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

A conducting ring of mass 2 kg and radius 0.5 m is placed on a smooth horizontal plane. The ring carries a current i = 4A. A horizontal magnetic field B = 10T is switched on at time t = 0 as shown in figure. The initial angular acceleration of the ring will be

40 $π$ rad/s²
20 $π$ rad/s²
5 $π$ rad/s²
15 $π$ rad/s²

The correct answer is: 40 $pi$ rad/s²

Related Questions to study

In given figure, X and Y are two long straight parallel conductors each carrying a current of 2 A. The force on each conductor is F newtons. When the current in each is changed to 1 A and reversed in direction, the force on each is now

In given figure, X and Y are two long straight parallel conductors each carrying a current of 2 A. The force on each conductor is F newtons. When the current in each is changed to 1 A and reversed in direction, the force on each is now

physics-General

A square loop ABCD, carrying a current i, is placed near and coplanar with a long straight conductor XY carrying a current I, the net force on the loop will be

A square loop ABCD, carrying a current i, is placed near and coplanar with a long straight conductor XY carrying a current I, the net force on the loop will be

physics-General

In the figure shown a current I₁ is established in the long straight wire AB. Another wire CD carrying current I₂ is placed in the plane of the paper. The line joining the ends of this wire is perpendicular to the wire AB. The force on the wire CD is:

In the figure shown a current I₁ is established in the long straight wire AB. Another wire CD carrying current I₂ is placed in the plane of the paper. The line joining the ends of this wire is perpendicular to the wire AB. The force on the wire CD is:

physics-General

parallel

A circular current loop of radius a is placed in a radial field B as shown. The net force acting on the loop is

A circular current loop of radius a is placed in a radial field B as shown. The net force acting on the loop is

physics-General

A semi circular current carrying wire having radius R is placed in x-y plane with its centre at origin ‘O’. There is non-uniform magnetic field $stack B with rightwards arrow on top equals fraction numerator B subscript o end subscript x over denominator 2 R end fraction stack k with hat on top$ (here Bo is +ve constant) is existing in the region. The magnetic force acting on semi circular wire will be along

A semi circular current carrying wire having radius R is placed in x-y plane with its centre at origin ‘O’. There is non-uniform magnetic field $stack B with rightwards arrow on top equals fraction numerator B subscript o end subscript x over denominator 2 R end fraction stack k with hat on top$ (here Bo is +ve constant) is existing in the region. The magnetic force acting on semi circular wire will be along

Physics-General

A conducting wire bent in the form of a parabola y² = 2x carries a current i = 2 A as shown in figure. This wire is placed in a uniform magnetic field $stack B with rightwards arrow on top equals negative 4 stack k with hat on top$ Tesla. The magnetic force on the wire is (in newton)

A conducting wire bent in the form of a parabola y² = 2x carries a current i = 2 A as shown in figure. This wire is placed in a uniform magnetic field $stack B with rightwards arrow on top equals negative 4 stack k with hat on top$ Tesla. The magnetic force on the wire is (in newton)

physics-General

parallel

A straight rod of mass m and length L is suspended from the identical spring as shown in the figure. The spring stretched by a distance of x0 due to the weight of the wire. The circuit has total resistance RW. When the magnetic field perpendicular to the plane of the paper is switched on, springs are observed to extend further by the same distance. The magnetic field strength is

A straight rod of mass m and length L is suspended from the identical spring as shown in the figure. The spring stretched by a distance of x0 due to the weight of the wire. The circuit has total resistance RW. When the magnetic field perpendicular to the plane of the paper is switched on, springs are observed to extend further by the same distance. The magnetic field strength is

physics-General

A charged particle enters a uniform magnetic field perpendicular to its initial direction travelling in air. The path of the particle is seen to follow the path in figure. Which of statements 1–3 is/are correct? [1] The magnetic field strength may have been increased while the particle was travelling in air [2] The particle lost energy by ionising the air [3] The particle lost charge by ionising the air

A charged particle enters a uniform magnetic field perpendicular to its initial direction travelling in air. The path of the particle is seen to follow the path in figure. Which of statements 1–3 is/are correct? [1] The magnetic field strength may have been increased while the particle was travelling in air [2] The particle lost energy by ionising the air [3] The particle lost charge by ionising the air

physics-General

A particle moving with velocity v having specific charge (q/m) enters a region of magnetic field B having width $d equals fraction numerator 3 m v over denominator 5 q B end fraction$ at angle 53° to the boundary of magnetic field. Find the angle $theta$ in the diagram.

A particle moving with velocity v having specific charge (q/m) enters a region of magnetic field B having width $d equals fraction numerator 3 m v over denominator 5 q B end fraction$ at angle 53° to the boundary of magnetic field. Find the angle $theta$ in the diagram.

physics-General

parallel

A block of mass m & charge q is released on a long smooth inclined plane magnetic field B is constant, uniform, horizontal and parallel to surface as shown. Find the time from start when block loses contact with the surface.

A block of mass m & charge q is released on a long smooth inclined plane magnetic field B is constant, uniform, horizontal and parallel to surface as shown. Find the time from start when block loses contact with the surface.

physics-General

A particle having charge q enters a region of uniform magnetic field $stack B with rightwards arrow on top$ (directed inwards) and is deflected a distance x after travelling a distance y. The magnitude of the momentum of the particle is:

A particle having charge q enters a region of uniform magnetic field $stack B with rightwards arrow on top$ (directed inwards) and is deflected a distance x after travelling a distance y. The magnitude of the momentum of the particle is:

physics-General

The direction of magnetic force on the electron as shown in the diagram is along

The direction of magnetic force on the electron as shown in the diagram is along

physics-General

parallel

A particle with charge +Q and mass m enters a magnetic field of magnitude B, existing only to the right of the boundary YZ. The direction of the motion of the particle is perpendicular to the direction of B. Let $T equals 2 pi fraction numerator m over denominator Q B end fraction$ The time spent by the particle in the field will be

A particle with charge +Q and mass m enters a magnetic field of magnitude B, existing only to the right of the boundary YZ. The direction of the motion of the particle is perpendicular to the direction of B. Let $T equals 2 pi fraction numerator m over denominator Q B end fraction$ The time spent by the particle in the field will be

physics-General

Two waves of lengths 50 cm and 51 cm produced 12 beats per second The velocity of sound is

Two waves of lengths 50 cm and 51 cm produced 12 beats per second The velocity of sound is

Physics-General

The wave equation is y = 0.30 sin (314 t -1.57 x) where t, x and y are in second, meter and centimeter respectively The speed of the wave is

The wave equation is y = 0.30 sin (314 t -1.57 x) where t, x and y are in second, meter and centimeter respectively The speed of the wave is

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.