4530 Å and then flaorescences light of 5000Å .Assuming that uinder given condition 47% of the obserbed energy is re-emited out so flaurescence , calculate the ratio of quants emitted out to the number of quanta obserbed

A certain dye absorbs light of cerain wavelength and then fluorescence light of wavelength 5000 Å.Assuming that under given conditions , 50% of the absorbed energy is re-emitted out as fluorescence and the ratio of number of quanta emitted out to the number of quanta absorbed is 5:8, find the wavelength of absorbed light (in Å) : [hc=12400 eVÅ]

A certain day absorbs lights of lamda=400 nm and then fluorescence light of wavelength 500 mn. Assuming that under given condition 40% of the absorbed energy is re-emitted as fluorescence, calculate the ratio of quanta obserbed to number of quanta emitted out.

A certain dye absorbs 4000 Å and fluoresces at 8000 Å. These being wavelengths of maximum absorption that under given conditions 50 % of the absorbed energy is emitted. Calculate the ratio of the no. of quanta emitted to the number absorbed.

A light beam of wavelength 400 nm is incident on a metal of work- function 2.2 eV . A particular electron absorbs a photon and makes 2 collisions before coming out of the metal (a) Assuming that 10% of existing energy is lost to the metal in each collision find the final kinetic energy of this electron as it comes out of the metal. (b) Under the same assumptions find the maximum number of collisions, the electron should suffer before it becomes unable to come out of the metal.

A light beam of wavelength 400 nm is incident on a metal of work- function 2.2 eV. A particular electron absorbs a photon and makes 2 collisions before coming out of the metal (a) Assuming that 10% of existing energy is lost to the metal in each collision find the final kinetic energy of this electron as it comes out of the metal. (b) Under the same assumptions find the maximum number of collisions, the electron should suffer before it becomes unable to come out of the metal.

A point source of monochromatic light of 1.0 mW is placed at a distance of 5.0 m from a metal surface. Light falls perpendicularly on the surface. Assume wave theory of light to hold and also that all the light falling on the circular area with radius =1.0 xx 10^-9m (which is few times the diameter of an atom) is absorbed by a single electron on the surface. Calculate the time required by the electron to receive sufficient energy to come out of the metal if the work function of the metal is 2.0eV .

An iodine molecule dissociates into atom after absorbing light of wavelength 4500 Å. If quantum of radiation is absorbed by each molecule calculate the kinetic energy of iodine (Bond energy of I_(2) is 240 kJ mol^(-1))

An iodine molecule dissociates into atom after absorbing light of wavelength 4500 Å. If quantum of radiation is absorbed by each molecule calculate the kinetic energy of iodine (Bond energy of I_(2) is 240 kJ mol^(-1))

An iodine dissociates into atom after absorting light of wave length 4500Å If quantum of radition is absorbed by each molecule calculate the kinetic energy of iodine (Bood energy of I_(2) is 240 kJ(mol))