357653 Photons with energy \(4 {eV}\) are incident on a cathode \({C}\) in a photoelectric cell. The maximum energy of emitted photoelectrons is \(2 \,{eV}\). When photons of energy \(6 \,{eV}\) are incident on \({C}\) and no photoelectrons reaches the anode \({A}\), then the stopping potential is

357654 The curve drawn between velocity and frequency of photon in vacuum will be a

357655 According to Einstein's photoelectric equation, the graph of \(K.E\). of the photoelectron emitted from the metal versus the frequency of the incident radiation gives a straight line graph, whose slope

357656 When a monochromatic source of light is at a distance of \(0.2\;m\) from a photoelectric cell, the cut-off voltage and the saturation current are respectively \(0.6\;V\) and \(18\;ma\). If the same source is placed \(0.6\;m\) away from the cell, then:

357653 Photons with energy \(4 {eV}\) are incident on a cathode \({C}\) in a photoelectric cell. The maximum energy of emitted photoelectrons is \(2 \,{eV}\). When photons of energy \(6 \,{eV}\) are incident on \({C}\) and no photoelectrons reaches the anode \({A}\), then the stopping potential is

357654 The curve drawn between velocity and frequency of photon in vacuum will be a

357655 According to Einstein's photoelectric equation, the graph of \(K.E\). of the photoelectron emitted from the metal versus the frequency of the incident radiation gives a straight line graph, whose slope

357656 When a monochromatic source of light is at a distance of \(0.2\;m\) from a photoelectric cell, the cut-off voltage and the saturation current are respectively \(0.6\;V\) and \(18\;ma\). If the same source is placed \(0.6\;m\) away from the cell, then:

357653 Photons with energy \(4 {eV}\) are incident on a cathode \({C}\) in a photoelectric cell. The maximum energy of emitted photoelectrons is \(2 \,{eV}\). When photons of energy \(6 \,{eV}\) are incident on \({C}\) and no photoelectrons reaches the anode \({A}\), then the stopping potential is

357654 The curve drawn between velocity and frequency of photon in vacuum will be a

357655 According to Einstein's photoelectric equation, the graph of \(K.E\). of the photoelectron emitted from the metal versus the frequency of the incident radiation gives a straight line graph, whose slope

357656 When a monochromatic source of light is at a distance of \(0.2\;m\) from a photoelectric cell, the cut-off voltage and the saturation current are respectively \(0.6\;V\) and \(18\;ma\). If the same source is placed \(0.6\;m\) away from the cell, then:

357653 Photons with energy \(4 {eV}\) are incident on a cathode \({C}\) in a photoelectric cell. The maximum energy of emitted photoelectrons is \(2 \,{eV}\). When photons of energy \(6 \,{eV}\) are incident on \({C}\) and no photoelectrons reaches the anode \({A}\), then the stopping potential is

357654 The curve drawn between velocity and frequency of photon in vacuum will be a

357655 According to Einstein's photoelectric equation, the graph of \(K.E\). of the photoelectron emitted from the metal versus the frequency of the incident radiation gives a straight line graph, whose slope

357656 When a monochromatic source of light is at a distance of \(0.2\;m\) from a photoelectric cell, the cut-off voltage and the saturation current are respectively \(0.6\;V\) and \(18\;ma\). If the same source is placed \(0.6\;m\) away from the cell, then: