357657 When a metal surface is illuminated by a monochromatic light of wave length \(\lambda\), then the stopping potential difference required is \(3\;V\). When the same surface is illuminated by the light of wavelength \(2 \lambda\), then the stopping potential required is \(V\). Then the threshold wavelength of the given metal surface will be

357658 The threshold frequency of a metal with workfunction \(6.63\,\,eV\) is:

357659 Assertion :
Stopping potential is a measure of \(KE\) of photoelectron.
Reason :
\(W=e V_{s}=\dfrac{1}{2} m v^{2}=K E\)

357660 The threshold frequency of a metal is \(f_{0}\). When the light of frequency \(2 f_{0}\) is incident on the metal plate, the maximum velocity of photoelectrons is \(v_{1}\). When the frequency of incident radiation is increased to \(5 f_{0}\), the maximum velocity of photoelectrons emitted is \(v_{2}\). The ratio of \(v_{1}\) to \(v_{2}\) is

357657 When a metal surface is illuminated by a monochromatic light of wave length \(\lambda\), then the stopping potential difference required is \(3\;V\). When the same surface is illuminated by the light of wavelength \(2 \lambda\), then the stopping potential required is \(V\). Then the threshold wavelength of the given metal surface will be

357658 The threshold frequency of a metal with workfunction \(6.63\,\,eV\) is:

357659 Assertion :
Stopping potential is a measure of \(KE\) of photoelectron.
Reason :
\(W=e V_{s}=\dfrac{1}{2} m v^{2}=K E\)

357660 The threshold frequency of a metal is \(f_{0}\). When the light of frequency \(2 f_{0}\) is incident on the metal plate, the maximum velocity of photoelectrons is \(v_{1}\). When the frequency of incident radiation is increased to \(5 f_{0}\), the maximum velocity of photoelectrons emitted is \(v_{2}\). The ratio of \(v_{1}\) to \(v_{2}\) is

357657 When a metal surface is illuminated by a monochromatic light of wave length \(\lambda\), then the stopping potential difference required is \(3\;V\). When the same surface is illuminated by the light of wavelength \(2 \lambda\), then the stopping potential required is \(V\). Then the threshold wavelength of the given metal surface will be

357658 The threshold frequency of a metal with workfunction \(6.63\,\,eV\) is:

357659 Assertion :
Stopping potential is a measure of \(KE\) of photoelectron.
Reason :
\(W=e V_{s}=\dfrac{1}{2} m v^{2}=K E\)

357660 The threshold frequency of a metal is \(f_{0}\). When the light of frequency \(2 f_{0}\) is incident on the metal plate, the maximum velocity of photoelectrons is \(v_{1}\). When the frequency of incident radiation is increased to \(5 f_{0}\), the maximum velocity of photoelectrons emitted is \(v_{2}\). The ratio of \(v_{1}\) to \(v_{2}\) is

357657 When a metal surface is illuminated by a monochromatic light of wave length \(\lambda\), then the stopping potential difference required is \(3\;V\). When the same surface is illuminated by the light of wavelength \(2 \lambda\), then the stopping potential required is \(V\). Then the threshold wavelength of the given metal surface will be

357658 The threshold frequency of a metal with workfunction \(6.63\,\,eV\) is:

357659 Assertion :
Stopping potential is a measure of \(KE\) of photoelectron.
Reason :
\(W=e V_{s}=\dfrac{1}{2} m v^{2}=K E\)

357660 The threshold frequency of a metal is \(f_{0}\). When the light of frequency \(2 f_{0}\) is incident on the metal plate, the maximum velocity of photoelectrons is \(v_{1}\). When the frequency of incident radiation is increased to \(5 f_{0}\), the maximum velocity of photoelectrons emitted is \(v_{2}\). The ratio of \(v_{1}\) to \(v_{2}\) is