357704 When a certain photosensitive surface is illuminated with monochromatic light of frequency \(v\), the stopping potential for the photo current is \(\frac{{ - {V_0}}}{2}\). When the surface is illuminated by monochromatic light of frequency \(\dfrac{v}{2}\), the stopping potential is \( - {V_0}\). The threshold frequency for photoelectric emission is

357705 Two photons of energies twice and thrice the work function of a metal are incident on the metal surface. Then the ratio of maximum velocities of the photoelectrons emitted in the two cases respectively, is

357706 On a photosensitive material, when frequency of incident radiation is increased by \(40 \%\), kinetic energy of emitted photoelectrons increases from \(0.4 \,{eV}\) to \(1.2 \,{eV}\). The work function of the material is

357707 When monochromatic light of wavelength \(\lambda\) is incident on a metallic surface, the stopping potential for photoelectric current is \(3 V_{0}\). When the same surface is illuminated with light of wavelength \(2 \lambda\), the stopping potential is \(V_{0}\)
The threshold wavelength for this surface when photoelectric effect takes place is

357704 When a certain photosensitive surface is illuminated with monochromatic light of frequency \(v\), the stopping potential for the photo current is \(\frac{{ - {V_0}}}{2}\). When the surface is illuminated by monochromatic light of frequency \(\dfrac{v}{2}\), the stopping potential is \( - {V_0}\). The threshold frequency for photoelectric emission is

357705 Two photons of energies twice and thrice the work function of a metal are incident on the metal surface. Then the ratio of maximum velocities of the photoelectrons emitted in the two cases respectively, is

357706 On a photosensitive material, when frequency of incident radiation is increased by \(40 \%\), kinetic energy of emitted photoelectrons increases from \(0.4 \,{eV}\) to \(1.2 \,{eV}\). The work function of the material is

357707 When monochromatic light of wavelength \(\lambda\) is incident on a metallic surface, the stopping potential for photoelectric current is \(3 V_{0}\). When the same surface is illuminated with light of wavelength \(2 \lambda\), the stopping potential is \(V_{0}\)
The threshold wavelength for this surface when photoelectric effect takes place is

357704 When a certain photosensitive surface is illuminated with monochromatic light of frequency \(v\), the stopping potential for the photo current is \(\frac{{ - {V_0}}}{2}\). When the surface is illuminated by monochromatic light of frequency \(\dfrac{v}{2}\), the stopping potential is \( - {V_0}\). The threshold frequency for photoelectric emission is

357705 Two photons of energies twice and thrice the work function of a metal are incident on the metal surface. Then the ratio of maximum velocities of the photoelectrons emitted in the two cases respectively, is

357706 On a photosensitive material, when frequency of incident radiation is increased by \(40 \%\), kinetic energy of emitted photoelectrons increases from \(0.4 \,{eV}\) to \(1.2 \,{eV}\). The work function of the material is

357707 When monochromatic light of wavelength \(\lambda\) is incident on a metallic surface, the stopping potential for photoelectric current is \(3 V_{0}\). When the same surface is illuminated with light of wavelength \(2 \lambda\), the stopping potential is \(V_{0}\)
The threshold wavelength for this surface when photoelectric effect takes place is

357704 When a certain photosensitive surface is illuminated with monochromatic light of frequency \(v\), the stopping potential for the photo current is \(\frac{{ - {V_0}}}{2}\). When the surface is illuminated by monochromatic light of frequency \(\dfrac{v}{2}\), the stopping potential is \( - {V_0}\). The threshold frequency for photoelectric emission is

357705 Two photons of energies twice and thrice the work function of a metal are incident on the metal surface. Then the ratio of maximum velocities of the photoelectrons emitted in the two cases respectively, is

357706 On a photosensitive material, when frequency of incident radiation is increased by \(40 \%\), kinetic energy of emitted photoelectrons increases from \(0.4 \,{eV}\) to \(1.2 \,{eV}\). The work function of the material is

357707 When monochromatic light of wavelength \(\lambda\) is incident on a metallic surface, the stopping potential for photoelectric current is \(3 V_{0}\). When the same surface is illuminated with light of wavelength \(2 \lambda\), the stopping potential is \(V_{0}\)
The threshold wavelength for this surface when photoelectric effect takes place is