Consider the situation of the previous p...

Consider the situation of the previous problem. Consider the fastest electron emitted parallel to the large metal plate. Find the displacement of this electron parallel to its initial velocity before it strikes the large metal plate.

Text Solution

Verified by Experts

Here electric field of metal plate ,
E = P / E_o = 1 xx 10^(19) / 8.85 xx 10^(-12) `
` = 113 V / m`
Accelaration, a = `qE / m `
`= 1.6 xx 10^(-19) xx 113 / 9.1 xx 10^(-31) = 19.87 xx 10^(12) `
` t = (sqrt 2y/ a ) = (sqrt 2 xx 20 xxx 10^(-2) / 19.87 xx 10^(12)) `
` = 1.41 xx10^(-7) sec`
K.E. = hc / lambda - W = 1.2eV` ltbrge 1.41 xx 10^(-7)sec `
` =1.2 xx 1.6 xx 10^(-19) J `
`[:. in problem 31 : KE = 1.2 eV ]`
`:. V = (sqrt 2KE / m) `
` = ( sqrt 2 xx 1.2 xx 1.6 xx 10^(-19)/ 4.1 xx 10^(-31)`
`= 0.665 xx 10^(-6) m / sec`.
`:. Horizontal displacemnt
` = Vxx t `
` = 0.665 xx 10^(-6) xx 1.4 xx 10^(-7) `
` 0.092 m = 9.2 cm`

Topper's Solved these Questions

PHOTO ELECTRIC EFFECT AND WAVE PARTICLE DUALITY
HC VERMA|Exercise objective II|7 Videos
PERMANENT MAGNETS
HC VERMA|Exercise Exercise|25 Videos
PHOTOMETRY
HC VERMA|Exercise All Questions|44 Videos

Similar Questions

Explore conceptually related problems

Consider the situation of the previous question from a frame moving with a speed v_0 parallel to the initial velocity of the block? b. What is the work done by the kinetic friction?

Consider the situation of the previous problem. A particle having charge q and mass m is projected from the point Q in a direction going into the plane of the diagram. It is found to describe a circle of radius r between the two plates. Find the speed of the charged particle.

Consider the situation of the previous problem. Define displacement resistance (R_d = V/i_d) of the space between the plates where V is the potential difference between the plates and i_d is the displacement current. Show that R_d varies with time as (R_d)= (R(e^(t/tau)-1).)

Consider the situation described in the previous example. A particle of mass m having a charge q is placed at a distance d from the metal sheet and is projected towards it. Find the maximum velocity of projection for which the particle does not hit the sheet.

Consider a situation similar to that of the previous problem except that the ends of the rod slide on a pair of thick metallic rails laid parallel to the wire. At one end the rails are connected by resistor of resistance R. (a) what force is needed ot keep the rod sliding at a constant speed v? (b) in this situation what is the current in the resistance R? (c) Find the rate of heat developed in the resistor. (d) find the power delivered by the external agent exerting the force on the rod.

Consider the situation of the previous problem. (a) Calculate the force needed to keep the sliding wire moving with a constant velocity v. (b) If the force needed just after t = 0 is F_0 , find the time at which the force needed will be F_0 /2.

Consider the situation shown in the figure of the previous problem. Suppose the wire connecting O and C has zero resistance but circular loop has a resistance R uniformly distributed along its length. The rod OA is made to rotate with a uniform angular speed omega as shown in the figure. Find the current in the rod when ltAOC = 90^@ .

A parallel- plate capacitor with plate area A and separation between the plates d, is charged by a constant current i. Consider a plane surface of area A/2 parallel to the plates and drawn summetrically between the plates. Find the displacement current through this area.

Consider the statements A and B in the previous queston. Peltier effect is caused by A. Free electron density is different in different metals. B. Free electron density in a metal depends on temperature.

Consider the situation shown in figure .The plates of the capacitor have plate area A and are clapmed in the laborstory . The dielectric slab is released from rest with a length a inside the capacitor. Neglecting any effect of friction or gravity, show that slab will execute periodie motion and find its time period.

HC VERMA-PHOTO ELECTRIC EFFECT AND WAVE PARTICLE DUALITY-Exercise

The work function of a photoelectric material is 4.0 e V. (a) What i...
Text Solution
|
Find the maximum magnitude of the linear momentum of a photoelectron e...
Text Solution
|
When a metal plate is exposed to a monochromatic beam of light of wave...
Text Solution
|
In an experiment on photoelectric effect, the stopping potential is me...
Text Solution
|
The electric field associated with a monochromatic beam of light becom...
Text Solution
|
The electric field associated with a light wave is given by E= E0 sin...
Text Solution
|
The electric field at a point associated with a light wave is E=100Vm^...
Text Solution
|
A monochromatic light source of power 5mW emits 8 xx 10^(15) photons p...
Text Solution
|
Figure is the plot of the stopping potential versus the frequency of t...
Text Solution
|
A photographic film is coated with a silver bromide layer. When light ...
Text Solution
|
In an experiment on photoelectric effect light of wavelength 400 nm is...
Text Solution
|
A silver ball of radius 4.8 cm is suspended by a thread in a vacuum ch...
Text Solution
|
In an experiment on photoelectric effect, the emitter and the collecto...
Text Solution
|
In the following arrangement y = 1.0 mm , d = 0.24 mm and D = 1.2 m. T...
Text Solution
|
In a photoelectric experiment, the collector plate is at 2.0 V with re...
Text Solution
|
A small piece of cesium metal phi=1.9eV is kept at a distance of 20 cm...
Text Solution
|
Consider the situation of the previous problem. Consider the fastest e...
Text Solution
|
A horizontal cesium plate(phi=1.9eV) is moved vertically downward at a...
Text Solution
|
A small metal plate of work function phi is kept at a distance r from ...
Text Solution
|
A light beam of wavelength 400 nm is incident on a metal of work- func...
Text Solution
|