In an experiment on photoelectric effect , the slope of the cut - off voltage versus frequency of incident light is found to be ` 4.12 xx 10^(-15)` V s . Calculate the value of Planck's constant.

In photoelectric the slope of the straight line graph between stopping potential and frequency of incident radiation gives the ratio of Plancks constant to

Half life of a first order reaction is 2.1xx10^(12)s^(-1) . Calculate the rate constant of the reaction.

Electrons ejected from the surface oa a metal ,when light of certain frequency is incident on it ,are stoppeed fully by a retarding potenital of 3V. Photoelectric effect in this metallic surface begins at a frequency 6xx10^(14)s^(-1) .The frequency of the incident light in s^(-1) is [Planck's constant =6.4xx10^(-34) Js, charge on the electron =1.6xx10^(-19)C]

In an experiment on photoelectric emission from a metallic surface ,wavelength of incident light 2xx10^(-7) m and stopping potential is 2.5V .The threshold frequency of the metal (in Hz) approximately (Charge of electrons e=1.6xx10^(-19) C, Planck's constant , h=6.6xx10^(-34)J-s)

In the given circuit, the angular frequency of the voltage source is 70xx10^(3) rad s^(-1) . The circuit effectively behaves like,

In a photoelectric effect experiment, the kinetic energy of an emitted electron is 1.986 xx 10^(-19) J , when a radiation of frequency 1.0 xx 10^15 s^(-1) hits the metal. What is the threshold frequency of the metal (in s^(-1) )?(Planck's constant = 6.62 xx 10^(-34) Js)

To explain the nature of radiation, James Clark Maxwell in 1864 put forward .Electromagnetic wave theory.. This theory could explain the phenomena of interference and diffraction but could not explain phenomena of black body radiation and photoelectric effect. Also, after the advent of electromagnetic wave theory, Rutherford.s model of atom suffered a serious drawback. To explain the phenomena of black body radiation and photoelectric effect, Max planck in 1900 put forward Planck.s quantum theory. BAsed on this theory, Neils Bohr in 1913 put forward Bohr.s model of atom which could overcome the drawback of Rutherford.s model and also explain the line spectral elements, especially the line spectra of hydrogen and hydrogen-like particles. Kinetic energy of the electron ejected when yellow light of frequency 5.2 xx 10^(14) s^(-1) falls on the surface of potassium metal (threshold frequency = 5 xx 10^(14) s^(-1) ) is

When a certain metal was irradiated with light of frequency 40xx10^(16) s^(-1) , the photoelectrons emitted had four times kinetic energy as the kinetic energy of photoelectrons emitted when the same metal was irradiated with light of frequency 2.0 xx 10^(16) s^(-1) . the trhreshold frequency ( v_(0) ) of the metal in s^(-1) is