Using the graph shown in the figure for stopping potential vs. the incident frequency of photons, calculate Planck.s constant.

Figure shows the graph of stopping potential verus that frequency of a photosensitive metal. The plank's constant and work funcation of the metal are

The slope of the graph drawn between stopping potential and frequency of incident radiation will be

Sketch the graphs, showing the variation of stopping potential V_s with frequency v of the incident radiations for two photosensitive materials A and B having threshold frequencies v_0gtv'_0 respectively. (i) which of the two metals A or B has higher work function? (ii) What information do you get from the slope of the graphs? (iii) What does the value of the intercept of graph A on the potential axis represent?

When a high frequency electromagnetic radiation is incident on a metallic surface, electrons are emitted from the surface. Energy of emitted photoelectrons depends only on the frequency of incident electromagnetic radiation and the number of emitted electrons depends only on the intensity of incident light. Einstein's protoelectron equation [K_(max)=hv-phi} correctly explains the PE, where upsilon= frequency of incident light and phi= work function. Q. The slope of the graph between stopping potential and frequency is [here h is the Planck's constant and e is the charge of an electron] is

Graph of incident freuency with stopping potential in photoelectric effect is

The following figure shows a graph for the stopping potential as a function of the frequency of incident light illuminating a metal surface. Find the photoelectric work function for this surface.

The surface of cesium is illuminated with monochromatic light of various wavelengths and the stopping potential for the wavelength are measured. The results of this experiment is plotted as shown in the figure Estimate the value of work function of the cesium and Planck's constant.

Graph between stopping potential and frequency of photon is given in figure Find out work function of metal:

Graph between stopping potential and frequency of light as shown find the work function

Three metals have work functions in the ratio 2 3:4. Graphs are drawn for all connecting stopping potential and incident frequency. The graphs have slopes in the ratio