A free electron is located in the field of a monochromatic light wave. The intensity of light is I = 150 W//m^(2), its frequency is omega = 3.4 . 10^(15) s^(-1). Find: (a) the electron's oscillation amplitude and its velocity amplitude, (b) the ratio F_(m)//F_(e), where F_(m) and F_(e) are the amplitudes of forces with which the magnetic and electric components of the ligth wave field act on the electron, demonstrate that the ratio is equal to (1)/(2)v//c, where v is the electron's velocity amplitude and c is the velocity of light. Instruction. The action of the magnetic field component can be disregarded in the equation of motion of the electron since the calculations shown it to be negligible.

A free electron is located in the field of a monochromatic light wave.

1.	A free electron is located in the field of a monochromatic light wave. The intensity of light is I = 150 W//m^(2), its frequency is omega = 3.4 . 10^(15) s^(-1). Find: (a) the electron's oscillation amplitude and its velocity amplitude, (b) the ratio F_(m)//F_(e), where F_(m) and F_(e) are the amplitudes of forces with which the magnetic and electric components of the ligth wave field act on the electron, demonstrate that the ratio is equal to (1)/(2)v//c, where v is the electron's velocity amplitude and c is the velocity of light. Instruction. The action of the magnetic field component can be disregarded in the equation of motion of the electron since the calculations shown it to be negligible.
Answer» Solution :In a travelling plane electromagnetic wave the intensity is simply the time averaged magnitude of the Polynting VECTOR:- ` I = lt\|oversetrarr(E) xx oversetrarr(H)\|gt = lt sqrt((epsilon_(0))/(mu_(0)))E^(2) gt = lt c epsilon_(0)E^(2)gt` on using `c = (1)/(sqrt(epsilon_(0)mu_(0))), E sqrt(epsilon_(0)) = H sqrt(mu_(0))`. Now time averaged value of `E^(2)` is `E_(0)^(2)//2` so `I = (1)/(2)c epsilon_(0) E_(0)^(2)` or `E_(0) = sqrt((2I)/(c epsilon_(0)))`, (a) Represent the electric field at any POINT by `E = E_(0) sin omegat`. Then for the electron we have the equation. `m ddotx = eE_(0)sin omegat` so `x =- (eE_(0))/(m omega^(2)) sin omegat` The amplitude of the forced oscillation is `(eE_(0))/(m omega^(2)) = (e)/(m omega^(2)) sqrt((2I)/(c epsilon_(0))) = 5.1 xx 10^(-16) cm` The velocity amplitude is clearly `(eE_(0))/(m omega) = 5.1 xx 10^(-16) xx 3.4 xx 10^(15) = 1.73 cm//sec` (b) For the electric force `F_(e) =` amplitude of the electric force `= eE_(0)` For the magnetic force (which we have neglected above), it is `(evB) = (evmu_(0)H)` `= evE sqrt(epsilon_(0)mu_(0)) = EV(E)/(c)` writing `v=- v_(0) cos omega t` where `v_(0) = (eE_(0))/(m omega)` we see that the magnetic force is apart from a sign `(ev_(0)E_(0))/(2c)sin 2 omegat` Hence `(F_(m))/(F_(e)) =` Ratio of amplitudes of the two forces `= (v_(0))/(2c) = 2.9 xx 10^(-11)` This is negligible and justifies the neglect of magnetic field of the electromagnetic wave in CALCULATING `v_(0)`.

Discussion

No Comment Found

Related InterviewSolutions

A wire is bent to form a semicircle of the radius a. The wire rotates about its one end with angular velocity omega . Axis of rotation is perpendicular to the plane of the semicircle . In the space , a uniform magnetic field of induction B exists along the aixs of rotation as shown in the figure . Then -
A massless non conducting rod AB of length 2l is placed in uniform time varying magnetic field confined in a cylindrical region of radius (R gt l) as shown in the figure. The center of the rod coincides with the centre of the cylin- drical region. The rod can freely rotate in the plane of the Figure about an axis coinciding with the axis of the cylinder. Two particles, each of mass m and charge q are attached to the ends A and B of the rod. The time varying magnetic field in this cylindrical region is given by B = B_(0) [1-(t)/(2)] where B_(0) is a constant. The field is switched on at time t = 0. Consider B_(0) = 100T, l = 4 cm(q)/(m) = (4pi)/(100) C//kg. Calculate the time in which the rod will reach position CD shown in the figure for th first time. Will end A be at C or D at this instant ?
A concave lens with equal radius of curvature both sides has a focal length of 12 cm. The refractive index of the lens is 1.5. How will the focal length of the lens change if it is immersed in the liquid of refractive index 1.8 ?
If the tempearture of black body is raised by 5%, the heat energy radiated would increases by :
What are the co-ordinates of the image of S formed by a plane mirror as shown in figure?
The direction of ray of light incident on a concave mirror is shown by PQ in Fig. The direction in which the ray would travel after reflection is shown by four rays marked 1, 2, 3 and 4. Which of the four rays correctly shows the direction of reflected ray?
What is meant by polarisation ?
Two concentric coils each of radius equal to 2πcm are placed right angles to each other. If 3 A and 4 A are the currents flowing through the two coils respectively. The magnetic induction( in Wb m^(-2) )at the center of the coils will be
Assertion: Out of ""_(1)He^(3) and ""_(7)He^(3), the binding energy of ""_(1)He^(3)is greater than ""_(2)He^(8). Reason: Inside the nucleus of""_(1)H^(3), there is more repulsion than inside the nucleus of ""_(2)He^(4).
In which accelerated motion, K.E of the particle is constant

Discussion

No Comment Found

Related InterviewSolutions

Reply to Comment