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Short & Long Answer Questions: Laws of Motion | Physics for ACT PDF Download

Q.1 Why do bodies of small mass require small initial effort to bring them into motion?
Answer:
The inertia of a body is proportional to its mass. Smaller the mass, lesser is the opposition to the change of state of motion.
Q.2 Can a body in linear motion be in equilibrium?
Answer:
Yes, provided the vector sum of the forces acting upon the body is zero.
Q.3 A body is acted upon by a number of external forces. Can it remain at rest?

Answer: If the vector sum of all the external forces is zero, then the body will remain at rest.
Q.4 If the net force acting on the body be zero, will the body remain necessarily in rest position?

Answer: No, the body may be in the state of uniform motion along a straight line even when the net force acting on the body is zero.
Q.5 If a force is acting on a moving body perpendicular to the direction of motion, then what will be its effect on the speed and direction of the body?

Answer: There will be no change in the speed of the body but the direction will change continuously.
Q.6 Why do the passengers fall in backward direction when a bus suddenly starts moving from the rest position?
Answer:
When the bus suddenly starts moving, the lower part of the passenger's body begins to move along with the bus while the upper part tend to remain at rest due to inertia of rest. 

Effect of InertiaEffect of Inertia

That is why a passenger standing or sitting loosely in a bus falls backward when the bus suddenly starts moving.
Q.7 Why are passengers thrown forward from their seats when a speeding bus stops suddenly?

Answer: This is due to inertia of motion. When the speeding bus stops suddenly, lower part of the body in contact with the seat stops. The upper part of the body of the passengers tends to maintain its uniform motion. Hence the passengers are thrown forward.
Q.8 A man jumping out of a moving train falls with his head forward. Why?
Answer: As the man jumps out from a moving train, his feet suddenly come to rest on touching the ground while the upper part of his body continues to move forward. That is why he falls with his head forward. In order to save himself, he should run through some distance in the forward direction.
Q.9 Why do the blades of an electric fan continue to rotate for some time after the current is switched off?

Answer: This is due to inertia of motion that the blades of an electric fan continue to rotate for some time even after the fan has been switched off.
Q.10 A stone when thrown on a glass window smashes the windowpane to pieces, but a bullet from the gun passes through making a clean hole. Why?
Answer:
Due to its small speed, the stone remains in contact with the windowpane for a longer duration. It transfers its motion to the pane and breaks it into pieces. But the particles of windowpane near the hole are unable to share the fast motion of the bullet and so remain undisturbed.
Q.11 We beat a blanket with stick to remove dust particles. Why?
Answer: When we beat blanket with a stick, it comes into motion. But the dust particles continue to be at rest due to inertia and get detached from the blanket.
Q.12 If you jerk a piece of a paper placed under a book very quickly, the book will not move. Why?

Answer: The book continues in its state of rest due to inertia.
Q.13 Why fruits fall down from a tree, when its branches are shaken?
Answer:  Before shaking the branches, fruits are at rest. When branches are shaken, they come in motion while the fruits tend to remain at rest due to inertia of rest. As a result fruits get detached from the branches and fall down.
Q.14 Why an athlete runs some steps before taking a jump?
Answer:
An athlete always runs for some distance before taking a jump so that inertia of motion may help him in his muscular efforts to take a longer jump.
Q.15 A passenger sitting in a carriage at rest pushes it from within. Will the carriage move?

Answer: No, internal forces cannot produce motion in a system.
Q.16 If a ball is thrown up in a moving train, it comes back to the person's hands. Why?
Answer:
Both during its upward and downward motion, the ball continues to move (inertia of motion) with the same horizontal Velocity as the train. In this period, the ball covers the same horizontal distance as the train and so it comes back to the thrower's hands.
Q.17 Why are the passengers thrown out- wards when a car in which they are travelling suddenly takes a circular turn?
Answer:
This is because the passengers tend to maintain their direction of motion (inertia of direction) while the direction of car changes when it takes the turn.
Q.18 Why are the wheels of vehicles are provided with mudguards?

Answer: When the wheel rotates at a high speed, the mud sticking to the wheel flies off tangentially, this is due to inertia of direction. In order that the flying mud does not spoil the clothes of passersby, the wheels are provided with mudguards.
Q.19 An astronaut accidentally gets thrown out of his small spaceship accelerating in inter-stellar space at a constant rate of 100 ms−2. What is the acceleration of the astronaut the instant after he is outside the spaceship?

