Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Physics-

General

Easy

Question

The kinetic energy of a particle continuously increase with time. Then

the magnitude of its linear momentum is increasing continuously
its height above the ground must continuously decrease
the work done by all forces acting on the particle must be positive
the resultant force on the particle must be parallel to the velocity at all times

The correct answer is: its height above the ground must continuously decrease

Related Questions to study

A particle moves in one dimensional field with total mechanical energy E. If potential energy of particle is $U left parenthesis x right parenthesis$ , then

A particle moves in one dimensional field with total mechanical energy E. If potential energy of particle is $U left parenthesis x right parenthesis$ , then

physics-General

A body of mass m is slowly halved up the rough hill by a force $h cross times F$ at which each point is directed along a tangent to the hill. Work done by the force

A body of mass m is slowly halved up the rough hill by a force $h cross times F$ at which each point is directed along a tangent to the hill. Work done by the force

physics-General

Simple pendulum $P subscript 1 end subscript$ and $P subscript 2 end subscript$ have lengths $l subscript 1 end subscript$ = 80 cm and $l subscript 2 end subscript$ = 100 cm. The bob are of masses $m subscript 1 end subscript$ and $m subscript 2 end subscript$ . Initially both are at rest in equilibrium position. If each of the bobs is given a displacement of 2cm, the work done is $W subscript 1 end subscript text and end text W subscript 2 end subscript$ respectively. Then,

Simple pendulum $P subscript 1 end subscript$ and $P subscript 2 end subscript$ have lengths $l subscript 1 end subscript$ = 80 cm and $l subscript 2 end subscript$ = 100 cm. The bob are of masses $m subscript 1 end subscript$ and $m subscript 2 end subscript$ . Initially both are at rest in equilibrium position. If each of the bobs is given a displacement of 2cm, the work done is $W subscript 1 end subscript text and end text W subscript 2 end subscript$ respectively. Then,

physics-General

parallel

The upper half of an inclined plane with inclination q is perfectly smooth while the lower half is rough. A body starting from rest at the top will again come to rest at the bottom if the coefficient of friction for the lower half is given by

The upper half of an inclined plane with inclination q is perfectly smooth while the lower half is rough. A body starting from rest at the top will again come to rest at the bottom if the coefficient of friction for the lower half is given by

physics-General

A particle is projected along the inner surface of a smooth vertical circle of radius R, its velocity at the lowest point being $fraction numerator 1 over denominator 5 end fraction square root of 95 R g end root$ It will leave the circle at an angular distance .... from the highest point.

A particle is projected along the inner surface of a smooth vertical circle of radius R, its velocity at the lowest point being $fraction numerator 1 over denominator 5 end fraction square root of 95 R g end root$ It will leave the circle at an angular distance .... from the highest point.

physics-General

The potential energy for the force $stack F with rightwards arrow on top equals y z stack i with hat on top plus x z stack j with hat on top plus x y stack k with hat on top$ if the zero of the potential energy is to be chosen at the point (2, 2, 2) is

The potential energy for the force $stack F with rightwards arrow on top equals y z stack i with hat on top plus x z stack j with hat on top plus x y stack k with hat on top$ if the zero of the potential energy is to be chosen at the point (2, 2, 2) is

physics-General

parallel

Consider a roller coaster with a circular loop. A roller coaster car starts from rest from the top of a hill which is 5 m higher than the top of the loop. It rolls down the hill and through the loop. What must the radius of the loop be so that the passengers of the car will feel at highest point, as if they their normal weight ?

Consider a roller coaster with a circular loop. A roller coaster car starts from rest from the top of a hill which is 5 m higher than the top of the loop. It rolls down the hill and through the loop. What must the radius of the loop be so that the passengers of the car will feel at highest point, as if they their normal weight ?

physics-General

A pendulum bob of mass m is suspended at rest. A constant horizontal force $F equals m g divided by 2$ starts acting on it. The maximum angular deflection of the string is

A pendulum bob of mass m is suspended at rest. A constant horizontal force $F equals m g divided by 2$ starts acting on it. The maximum angular deflection of the string is

physics-General

4 A car is moving along a hilly road as shown (side view). The coefficient of static friction between the tyres and pavement is constant and the car maintains a steady speed. If, at one of the points shown the driver applies the brakes as hard as possible without making the tires slip, the magnitude of the frictional force immediately after the brakes are applied will be maximum if the car was at

4 A car is moving along a hilly road as shown (side view). The coefficient of static friction between the tyres and pavement is constant and the car maintains a steady speed. If, at one of the points shown the driver applies the brakes as hard as possible without making the tires slip, the magnitude of the frictional force immediately after the brakes are applied will be maximum if the car was at

physics-General

parallel

One end of a light rope is tied directly to the ceiling. A man of mass M initially at rest on the ground starts climbing the rope hand over upto a height $l$ . From the time he starts at rest on the ground to the time he is hanging at rest at a height $l$ , how much work done on the man by the rope ?

