Assertion: When a body dropped from a height explodes in mid air, its center of mass keeps moving in vertically downward directions.
Reason: Explosion occurs under internal forces only. External force is zero.

Assertion :- A ball is thrown from the edge of a very high clif. No matter what the angle at which it is thrown , due to air resistance, the ball will eventually end up moving vertically downward. Reason :- In horizontal direction there is a component of retarding force of air resistance alone.

A ball starts falling under the effect of gravitational force from a height of 45m. When it reaches a height of 25 m. When it reaches a height of 25 m it explodes into two pieces of mass ratio 1:2 . There is no change in the vertical motion of the piece after the explosion but they acquire horizontal velocity. If the heavier piece gains a horizontal velocity of 10ms^(-1) , then the distance between the two pieces when both of them strike the ground is

Assertion : A body can be at rest even when it is under the action of may number of external forces Reason : Because vector sum of the all external forces is zero .

Assertion: A projectile gets exploded at its highest point. All the piece get only horizontal velocities. Reason: The weight of the projectile is the external force for projectile.

Assertion:- In two particle system when viewed from center of mass reference frame, if one particle slops then other one will also stop simultaneously, irrespective of external forces acting on system. Reason:- Centre of mass of a system is a point about which total momentum of system is always constant and non-zero.

A time t = 0 , a body of mass 1 kg is dropped from height 500 m . At t = 1 sec , the body explodes into two parts of equal mass. One of them moves vertically upwards with velocity 5 m//s just after the explosion. The distance (in m ) between the parts at time t = 4 sec is 15x Then find x ?

A projectile has a maximum range of 16 km. At the highest point of its motion, it explodes into two equal masses. One mass drops vertically downward. The horizontal distance covered by the other mass from the time of explosion

Assertion : Generally the path of a projectile from the earth is parabolic but it is elliptical for projectiles going to very great height. Reason : Up to ordinary height the projectile moves under a uniform gravitational force, but for great heights, projectile moves under a variable force.

The basic principle underlying the Hall effect is the Lorentz force. When an electron moves along a direction perpendicular to an applied magnetic field, it experiences a force acting normal to both the directions and moves in response to this force and the force exerted by the internal electric field. For an n -type, "bar" -shaped semiconductor, the carriers are predominantly electrons of bulk density n . We assume that the constant current I flows along the x -axis from left to right in the presence of a magnetic field toward y -axis. Electrons subjected to the lorentz force initially drift away from the current line toward the negative z -axis, resulting in an excess surface electrical charge on the sides of the sample. This charge results in the hall voltage, a potential drop across the two sides of the sample. The transverse voltage is the hall voltage V_(H) and its magnitude is equal to IB//qnd , where I is the current, B is the magnetic field, d is the sample thickness and q is the elementary charge. A silver ribbon lies as shown in the adjacent figure. ( z_(1)=11.8 mm and y_(1)=0.23 mm ) carrying a current of 120 A in the x -direction in a uniform magnetic field B=0.95 T . If electron density is 5.85xx10^(28)//m^(3) , then Magnitude of the drift velocity of elelctrons is

The basic principle underlying the Hall effect is the Lorentz force. When an electron moves along a direction perpendicular to an applied magnetic field, it experiences a force acting normal to both the directions and moves in response to this force and the force exerted by the internal electric field. For an n -type, "bar" -shaped semiconductor, the carriers are predominantly electrons of bulk density n . We assume that the constant current I flows along the x -axis from left to right in the presence of a magnetic field toward y -axis. Electrons subjected to the lorentz force initially drift away from the current line toward the negative z -axis, resulting in an excess surface electrical charge on the sides of the sample. This charge results in the hall voltage, a potential drop across the two sides of the sample. The transverse voltage is the hall voltage V_(H) and its magnitude is equal to IB//qnd , where I is the current, B is the magnetic field, d is the sample thickness and q is the elementary charge. A silver ribbon lies as shown in the adjacent figure. ( z_(1)=11.8 mm and y_(1)=0.23 mm ) carrying a current of 120 A in the x -direction in a uniform magnetic field B=0.95 T . If electron density is 5.85xx10^(28)//m^(3) , then What is the value of hall emf ?