Let n_{r} and n_{b} be respectively the number of photons emitted by a red bulb and a blue bulb of equal power in a given time.
10^{3} W of 5000 Å light is directed on a photoelectric cell. If the current in the cell is 0.16 mA, the percentage of incident photons which produce photoelectrons, is
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If the frequency of light in a photoelectric experiment is doubled, the stopping potential will
The stopping potential for the photo electrons emitted from a metal surface of work function 1.7eV is 10.4 V. Identify the energy levels corresponding to the transitions in hydrogen atom which will result in emission of wavelength equal to that of incident radiation for the above photoelectric effect
When a photon of light collides with a metal surface, number of electrons, (if any) coming out is
A point source of light is used in photoelectric effect. If the source is removed farther from the emitting metal, the stopping potential
A point source causes photoelectric effect from a small metal plate. Which of the following curves may represent the saturation photocurrent as a function of the distance between the source and the metal?
The maximum kinetic energy of photoelectrons emitted from a surface when photons of energy 6 eV fall on it is 4eV. The stopping potential is Volts is
Radiation of two photon energies twice and five times the work function of metal are incident sucessively on the metal surface. The ratio of the maximum velocity of photoelectrons emitted is the two cases will be
Cut off potentials for a metal in photoelectric effect for light of wavelength l_{1}, l_{2} and l_{3} is found to be V_{1}, V_{2} and V_{3} volts if V_{1}, V_{2} and V_{3} are in Arithmetic Progression and l_{1}, l_{2} and l_{3} will be
Photons with energy 5eV are incident on a cathode C, on a photoelectric cell. The maximum energy of the emitted photoelectrons is 2eV. When photons of energy 6eV are incident on C, no photoelectrons will reach the anode A if the stopping potential of A relative to C is
By increasing the intensity of incident light keeping frequency (v > v_{0}) fixed on the surface of metal
In a photoelectric experiment, electrons are ejected from metals X and Y by light of intensity I and frequency f. The potential difference V required to stop the electrons is measured for various frequencies. If Y has a greater work function than X ; which one of the following graphs best illustrates the expected results ?
A image of the sun of formed by a lens of focallength of 30 cm on the metal surface of a photoelectric cell and a photoelectrci current is produced. The lens forming the image is then replaced by another of the same diameter but of focal length 15 cm. The photoelectric current in this case is
A proton and an electron are accelerated by same potential difference have deBroglie wavelength l_{p} and l_{e}.
An electron with initial kinetic energy of 100eV is acceleration through a potential difference of 50V. Now the deBroglie wavelength of electron becomes.
If h is Planck's constant is SI system, the momentum of a photon of wavelength 0.01 Å is
The angular momentum of an electron in the hydrogen atom is . Here h is Planck's constant. The kinetic energy of this electron is
Consider the following electronic energy level diagram of Hatom : Photons associated with shortest and longest wavelengths would be emitted from the atom by the transitions labelled.
If the electron in a hydrogen atom were in the energy level with n = 3, how much energy in joule would be required to ionise the atom ? (Ionisation energy of Hatom is 2.18 × 10^{18} J)
In a hydrogen atom, the electron is in nth excited state. It may come down to second excited state by emitting ten different wavelengths. What is the value of n
Difference between nth and (n + 1)th Bohr's radius of `H' atom is equal to it's (n ^{_ }1)th Bohr's radius. The value of n is
The electron in a hydrogen atom makes transition from M shell to L. The ratio of magnitudes of initial to final centripetal acceleration of the electron is
The electron in a hydrogen atom makes a transition n_{1} → n_{2} whose n_{1} and n_{2} are the principal quantum numbers of the two states. Assume the Bohr model to be valid. The frequency of orbital motion of the electron in the initial state is 1/27 of that in the final state. The possible values of n_{1} and n_{2} are
The radius of Bohr's first orbit is a_{0}. The electron in n^{th} orbit has a radius
The ionisation potential of hydrogen atom is 13.6 volt. The energy required to remove an electron from the second orbit of hydrogen is :
In a sample of hydrogen like atoms all of which are in ground state, a photon beam containing photons of various energies is passed. In absorption spectrum, five dark lines are observed. The number of bright lines in the emission spectrum will be (Assume that all transitions take place)
When a hydrogen atom, initially at rest emits, a photon resulting in transition n = 5 → n = 1, its recoil speed is about
Consider the spectral line resulting from the transition n = 2 → n = 1 in the atoms and ions given below. The shortest wavelength is produced by :
In an atom, two electrons move around the nucleus in circular orbits of radii R and 4R. The ratio of the time taken by them to complete one revolution is : (neglect electric interaction)
9 docs1272 tests

9 docs1272 tests