One end of a light rope is tied directly to the ceiling. A man of mass M initially at rest on the ground starts climbing the rope hand over upto a height $l$ . From the time he starts at rest on the ground to the time he is hanging at rest at a height $l$ , how much work done on the man by the rope ?

physics-General

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x. $blank x greater or equal than fraction numerator mu m g over denominator k end fraction$ Let $F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript text and end text F subscript m i n end subscript$ = 2 N. Also shown is the variation of $text Fmax+ end text text Fmin end text text versus end text x$ , the elongation of the spring The value of $F subscript m i n end subscript$ , if x = 3 cm is :

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x. $blank x greater or equal than fraction numerator mu m g over denominator k end fraction$ Let $F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript text and end text F subscript m i n end subscript$ = 2 N. Also shown is the variation of $text Fmax+ end text text Fmin end text text versus end text x$ , the elongation of the spring The value of $F subscript m i n end subscript$ , if x = 3 cm is :

physics-General

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x. $blank x greater or equal than fraction numerator mu m g over denominator k end fraction$ Let $F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript minus F subscript m i n end subscript$ = 2 N. Also shown is the variation of $text Fmax+ end text text Fmin end text text versus end text x$ , the elongation of the spring The spring constant of the spring is:

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x. $blank x greater or equal than fraction numerator mu m g over denominator k end fraction$ Let $F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript minus F subscript m i n end subscript$ = 2 N. Also shown is the variation of $text Fmax+ end text text Fmin end text text versus end text x$ , the elongation of the spring The spring constant of the spring is:

physics-General

parallel

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x $x greater or equal than fraction numerator mu m g over denominator k end fraction text Let end text F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript minus F subscript m i n end subscript equals 2 N$ . Also shown is the variation of Fmax+ Fmin versus x, the elongation of the spring The coefficient of friction between the block and the horizontal surface is :

A block of mass 1 kg is placed on a rough horizontal surface. A spring is attached to the block whose other end is joined to a rigid wall,as shown in the figure. A horizontal force is applied on the block so that it remains at rest while the spring is elongated by x $x greater or equal than fraction numerator mu m g over denominator k end fraction text Let end text F subscript m a x end subscript text and end text F subscript m i n end subscript$ be the maximum and minimum values of force F for which the block remains in equilibrium. For a particular x, $F subscript m a x end subscript minus F subscript m i n end subscript equals 2 N$ . Also shown is the variation of Fmax+ Fmin versus x, the elongation of the spring The coefficient of friction between the block and the horizontal surface is :

physics-General

Two bodies A and B of masses 10 kg and 5 kg are placed very slightly separated as shown in figure. The coefficients of friction between the floor and the blocks are as $mu subscript s end subscript equals mu subscript k end subscript equals 0.4$ . Block A is pushed by an external force F. The value of F can be changed. When the welding between block A and ground breaks, block A will start pressing block B and when welding of B also breaks, block B will start pressing the vertical wall If F = 50 N, the friction force acting between block B and ground will be :

Two bodies A and B of masses 10 kg and 5 kg are placed very slightly separated as shown in figure. The coefficients of friction between the floor and the blocks are as $mu subscript s end subscript equals mu subscript k end subscript equals 0.4$ . Block A is pushed by an external force F. The value of F can be changed. When the welding between block A and ground breaks, block A will start pressing block B and when welding of B also breaks, block B will start pressing the vertical wall If F = 50 N, the friction force acting between block B and ground will be :

physics-General

Two bodies A and B of masses 10 kg and 5 kg are placed very slightly separated as shown in figure. The coefficients of friction between the floor and the blocks are as $mu subscript s end subscript equals mu subscript k end subscript equals 0.4$ . Block A is pushed by an external force F. The value of F can be changed. When the welding between block A and ground breaks, block A will start pressing block B and when welding of B also breaks, block B will start pressing the vertical wall $minus$ If $F equals 20 N$ , with how much force does block A presses the block B

Two bodies A and B of masses 10 kg and 5 kg are placed very slightly separated as shown in figure. The coefficients of friction between the floor and the blocks are as $mu subscript s end subscript equals mu subscript k end subscript equals 0.4$ . Block A is pushed by an external force F. The value of F can be changed. When the welding between block A and ground breaks, block A will start pressing block B and when welding of B also breaks, block B will start pressing the vertical wall $minus$ If $F equals 20 N$ , with how much force does block A presses the block B

physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.