Answer: Assuming that there are no nearby stars to exert gravitational force and the small spaceship exerts negligible gravitational force on the astronaut, then moment he gets out of the ship, there is no external force on him. By the first law of motion, the acceleration of the astronaut is zero.
Q.20 Why is Newton's first law of motion also called law of inertia?
Answer:
According to Newton's first law of motion, a body by itself cannot change its state of rest or of uniform in a straight line. This inability of a body is called inertia. That is why Newton's first law of motion is also called law of inertia.
Q.21 A thief jumps from the upper storey of a house with a load on his back. What is the force of the load on his back when the thief is in air

Answer: Zero. This is because a condition of weight- lessness exists during a free fall. W=m(g−a)=m(g−g)=0.
Q.22 A soda-water bottle is falling freely. Will the bubbles of the gas rise in the water of the bottle?

Answer: Bubbles will not rise in water. The water in the freely-falling bottle is in the state of weightlessness?  Consequently, the pressure in water does not increase with depth. No up thrust acts on the bubbles and they do not rise.
Q.23 A bird is sitting on the floor of a wire cage and the cage is in the hand of a boy. The bird starts flying in the cage. Will the boy experience any change in the weight of the cage?

Answer: The air inside the wire cage is in free contact with the atmospheric air. When the bird starts flying inside the cage, the weight of the bird is no more experienced and the cage will appear lighter than before.
Q.24 The distance travelled by a body is directly proportional to time. Is any external force acting on it?
Answer: 
As s ∝ t or s=kt Short & Long Answer Questions: Laws of Motion | Physics for ACT i.e., the body is moving with a uniform velocity and no external force is acting on. it.
Q.25 Chinawares are wrapped in straw paper before packing. Why?
Answer: 
The straw paper between the chinaware increases the time of experiencing the jerk during transportation. Hence, they strike against each other with less force and are less likely to be damaged.
Q.26 Why we are hurt less when we jump on a muddy floor in comparison to a hard floor?

Answer: When we jump on a muddy floor, the floor is carried in the direction of the jump and the time interval Δt for which force acts is increased. This decreases rate of change of momentum and hence the force of reaction. Therefore we are hurt less.
Q.27 Why are shockers used in cars, scooters and motorcycles?

Answer: In the event of jerk or jump, the time for which the force lets increases. Since the product of force and time is to remain constant in a given situation, therefore the force decreases.
Q.28 Why buffers are provided between the bogies of a railway train?

Answer: Due to buffer spring, the time of impact between the bogies increases, and the force acting between the bogies (F = Impulse / time) decreases. Consequently, passengers sitting inside the bogies do not experience strong jerks. For the same reason shockers are provided in all vehicles.
Q.29 Why is it necessary to bend knees while jumping from greater height?

Answer: During the jump, our feet at once come to rest and for this smaller time (F = Impulse / time) a large force acts on feet. If we bend the knees slowly, the value of time of impact increases and less force acts on our feet. So we get less hurt.
Q.30 A brick can be pushed gently on the smooth floor by applying force with our foot. But if we kick the brick, the foot is hurt. Why?
Answer:
When the brick is kicked, the time for which force is impressed is short and hence rate of change of momentum of the brick is large. The brick in turn, due to reaction applies large force on the foot. This force may hurt our foot.
Q.31 Why is it that when a man jumps down from a height of several storey into a stretched tarpaulin, he receives no injury?

Answer: When the man jumps, the tarpaulin gets depressed at the place of impact. This increases the time of impact (Δt). As a result, the tarpaulin exerts a very small force (F = impulse/time) on the man, and he receives no injury.
Q.32 According to Newton's third law, every force is accompanied by equal and opposite force. How can anything move then?

Answer: Though action and reaction act simultaneously, but they act on different bodies. This makes the motion possible.
Q.33 Why is it difficult to drive a nail into a wooden block without supporting it?

Answer: When we hit the nail with a hammer, the nail and unsupported block together move forward as an single system. There is no force of reaction. When the block is rested against a support, the reaction of the support holds y the block in position and the nail is driven into the block.
Q.34 Why it is difficult to climb up a greasy pole?

