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At a height of $0.4m$ from the ground, the velocity of a projectile in vector form is$\overrightarrow{v}=(6\hat{i}+2\hat{j})m/s.$ The angle of projection is
$(g=10m/s^2)$

A massless wire $2\text{m}$ in length suspended vertically stretches by $10\text{mm}$ when mass of $10\text{kg}$ is attached to the lower end. The elastic potential energy gained by the wire is (Take $g=10{\text{m/s}}^2$)

Mass of upper block and lower block kept over the table is $2kg$ and $1kg$ respectively and coefficient of friction between the blocks is $0.1$. Table surface is smooth. The maximum mass $m$ for which all the three blocks move with same acceleration is $(g=10m/s^2)$

A $20\text{kg}$ wagon originally at rest, is pushed with a force of $7\text{N}$ for $1.5\text{s}$, then with a force of $5\text{N}$ for $1.7\text{s}$ and then with a force of $10\text{N}$ for $3\text{s}$. Find the final velocity of the cart.

sphere of 4 cm radius is suspended within a hollow sphere of radius 6cm the inner sphere is charged to a potential 3S you when the outer sphere is earthed the charge on the inner sphere is

Write a Condition in which instantaneous velocity and average velocity are same.

A charged particle moves through a magnetic field in a direction perpendicular to it , then which of the following quantities remains unchanged?

Force of interaction between two co axial short electric dipoles whose centres are R distance apart varies as

A cubical block of wood of edge $3\text{cm}$ floats in water. The lower surface of the cube just touches the free end of a vertical spring fixed at the bottom of the pot. Find the maximum weight that can be put on the block without wetting it.
(Take density of wood $=800{\text{kg/m}}^3$, spring constant of the spring $=50\text{N/m}$ and $g=10{\text{m/s}}^2$.)

A shell of mass 'm' is projected with velocity V at an angle ${60}^o$ to the horizontal. When it reaches the maximum height, then its angular momentum with respect to point of projection

The galvanometer shown in the figure has a resistance $50\Omega$ and full-scale deflection current 1 mA. What are the the resistances $R_1,R_2$ and $R_3$ required to convert it into ammeter having ranges as indicated?

Consider a swimmer with velocity $V_s$ in still water. He now tries to cross a river flowing due north with velocity $V_r=V_0(1-\frac{x^2}{a^2})$, where $x=-a$ and $x=+a$ are banks of river. X-axis is towards east. Displacement of man towards the north, if he crosses the river in minimum time is

Recall the term used to describe the possible energies that electrons in an atom can have.

Charges are placed on corners of square of side $a$ (as shown in figure). Find magnitude of net dipole moment.

The velocity of water in a river is $18{\text{kmh}}^{-1}$ near the surface. If the river is $5\text{m}$ deep, then the shearing stress between the surface layer and the bottom layer is:
(Given - coefficient of viscosity of water, $\eta ={10}^{-3}\text{Pa.s}$)

A jet airplane travelling at the speed of $500km{h}^{-1}$ ejects its products of combustion at the speed of $1500km{h}^{-1}$ relative to the jet plane. What is the speed of the latter with respect to an observer on ground?

Difference between center of mass and center of gravity

Two bodies of metal are mounted on glass stands. Their surface area is equal but one is a sphere and other is pear shaped. Both are given the same amount of charge. Which one will lose its charge first?

The amplitude of S.H.M at resonance is _______ in the ideal case of zero damping.

A 1500-kg car moving on a flat, horizontal road negotiates a curve. If the radius of the curve is 20.0 m and the coefficient of static friction between the tires and dry pavement is 0.50, find the maximum speed the car can have so that it still makes the turn successfully.

A block of 5 kg mass rests on a horizontal floor. The action of the block on the floor is

A sphere of radius r is kept on a concave mirror of radius of curvature R. The arrangement is kept on a horizontal table (the surface of concave mirror is frictionless and sliding not rolling). If the sphere is displaced from its equilibrium position and left, then it executes S.H.M. The period of oscillation will be

If a water drop is kept between two glass plates, then its shape is

Power of a water pump is 2 kW. If $g=10m/se{c}^2$ , the amount of water it can raise in one minute to a height of 10 m is

Consider the situation shown in figure. Find the maximum angle $\theta$ for which the light suffers total internal reflection at the vertical surface.

What amount of work is done in increasing the length of a wire through unity?

Each of the three blocks P, Q and R shown in figure has a mass of 3 kg. Each of the wires A and B has cross-sectional area 0.005 cm^{2} and Young modulus 2 \times 10^{11} N~m^{2}. Neglect friction. Find the longitudinal strain developed in wire B. Take $g=10m{s}^{-2}.$

A body is dropped from a height of $39.2\text{m}$. After it crosses the half distance, the acceleration due to gravity comes to an end. Then the body will hit the ground with a velocity of $($Take $g=9.8{\text{ms}}^{-2})$

Two lenses with powers; 2D & -4D are kept together. What is the effective focal length of the combination?

A particle is subjected to two simple harmonic motions given by

$x_1=2.0sin\left(100\pi t\right)$ and $x_2=2.0sin(120\pi t+\pi /3)$,

where x is in centimeter and t in second. Find the displacement of the particle at (a) $t=0.0125,$ (b) $t=\mathrm{0.025.}$

A charge q is circulating in an orbit of radius r making n revolutions per second. The magnetic field produced at the center of the circle inTesla is

A vector $\overrightarrow{A}$ makes an angle of ${20}^0$ and $\overrightarrow{B}$ makes an angle of ${110}^0$ with the X-axis. The magnitudes of these vectors are 3 m and 4 m respectively. Find the resultant.

A block of mass m is pulled along a horizontal surface by applying a force at an angle $\theta$ with the horizontal. If the block travels with a uniform velocity and has a displacement d and the coefficient of friction is $\mu$. then the work done by the applied force is

Moment of Inertia of a thin uniform rod rotating about the perpendicular axis passing through its centre is I. If the same rod is bent into a ring and its moment of inertia about its diameter is I’, then the ratio $\frac{I}{I^{\prime }}$ is

Water is flowing continuously from a tap having an internal diameter $8\times {10}^{-3}m$. The water velocity as it leaves the tap is $0.4m{s}^{-1}$. The diameter of the water stream at a distance $2\times {10}^{-1}m$ below the tap is close to

A thin symmetrical double convex lens of power $P$ is cut into three parts $(A,B,C)$, as shown in the figure. Power of $A$ is:

A thermally insulated chamber of volume $2v_0$ is divided by a frictionless piston of area ‘S’ into two equal parts A and B. Part ‘A’ has an ideal gas at pressure $P_0$ and temperature $T_0$ and in part B there is vacuum. A massless spring of force constant k is connected with piston and the wall of the container as shown. Initially spring is unstretched. Gas in chamber A is allowed to expand. Consider the compression in spring to be $x_0$ in equilibrium.

A metallic sphere having radius 0.08m and mass m = 10 kg is heated to a temperature of ${227}^{\circ }C$and suspended inside a box whose walls are at a temperature of ${27}^{\circ }C$. The maximum rate at which its temperature will fall is Take $e=1,\sigma =5.8\times {10}^{-8}W{m}^{-2}{K}^{-4}$ and specific heat of the metal $S=90cal/kg/k;J=4.2J/cal)$

The K.E of mole of an ideal gas is $E=\frac{3}{2}\text{RT}$. Then $C_p$ will be