Home
Class 11
PHYSICS
Assume that a tunnel is dug across the e...

Assume that a tunnel is dug across the earth (radius=R) passing through its centre. Find the time a particle takes to cover the length of the tunnel if (a) it is projected into the tunnel with a speed of `sqrt((gR)` (b) it is relased from a height R above the tunnel (c ) it is thrown vertically upward along the length of tunnel with a speed of `sqrt(gR).`

Text Solution

Verified by Experts

The correct Answer is:
A, B, C
Let M be the total mass of the earth. At any position x.
`:. (M_1)/(M) = (pxx(4)/(3)pix^3)/(pxx (4)/(3)pi r^3) xx (x^3)/(R^3)`
`rArr M_1 = (Mx^3)/(R^3)`
So, force on the particle is given by
`:. F_x = (GMm)/(x^2)`
` = (GMm)/(R^3)x ..... (1)`
So, acceleration of the mass 'M' at that position is given by,
`a_x = (GMm)/(R^3)`
`rArr (ax)/(x) = omega^2`
`=(GM)/(R^3) = (g)/(R ) (g = (GM)/(R^2))`
So, `T = 2pi sqrt((R )/(g))`
= time period of ocillation
(a) Now using velocity
= displacement equation
`upsilon = omega sqrt((A^2 - Y^2))`
[where, A = amplitude]
Given when,
`y = R, upsilon = sqrt(gR), w = sqrt((g)/(R ))`
`rArr sqrt(gR) = sqrt(((g)/(R )))/((A^2 - R^2))`
`rArr R^2 = A^2 - R^2`
[ Now, the phases of the particle at the point
P is grater then `(pi)/(2)` has less then `pi` and at
Q is grater then `pi` but less then `(3pi)/(2)` Let the times taken by the particle to reach the position P and Q be `t_1 and t_2` respectively, then using displacement equation].
y = r sin omega t`
We have
`R = sqrt2 R sin omega t`
`rArr omegat_1 = (3pi)/(4)`
We have, `R = sqrt2 R sin omega t_1`
`rArr omega t_2 = (5pi)/(4)`
`So, omega (t_2 - t_1) = (pi)/(2)`
`rArr t_2 - t_1 = (pi)/(2omega) = ((pi)/(2))/((R )/(g))`
Time taken by the particle to travel from P to Q is
`t_2 - t_1 = (pi)/(2) ((R )/(g))sec.`
(b) When the body is dropped from a height r, then applying conservation of energy, change in P.E. = gain in K.E.
`rArr (GMm)/(R ) - (GMm).(2R) = (1)/(2) m upsilon^2`
`rArr upsilon = sqrt(gR)`
Since the velocity is same at P, as in part (a) the body will taken same time to travel PQ.
(c ) When the body is projected vertically upward from P with a velocity. `(sqrt(gR)`its velocity will be zero at the highest point. The velocity of the body, when reaches P, again wil be
`upsilon = sqrt((gR))
Hece the body will take same time
`(pi)/(2) sqrt((R )/(g))` to travel P.Q.
Doubtnut Promotions Banner Mobile Dark
|

Topper's Solved these Questions

  • SIMPLE HARMONIC MOTION

    HC VERMA|Exercise Objective-2|16 Videos

  • ROTATIONAL MECHANICS

    HC VERMA|Exercise Exercises|86 Videos

  • SOME MECHANICAL PROPERTIES OF MATTER

    HC VERMA|Exercise Exercises|32 Videos

Similar Questions

Explore conceptually related problems

A tunnel is dug along a diameter of the earth. Find the force on a particle of mass m placed in the tunnel at a distance x from the centre.

Assume that a tunnel ils dug along a chord of the earth, at a perpendicular distance R/2 from the earth's centre where R is the radius of the earth. The wall of the tunnel is frictionless. a. Find the gravitational force exerted by the earth on a particle of mass m placed in the tunnel at a distance x from the centre of the tunnel. b. Find the component of this fore along the tunnel and perpendicular to the tunnel. c. Find the normal force exerted by the wall on the particle. d. Find the resultant force on the particle. e.Show that the motion of the particle in the tunnel is simple harmonic and find the time period.

A tunnel is dug along a chord of the earth a perpendicular distance R/2 from the earth's centre. The wall of the tunnel may be assumed to be frictionless. Find the force exerted by the wall on a particle of mass m when it is at a distance x from the centre of the tunnel.

Shown a circular coil of N turns and radius a, connected to a battery of emf epsilon through a rheostat. The rheostat has a total length L and resistance R. The resistance of the coil is r. A small circular loop of radius a' and resistance r' is placed coaxially with the coil. The centre of the loop is at a distance x from the centre of hte coil. In the beginning, the sliding contact of the rehostat is at the left end and then on wards it is moved towards right at a constant speed v. Find the emf induced int he small circular loop at the instant (a) the contact begins to slide and (b) it has slid thrugh half the length of the rheostat.

Figure shows a smooth track which consists of a straight inclined part of length l joining smoothly with the circular part. A particle of mass m is projected up the incline from its bottom. a.Find the minimum projected speed v_0 for which the particle reaches the top of the track. b. Assuming that the projection speed is 2v_0 and that the block does not lose contact with the track before reading its top, find teh force acting on it whenit reaches the top. c. Assuming that teh projection speed is only slightly greater than v_0 where will the block lose contact with the track?

A pendulum having a bob of mas m is hanging in a ship sailing along the equator from east to west. When the ship is stationary with respect to water the tension in the string is T_0 . a. Find the speed of the ship due to rotation of the earth about its axis. b. find the difference between T_0 and the earth's attraction on the bob. c. If the ship sails at speed v, what is the tension in the string ? Angular speed of earth's rotation is omega and radius of the earth is R.

Shows a convex lens of focal length 12 cm lying in a uniform magnetic field B of magnitude 1.2 T parallel to its principal axis. A particle having a charge 2.0X 10^(-3) C and mass 2.0 X 10^(-5) kg is projected perpendiucular to the plane of the diagram with a speed of 4.8 ms ^(-1). The particle moves along a circle with its centre on the principal axis at a distance of 18 cm from the lens. Show that the image of the particle goes along a circle end find the radius of thet circle.

A string of linear mass density 0.5 g cm^-1 and a total length 30 cm is tied to a fixed wall at one end and to a frictionless ring at the other end. The ring can move on a vertical rod. A wave pulse is produced on the string which moves towards the ring at a speed of 20 cm s^-1 . The pulse is symmetric about its maximum which is located at a distance of 20 cm from the end joined to the ring. (a) Assuming that the wave is reflected from the ends without loss of energy, find the time taken by the string to regain its shape. (b) The shape of the string changes periodically with time. Find this time period. (c) What is the tension in the string ?

A motorcycle has to move with a consatnt speed on an overbridge which is in the form of as circular arc of radius R and has a total length L. Suppose the motorcycle starts from the highest point. a) what can its maximum velocity be for which the contact with the road is not broken at the highest point? b) If the motorcycle goes at speed 1/sqrt2 times the maximum found in part a. where will it lose the contact with the road? c) What maximum uniform speed can it maintain on the bridge if it does not lose contact anywhere on the bridge?

A particle of mass m is kept on the top of a smooth sphere of radius R. It is given a sharp impulse which imparts it a horizontal speed v. a. find the normal force between the sphere and the particle just after the impulse. B. What should be the minimum value of v for which the particle does not slip on the sphere? c. Assuming the velocity v to be half the minimum calculated in part, d. find the angle made by the radius through the particle with the vertical when it leaves the sphere.

Home
Profile