Answer: When a person climbs up a pole, he presses the pole downward with his feet and the pole, in turn, pushes the person upwards with an equal force. If the pole  is greasy, its surface becomes slippery and the person is not able to press it. As there is no action, there will be no reaction. Hence it becomes difficult for the person to climb up.
Q.35 In a tug of war, the team that pushes harder against the ground wins. Why?

Answer: The team that pushes harder against ground » gets greater reactional force and this leads them to win.

Q.36 Can a sailboat be propelled by air blown at the sails from a fan attached to the boat?

Answer: No. When the fan pushes the sail by blowing air, the air also pushes the fan in the opposite direction. As the fan is also a part of the boat, the vector sum of the momenta of the fan and the boat is zero. The boat will move only if some external agency applies force on it.
Q.37 A man is at rest in the middle of a pond on perfectly frictionless ice. How can he get himself to the shore?
Answer:
If the man throws away his shirt in a direction opposite to the desired direction of motion, he can get himself to the shore.
Q.38 Two bodies of masses M and m are allowed to fall from the same height. If the air-resistance be same for each body, will the two bodies reach the earth simultaneously?

Answer: No. Let the air-resistance on each body be F. Net downward force on body of mass M = Mg - F Acceleration of body of mass M,  Short & Long Answer Questions: Laws of Motion | Physics for ACT Similarly acceleration of body of mass m, a′ 

Short & Long Answer Questions: Laws of Motion | Physics for ACT Thus the acceleration of the larger mass is greater, it will reach the earth earlier.
Q.39 There is some water in a beaker placed on the pan of a spring balance. If we dip our finger in this water without touching the bottom of the beaker then what would be the effect on the reading of the balance?
Answer:
The reading will increase. The water will exert up thrust on the finger and the finger will exert an equal force of reaction on water in the downward direction i.e., on the bottom of the beaker.
Q.40 Two boys having the same mass are standing on ice-skates at some distance apart on a friction- less surface. A rope is fastened around the body of a boy, the other end of which is in the hand of the second boy. What would happen if the second boy pulls the rope?
Answer:
The two boys will move towards each other with the same velocity so that their combined momentum is still zero (conservation of momentum).
Q.41 A retarding force is applied to stop a motor car. If the speed of the motor car is doubled, how much more distance will it cover before stopping under the same retarding force?

Answer:  Work done against retarding force =Loss in K.E. In first case, Short & Long Answer Questions: Laws of Motion | Physics for ACT ...(i)

 In second case, Short & Long Answer Questions: Laws of Motion | Physics for ACT ..(ii)

 From (i) and (ii),   s′= 4s Thus the motor car will cover a distance four times longer than before.
Q.42 Why does a rifle give a backward kick on firing a bullet?
Answer:
Before firing, both the bullet and the rifle are at rest and their total momentum is zero. After firing, the bullet gains a large momentum in the forward direction.  To conserve momentum, the rifle gains an equal momentum in the opposite direction. So the rifle gives a backward kick.
Q.43 Why is it advisable to hold a gun tight to one's shoulder when it is being fired?
Answer:
The recoiling gun can hurt the shoulder. If the gun is held tightly against the shoulder, the body and the gun will constitute one system. Total mass becomes large and the recoil velocity becomes small.
Q.44 When a body falls to the earth, the earth also moves up to meet it. But the earth's motion is not noticeable. Why?
Answer:
We know that acceleration is the ratio of applied force and mass of the body. Since the earth is a massive body, therefore its acceleration is very small. Hence the motion of the earth is not noticeable.
Q.45 A meteorite bums in the atmosphere before it reaches the earth's surface. What happens to its momentum?
Answer:
Since the meteorite moves under the force of gravity, therefore its momentum changes but remains conserved before and after burning.
Q.46 Why does a heavy rifle not kick as strongly as a light rifle using the same cartridge?
Answer:
Recoil velocity of a rifle, Short & Long Answer Questions: Laws of Motion | Physics for ACT Short & Long Answer Questions: Laws of Motion | Physics for ACT Thus the recoil velocity of the heavy rifle is smaller than that of the light rifle, so it does not kick strongly.
Q.47 Why is static friction called a self adjusting force?
Answer: 
As the applied force increases, the static friction also increases and becomes equal to the applied force. That is why static friction is called a self-adjusting force.
Q.48 Can we get off a frictionless horizontal surface by jumping?

