Light described at a place by the equation `E=(100 V/m) [sin(5xx10^15 s ^(-1) )t +sin (8xx 10^15 s^(-1) )t]` falls on a metal surface having work function 2.0 eV. Calculate the maximum kinetic energy of the photoelectrons.

Light described at a palce by te equation E=(100 V/m) [sinxx10^15 s ^(-1) t +sin (8xx 10^15 s^(-1) t] falls on a metal surface having work function 2.0 eV. Calcualte the maximum kinetic energy of the photoelectrons.

Light wave described by the equation 200 V//m sin (1.5xx10^15 s^(-1) t cos (0.5xx10^15 s^(-1) t falls metal surface having work function 2.0 eV. Then, the maximum kinetic energy photoelectrons is

The electric field at a point associated with a light wave is E=100Vm^-1 sin [(3*0xx10^15 s^-1)t] sin [(6*0xx10^15s^-1)t]. If this light falls on a metal surface having a work function of 2*0 eV , what will be the maximum kinetic energy of the photoelectrons?

The electric field of certain radiation is given by the equation E = 200 {sin (4pi xx 10^10)t + sin(4pi xx 10^15)t} falls in a metal surface having work function 2.0 eV. The maximum kinetic energy (in eV) of the photoelectrons is [Plank's constant (h) = 6.63 xx 10^(-34)Js and electron charge e = 1.6 xx 10^(-19)C]

Statement-1 : Light described at a place by the equation E= E_(0) (sin omegat + sin 7 omegat) falls on a metal surface having work funcation phi_(0) . The macimum kinetic energy of the photoelectrons is KE_(max) = (7homega)/(2pi) - phi_(0) Statement-2 : Maximum kinetic energy of photoelectron depends on the maximum frequency present in the incident light according to Einstein's photoelectric effect equation.

Light of wavelength 2000Å is incident on a metal surface of work function 3.0 eV. Find the minimum and maximum kinetic energy of the photoelectrons.

The magnetic field associated with a light wave is given, at the origin, by B=B_(0)[sin(3.14xx10^(7))ct +sin(6.28xx10^(7))ct]. If this light falls on a silver plate having a work function fo 4.7 eV, what will be the maximum kinetic energy of the photo electrons? (c=3xx10^(8)ms^(-1),h=6.6xx10^(-34)J-s)

Light of wavelength 4000Å is allowed to fall on a metal surface having work function 2 eV. The maximum velocity of the emitted electrons is (h=6.6xx10^(-34)Js)

Light corresponding to the transition n = 4 to n = 2 in hydrogen atom falls on cesium metal (work function = 1.9 eV) Find the maximum kinetic energy of the photoelectrons emitted

An electromagnetic radiation whose electric component varies with time as E=E_0(1+cos omegat)cos omega_0t(omega=6xx10^(15) "rad"//s, omega_0=2.8 xx10^(14) "rad"//s) is incident on a lithium surface (work function =2.39 eV) . The maximum kinetic energy of a photoelectron liberated from the lithium surface is (h=4.14 x10^(-15) ev-s)