Choose the correct options-
(1) Inertia ` prop` mass
(2) `1 " newton"=10^(5)" dyne"`
(3) Thrust on rocket `overset rightarrow"F"=(Delta"M")/(Delta"t")" "overset rightarrow"V"-"M"oversetrightarrow"g"`
(4) Apparent weight of a body in the accelerated lifts is W=m (g+a).

Choose the correct statements- (1) For equilibrium of a body under the action of concurrent forces oversetrightarrow"F"_(1)+oversetrightarrow"F"_(2)+oversetrightarrow"F"_(3)+.......oversetrightarrow"F"_("n")=0 (2) If the downward acceleration of the lift is a = g, then the body will experience weightlessness. (3) If the downward acceleration of the body is a gt g, then the body will rise up to the ceiling of lift (4) If the downward acceleration of the lift is a gt g, then the body will experience weightlessness.

A spring balance fastened to the roof of a lift accelerating upwards indicates 120 N as the weight of a 80 N body. The acceleration of the lift is (g = 10 m//s^(2)) .

If the weight of a body on the surface of the moon is 100 N, what is its mass ? ( g = 1.63 m//s^(2))

Choose the correct alternative. Person has a mass of 8.4 kg. Its weight on moon if the value of 'g' on earth is 10 m//s^(2) , will be

A man is standing in a lift which goes up and comes down with the same constant acceleration. If the ratio of the apparent weights in the two cases is 2 : 1 , then the acceleration of the lift is : (Take g = 10 m//s^(2) )

The centre of mass of a body is a point at which the entire mass of the body is supposed to be concentrated. The position vector overset rarr(r ) of c.m of the system of tow particles of masses m_(1) and m_(2) with position vectors overset rarr(r_(1)) and overset rarr(r_(2)) is given by overset rarr(r ) = (m_(1)overset rarr(r_(1)) + m_(2)overset rarr(r_(2)))/(m_(1) + m_(2)) For an isolated system, where no external force is acting, overset rarr(v_(cm)) = constant Under no circumstances, the velocity of centre of mass of an isolated system can undergo a change With the help of the comprehension given above, choose the most appropriate alternative for each of the following questions : Two bodies of masses 1 kg and 2kg are located at (1, 2) and (-1, 3) respectively. the co-ordinates of the cetre of mass are :

The centre of mass of a body is a point at which the entire mass of the body is supposed to be concentrated. The position vector overset rarr(r ) of c.m of the system of tow particles of masses m_(1) and m_(2) with position vectors overset rarr(r_(1)) and overset rarr(r_(2)) is given by overset rarr(r ) = (m_(1)overset rarr(r_(1)) + m_(2)overset rarr(r_(2)))/(m_(1) + m_(2)) For an isolated system, where no external force is acting, overset rarr(v_(cm)) = constant Under no circumstances, the velocity of centre of mass of an isolated system can undergo a change With the help of the comprehension given above, choose the most appropriate alternative for each of the following questions : An electron and a proton move towards eachother with velocities v_(1) and v_(2) respectively. the velocity of their centre of mass is

The centre of mass of a body is a point at which the entire mass of the body is supposed to be concentrated. The position vector overset rarr(r ) of c.m of the system of tow particles of masses m_(1) and m_(2) with position vectors overset rarr(r_(1)) and overset rarr(r_(2)) is given by overset rarr(r ) = (m_(1)overset rarr(r_(1)) + m_(2)overset rarr(r_(2)))/(m_(1) + m_(2)) For an isolated system, where no external force is acting, overset rarr(v_(cm)) = constant Under no circumstances, the velocity of centre of mass of an isolated system can undergo a change With the help of the comprehension given above, choose the most appropriate alternative for each of the following questions : A bomb dropped from an aeroplane in level flight explodes in the middle. the centre of mass of the fragments

Consider a reaction A(g)overset(k=0.1 M min^(-1))to2B(g) . If initial concentration of A is 0.5 M then select correct graph.

A block of mass 2 kg rests on the floor of an elevator , which is moving down with an acceleration 'g' , then the apparent weight of the block is [ take g = 10 m//s^(2) ]