Answer: No, because a frictionless surface is unable to provide reaction which is necessary for jumping.
Q.49 Automobile tyres are generally provided with irregular projections over their surfaces. Why?

Answer: Irregular projections increase the friction between the rubber tyres and the road. This provides a firm grip between the tyres and the road and prevents slipping.
Q.50 Carts with rubber tyres are easier to fly than those with iron wheels. Why?

Answer: The coefficient of friction between rubber tyres and road is much smaller than that between iron wheels and the road.

Q.51 Sand is thrown on tracks covered with snow. Why?
Answer:
When tracks are covered with snow, there is considerable reduction of frictional force. So, the driving is not safe. When sand is thrown on the snow-covered tracks, the frictional force increases. So, safe driving is possible.
Q.52 Why are wheels of automobiles made circular?

Answer: Circular wheels roll on the road and rolling friction comes into play during the motion of automobile. Rolling friction is less than the sliding friction. It is due to this reason that wheels of automobiles are made circular.
Q.53 Proper inflation of tyres of vehicles saves fuel. Why?
Answer: 
When the tyre is properly inflated, the area of contact between the tyre and the ground is reduced. This reduces rolling friction. Consequently, the auto- mobile covers greater distance for the same quantity of fuel consumed.
Q.54 It is difficult to move a cycle along a road with its brakes on. Explain?  
Answer
: When the cycle is moved with brakes on, the wheels can only skid. So, the friction is sliding in nature. Since the sliding friction is greater than rolling friction, therefore, it is difficult to move a cycle with its brakes on.
Q.55 A large size brake on bicycle is as effective as small one. Comment.

Answer: Action of brakes is based upon friction. But the friction is independent of the area of surfaces in contact so long as the normal reaction remains the same. Hence, large size brakes and normal size trakes will be equally effective if the material of brakes remains unchanged.
Q.56 Why is it difficult to put a cycle into motion than to maintain its motion?
Answer:
To put a cycle into motion, one needs to overcome limiting friction while to maintain its motion, one needs to overcome kinetic friction. Limiting friction is greater than the kinetic friction. So it is difficult to put a cycle into motion than to maintain its motion.
Q.57 How does friction help us in walking?
Answer:
Due to friction, we are able to push the ground backward during walking. The reaction of the ground helps us to move forward.
Q.58 Why do we slip on a rainy day?
Answer:
On a rainy day, the wet ground becomes very smooth. The friction between our feet and the ground is greatly reduced. It causes us to slip.
Q.59 Why is it difficult to walk on sand?
Answer:
Because of its yielding nature, sand cannot exert as much forward thrust as hard ground does.
Q.60 Why fictional force gets increased when a surface is polished beyond a certain limit?

Answer: When surfaces are highly polished, the area of contact between them increases. As a result of this, a large number of atoms and molecules lying on both the surfaces start exerting strong attractive forces on each other and therefore frictional force increases.
Q.61 When a person walks on a rough surface, the frictional force exerted by the surface on the person is opposite to direction of his motion. State whether it true or false?

Answer: False. When a person walks, he pushes the ground backward with his foot. The tendency of the foot when it is in the contact of the earth is to move backward. Hence the force of friction acts in the forward direction, i.e., in a direction in which the man walks.
Q.62 Why has a horse to pull a cart harder during the first few steps of his motion? Or A horse has to apply more force to start a cart than to keep it moving. Why?

Answer: During the first few steps of his motion, the horse has to work against the limiting friction and once the cart starts moving, the horse has to work against kinetic friction which is less than limiting friction.
Q.63 Is it unreasonable to expect the coefficient of friction to exceed unity?

Answer: No. The coefficient is less than unity for normal plane surfaces. But when the surfaces are so irregular that they have sharp minute projections and cavities on them, then the coefficient of friction may exceed unity.
Q.64 Is friction a non-conservative force?

