357687 Maximum velocity of the photoelectron emitted by a metal is \(1.8 \times {10^6}\;m{s^{ - 1}}\). Take the value of specific charge of the electron is \(1.8 \times {10^{11}}Ck{g^{ - 1}}\). Then the stopping potential in volt is

357688 In an experiment on photoelectric effect, a student plots stopping potential \({V_o}\) against reciprocal of the wavelength \(\lambda\) of the incident light of two different metals \(A\) and \(B\). These are shown in the figure.



Looking at the graphs, you can most appropriately say that:

357689 The work function for a metal is 4 \(eV\) . To eject the photo electrons with zero velocity, the wavelength of incident light should be

357690 The photoelectric threshold wavelength of silver is \(3250 \times {10^{ - 10}}\;m\). The velocity of the electron ejected from a silver surface by ultraviolet light of wavelength \(2536 \times {10^{ - 10}}\;m\) is :-
(Given \(h = 4.14 \times {10^{ - 15}}eVs\) and \(c = 3 \times {10^8}\;m{s^{ - 1}}\) )

357687 Maximum velocity of the photoelectron emitted by a metal is \(1.8 \times {10^6}\;m{s^{ - 1}}\). Take the value of specific charge of the electron is \(1.8 \times {10^{11}}Ck{g^{ - 1}}\). Then the stopping potential in volt is

357688 In an experiment on photoelectric effect, a student plots stopping potential \({V_o}\) against reciprocal of the wavelength \(\lambda\) of the incident light of two different metals \(A\) and \(B\). These are shown in the figure.



Looking at the graphs, you can most appropriately say that:

357689 The work function for a metal is 4 \(eV\) . To eject the photo electrons with zero velocity, the wavelength of incident light should be

357690 The photoelectric threshold wavelength of silver is \(3250 \times {10^{ - 10}}\;m\). The velocity of the electron ejected from a silver surface by ultraviolet light of wavelength \(2536 \times {10^{ - 10}}\;m\) is :-
(Given \(h = 4.14 \times {10^{ - 15}}eVs\) and \(c = 3 \times {10^8}\;m{s^{ - 1}}\) )

357687 Maximum velocity of the photoelectron emitted by a metal is \(1.8 \times {10^6}\;m{s^{ - 1}}\). Take the value of specific charge of the electron is \(1.8 \times {10^{11}}Ck{g^{ - 1}}\). Then the stopping potential in volt is

357688 In an experiment on photoelectric effect, a student plots stopping potential \({V_o}\) against reciprocal of the wavelength \(\lambda\) of the incident light of two different metals \(A\) and \(B\). These are shown in the figure.



Looking at the graphs, you can most appropriately say that:

357689 The work function for a metal is 4 \(eV\) . To eject the photo electrons with zero velocity, the wavelength of incident light should be

357690 The photoelectric threshold wavelength of silver is \(3250 \times {10^{ - 10}}\;m\). The velocity of the electron ejected from a silver surface by ultraviolet light of wavelength \(2536 \times {10^{ - 10}}\;m\) is :-
(Given \(h = 4.14 \times {10^{ - 15}}eVs\) and \(c = 3 \times {10^8}\;m{s^{ - 1}}\) )

357687 Maximum velocity of the photoelectron emitted by a metal is \(1.8 \times {10^6}\;m{s^{ - 1}}\). Take the value of specific charge of the electron is \(1.8 \times {10^{11}}Ck{g^{ - 1}}\). Then the stopping potential in volt is

357688 In an experiment on photoelectric effect, a student plots stopping potential \({V_o}\) against reciprocal of the wavelength \(\lambda\) of the incident light of two different metals \(A\) and \(B\). These are shown in the figure.



Looking at the graphs, you can most appropriately say that:

357689 The work function for a metal is 4 \(eV\) . To eject the photo electrons with zero velocity, the wavelength of incident light should be

357690 The photoelectric threshold wavelength of silver is \(3250 \times {10^{ - 10}}\;m\). The velocity of the electron ejected from a silver surface by ultraviolet light of wavelength \(2536 \times {10^{ - 10}}\;m\) is :-
(Given \(h = 4.14 \times {10^{ - 15}}eVs\) and \(c = 3 \times {10^8}\;m{s^{ - 1}}\) )