Answer: Yes. When the direction of motion of a body reverses, the direction of friction is also reversed. Work has 1 to be done against friction both during forward and return journey i.e., work done against friction along a closed path is not zero. So friction is a non-conservative force.
Q.65 For uniform circular motion, does the direction of centripetal force depend on the sense of rotation?

Answer: No. Whether a body revolves clockwise or anticlockwise, the centripetal force always acts along the radius towards the centre of the circle.
Q.66 A stone tied at the end of a string is whirled in a circle. When the string breaks, the stoneflies away tangentially? Explain why.
Answer: 
The instantaneous velocity of the stone moving round the circle is along the tangent to the circular path. When the string breaks, the centripetal force vanishes. Due to the inertia of motion, the stone flies away tangentially.
Q.67 Why does a child in a merry-go-round press the side of his seat radially outward?

Answer: In accordance with Newton's third law, the seat will press the child inward, providing the necessary centripetal force.
Q.68 Why does skidding takes place generally on a rainy day along a curved path?
Answer:
The force of friction between the road and the tyres of the vehicle may not be sufficient to provide the necessary centripetal force.
Q.69 A car is taking a sudden turn to the left. A passenger in the front seat finds himself sliding towards the door. Explain, indicating the forces acting on the passenger and the car at this instant.
Answer:
The passenger in the front seat slides towards the door i.e., away from the circular turn. This is because of the centrifugal force acting on the passenger.
Q.70 The outer rail of a curved railway track is generally raised over the inner. Why?
Answer:
When the outer rail of a curved railway track is raised over the inner, the horizontal component of the normal reaction of the rails provides the necessary centripetal force for the train to enable it move along the curved path.
Q.71 A motor cyclist is going in a vertical circle. What is the necessary condition so that he may not fall down?

Answer: The necessary condition that the motor cyclist may not fall down is mυ2/r≥ mg i.e., υ≥Short & Long Answer Questions: Laws of Motion | Physics for ACT at the highest point and Short & Long Answer Questions: Laws of Motion | Physics for ACT at the lowest point.
Q.72 A bucket containing water is rotated in a vertical circle. Explain, why the water does not fall.
Answer: For its revolution in a vertical circle, water [n the bucket needs a centripetal force. The weight of the water due to which water can fall is used up in providing the necessary centripetal force and the water does not fall.
Q.73 Why does a pilot looping a vertical loop lot fall down even at the highest point?

Answer: At the highest point of the vertical loop, the weight of the pilot due to which he can fall is used up in providing him the necessary centripetal force.
Q.74 What is the maximum possible velocity at the lowest position for oscillation of a simple pendulum of length L. What can happen to the motion if the velocity exceeds this value?

Answer: The maximum possible velocity at the lowest point for oscillation of simple pendulum = Short & Long Answer Questions: Laws of Motion | Physics for ACT When velocity exceeds Short & Long Answer Questions: Laws of Motion | Physics for ACT but is less than  Short & Long Answer Questions: Laws of Motion | Physics for ACT the bob leaves the vertical circle. When υ= Short & Long Answer Questions: Laws of Motion | Physics for ACT the bob completes the vertical circle.
Q.75 A cricket player lowers his hands to catch the ball safely. Explain, why?
Answer:
The impulse is equal to the product of the force exerted by the ball and the time of catch. By lowering the hands, the time of catch increases. Then the force exerted on the hands becomes much smaller and it does not hurt the cricketer.
Q.76  It is easy to catch a table tennis ball than a cricket ball even both are moving with same velocity. Why?
Answer:
Due to its small mass, the momentum of the table tennis ball is much smaller than that of the cricket ball of same velocity. Less force is required to stop the table tennis ball than the cricket ball. Hence it is easy to catch the table tennis ball than the cricket ball.
Q.77  Why does a cyclist bend inwards while riding along a curved road?

Answer: A cyclist bends inwards because then the horizontal component of the normal reaction of the ground provides the necessary centripetal force for going along the curved road.
Q.78 The motion of a particle of mass m is described by y=ut+1/2gt2  Find the force acting on the particle.

Answer: We have y=ut+1/2gt2 Velocity, Short & Long Answer Questions: Laws of Motion | Physics for ACT Acceleration, 

Short & Long Answer Questions: Laws of Motion | Physics for ACT F=ma=mg Thus the given equation describes the motion of a particle under acceleration due to gravity and y is the position coordinate in the direction of g.
Q.79 A particle of mass 0.3 kg is subjected to a force of F=−kx with k=15Nm−1. What will be its initial acceleration, if it is released from a point 20 cm away from the origin?
Answer:
Here k=15Nm−1, x=20cm=0.20m,m=0.3kg F=−kx=15×0.20=−3N Acceleration,     a  Short & Long Answer Questions: Laws of Motion | Physics for ACT
Q.80  block of mass M is pulled along a horizontal frictionless surface by a rope of mass m. A force P is applied at the free end of the rope. Find the force exerted by the rope on the block.
Answer: If a is the acceleration produced, then P=(M+m)a   or a=Short & Long Answer Questions: Laws of Motion | Physics for ACT Force exerted by the rope on the block F=Ma= Short & Long Answer Questions: Laws of Motion | Physics for ACT
Q.81 Three forces F1,Fand F3 are acting on a particle of mass m, such that F2 and F3 are mutually perpendicular and under their effect, the particle remains stationary. What will be the acceleration of the particle, if the force F1 is removed?
Answer: As the particle remains stationary under the action of the three forces, so Short & Long Answer Questions: Laws of Motion | Physics for ACT When force Short & Long Answer Questions: Laws of Motion | Physics for ACT is removed, the net force left is Short & Long Answer Questions: Laws of Motion | Physics for ACT Acceleration, a=−Short & Long Answer Questions: Laws of Motion | Physics for ACT
Q.82 A spring balance is attached to the ceiling of a lift. A man hangs his bag on the spring and the spring reads 49 N, when the lift is stationary. What will be the reading of the spring balance, if the lift moves downward with an acceleration of 5ms−2.

Answer: When the lift is stationary. The reaction of the spring is equal to weight of the bag. ∴  R=mg=49N or m Short & Long Answer Questions: Laws of Motion | Physics for ACT When the lift moves downward. The reaction is R′=m(g−a)=5(9.8−5)=24N.
Q.83 Why does Newton's first law of motion appear to be contradicted in our day-to-day life?

Answer: In our day-to-day observations, we find that when we push a block lying on the surface of a table, it covers some distance before it stops. At first sight, it seems to contradict Newton's first law of motion. However, the motion of the block is being opposed by the force of friction between the block and the table and also by air resistance. In the absence of such opposing forces, the block would continue to move on its own.
Q.84 Explain, why (a) The passengers are thrown forward from their seats, when a speeding bus stops suddenly. (b) Does a cricketer move his hand backwards while holding a catch? (c) Is the boat pushed away when a man jumps out of the boat?

Answer: (a) This is due to inertia of motion. When the speeding bus stops suddenly, lower part of the body in contact with the seat stops. The upper part of the body of the passengers tends to maintain its uniform motion. Hence the passengers are thrown forward. 

(b) When the ball is caught, the impulse received by the hands is equal to the product of the force exerted by the ball and the time taken to complete the catch. By moving the hands backwards, the cricketer increases the time of catch. The force exerted on his hands becomes much smaller and it does not hurt him.

(c) Initially, the total momentum of the boat and the man is zero. As the man jumps out of the boat, he gains momentum in the forward direction. To conserve momentum, the boat also gains an equal and opposite momentum. So the boat moves away from the shore.
Q.85 Explain: (a) Why are ball bearings used in machinery? (b) Why does a horse have to apply more force to start a cart than to keep it moving? (c) What is the need for banking the tracks?

Answer: (a) By using ball bearings between the moving parts of a machinery, the sliding friction gets converted into rolling friction. The rolling friction is much smaller than sliding friction. This reduces power dissipation.

(b) During the first few steps of his motion, the horse has to work against the limiting friction and once the cart starts moving, the horse has to work against kinetic friction which is less than limiting friction. 

(c) When the circular track is banked, the horizontal component of the normal reaction of the road provides the necessary centripetal force for the vehicle to move it along the curved path. This reduces wear and tear of the tyres.
Q.86 The speed of driving a car safely depends upon the range of headlight. Explain.

Answer: By the range of the headlight of a car, we mean the maximum distance(s) up to which an obstacle on the road can be seen by the driver in the darkness. The driver has to stop the car before it reaches the obstacle. The retarding force acting on the car is constant. If, on applying brakes, the retardation in the car is a, then to stop the car within distance s, the speed υ of the car should be less thanShort & Long Answer Questions: Laws of Motion | Physics for ACT. Thus the speed of the car depends on the range (s) of the headlight.
Q.87 A bird is sitting on the floor of a closed glass cage and the cage is in the hand of a girl. Will the girl experience any change in the weight of the cage when the bird (i) starts flying in the cage with a constant velocity (ii) flies upwards with acceleration (iii) flies downwards with acceleration?

Answer: In a closed cage, the inside air is bound with the cage. 

(i) As the acceleration is zero, there is no change m the weight of the cage. 

(ii) In this case, the reaction R is given by R−Mg=Ma or R=M(g+a) Thus the cage will appear heavier than before. 

(iii) In this case, the reaction R is given by Mg−R=Ma or R=M(g−a) Thus the cage will appear lighter than before.
Q.88 A man stands in a lift going downward with uniform velocity. He experiences a loss of weight at the start but not when lift is in uniform motion. Explain why?

Answer: The apparent weight is given by R=W−ma=mg−ma or R=m(g−a) Since lift is in acceleration in the start, a≠0, so R<mg.When lift comes in uniform motion, acceleration ceases (a=0) and man experiences his own weight.
Q.89 Aeroplanes having wings fly at low altitudes while jet planes fly at high altitudes. Why?
Answer:
The wings of the aeroplane push the external air backward and the aeroplane moves forward by the reaction of the pushed air. At lower altitude the air is dense and so the aeroplane receives sufficient reactional force to move forward. In the jet plane the external air is sucked into the plane and compressed. Hence for the air to be dense is not only unnecessary but also undesirable. The reason is that jet planes fly with very large velocity. If air is dense, then due to the air-friction the plane will become very hot. Therefore, jet planes fly at high altitude where air-density is very small.
Q.90 A person (mass m) is hanging from a rope fastened to a stationary balloon (mass M). If the person climbs along the rope, then with what velocity the balloon will move and in what direction? The velocity of the person relative to the rope is υ.

Answer: The initial momentum of the person and balloon is zero. Hence when the person climbs, the balloon will come down with such a velocity υ that the total momentum be still zero. The velocity of the person dative to earth is (υ−u). Hence                
m(υ−u)−Mu=0 or u=Short & Long Answer Questions: Laws of Motion | Physics for ACT
Q.91 A long rope is hanging, passing over a pulley. Two monkeys of equal weights climb up from the opposite ends of the rope. One of them climbs up more rapidly relative to rope. Which monkey will reach first at the top? The pulley is frictionless and the rope is massless and inextensible.
Answer: 
There is no external force which may provide momentum to any monkey. The monkeys themselves give equal momenta to each other (through the rope). Therefore, two monkeys will climb up the rope at the same rate relative to the earth. As their masses are equal, they will reach the top simultaneously.
Q.92 When a ball is thrown upward, its momentum first increases and then decreases. Is the conservation of momentum violated in this process?
Answer
: No. The combined momentum of the ball and the earth is conserved. The ball attracts the earth by the same force as the earth attracts the ball. When the ball moves upward, its momentum decreases in the upward direction but simultaneously the momentum of the earth increases in the upward direction at the same rate. Similarly, when the ball falls down, its momentum increases in the downward direction but simultaneously the momentum of the earth increases in the upward direction at the same rate.
Q.93 A disc of mass m is placed on a table. A stiff spring is attached to it and is vertical. To the other end of the spring is attached a disc of negligible mass.  What minimum force should be applied to the upper disc to press the spring such that the lower disc is lifted off the table when the external force is suddenly removed?

Answer: The minimum applied force should be mg. When a force mg is applied vertically downwards on the upper disc, the lower disc gets pressed against the floor with a force equal to mg. The floors exerts an upward reaction equal to mg. When the external force is suddenly removed, this force of reaction lifts up the lower disc.
Q.94 Can a single isolated force exist in nature? Give reason.

Answer: No. According to Newton's third law of motion, to every action there is always an equal and opposite reaction. So the forces always exist in pairs. When we talk of a single force, we are just considering only one aspect of the mutual interaction.
Q.95 A body is dropped from the ceiling of a transparent cabin falling freely towards the earth. Describe the motion of the body as observed by an observer (i) sitting in the cabin (ii) standing on the earth.

Answer: (i) The body will appear stationary in air. (ii) The body will appear falling freely under gravity.
Q.96 A ball is suspended by a cord from the ceiling of a motor car. What will be the effect on the position of the ball if (i) the car is moving with uniform velocity (ii) the car is moving with accelerated motion and (iii) the car is turning towards right?
Answer:
(i)The ball will remain suspended vertically. (ii) The ball will move in backward direction. (iii) The ball will move towards left.
Q.97 When brakes are applied in a bicycle, the brake shoes apply frictional force on the wheels. The forces are internal for the system (bicycle). For retardation, external forces must act on the system. The force of friction at the road surface remains the same before and after the brakes are applied(f=μR). How does the bicycle stop?
Answer:
When brakes are applied, the wheels are prevented from rolling. During rolling, the friction at the road surface does not cause retardation. When rolling is prevented, the wheels have to slip on the road. The friction of the road now causes retardation.
Q.98 A light string passing over a smooth pulley connects two blocks of masses m1 and m2 (vertically). If the acceleration of the system is g/8,find the ratio of the two masses.
Answer: 
Short & Long Answer Questions: Laws of Motion | Physics for ACT Short & Long Answer Questions: Laws of Motion | Physics for ACT or Short & Long Answer Questions: Laws of Motion | Physics for ACT or 

Short & Long Answer Questions: Laws of Motion | Physics for ACT or Short & Long Answer Questions: Laws of Motion | Physics for ACT 

The document Short & Long Answer Questions: Laws of Motion | Physics for ACT is a part of the ACT Course Physics for ACT.
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FAQs on Short & Long Answer Questions: Laws of Motion - Physics for ACT

1. What are the three laws of motion?
Ans. The three laws of motion, also known as Newton's laws of motion, are as follows: 1. The first law, also known as the law of inertia, states that an object at rest will stay at rest, and an object in motion will stay in motion unless acted upon by an external force. 2. The second law states that the acceleration of an object is directly proportional to the net force applied to it and inversely proportional to its mass. It can be mathematically represented as F = ma, where F is the force, m is the mass, and a is the acceleration. 3. The third law states that for every action, there is an equal and opposite reaction. This means that whenever an object exerts a force on another object, the second object exerts an equal and opposite force on the first object.
2. What is the law of inertia?
Ans. The law of inertia, also known as Newton's first law of motion, states that an object at rest will stay at rest, and an object in motion will stay in motion unless acted upon by an external force. In simpler terms, it means that an object will continue doing what it is already doing unless a force is applied to change its state of motion. This law is often summarized as "an object in motion tends to stay in motion, and an object at rest tends to stay at rest."
3. How is force related to acceleration?
Ans. According to Newton's second law of motion, force and acceleration are directly proportional to each other. The law states that the acceleration of an object is directly proportional to the net force applied to it and inversely proportional to its mass. Mathematically, this relationship can be expressed as F = ma, where F is the force, m is the mass of the object, and a is the acceleration. This means that if the force acting on an object increases, its acceleration will also increase, given that the mass remains constant.
4. Can an object be in motion without any force acting on it?
Ans. No, according to Newton's laws of motion, an object cannot be in motion without any force acting on it. The first law of motion states that an object at rest will stay at rest, and an object in motion will stay in motion unless acted upon by an external force. In the absence of any force, an object will either remain at rest or continue moving with a constant velocity (if it was already in motion). Therefore, to change the state of motion of an object or to initiate its motion, an external force is required.
5. How do Newton's laws of motion apply to everyday life?
Ans. Newton's laws of motion have various applications in everyday life. Some examples include: - The first law of motion explains why seat belts are necessary in cars. When a car suddenly stops, the passengers tend to continue moving forward due to their inertia. Seat belts provide the necessary force to restrain the passengers and prevent them from moving forward. - The second law of motion is applied in various sports activities. For example, throwing a ball with more force will result in greater acceleration, allowing it to travel a greater distance. - The third law of motion can be observed in activities like walking. When we walk, we push the ground backward with our feet, and the ground pushes us forward, propelling us in the opposite direction.
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