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 diagram shows a solenoid carrying time varying current I = I₀ t (I₀ is constant) On the axis of this solenoid a conducting ring is being placed as shown in figure. The mutual inductance of the ring and the solenoid is M and self inductance of the ring is L. If the resistance of the ring is R then the maximum current which can flow through the ring is

$(2 M + L) \frac{I_{0}}{R}$
$\frac{M I_{0}}{R}$
$(2 M - L) \frac{I_{0}}{R}$
$(M + L) \frac{I_{0}}{R}$

The correct answer is: $fraction numerator M I subscript 0 end subscript over denominator R end fraction$

Related Questions to study

A solenoid is oriented end-on so that its opening is perpendicular to the circuit containing the two light bulbs as drawn in figure C1. For figure C2 and C3, a shorting wire of negligible resistance is added as shown. Assume that the magnetic field from the solenoid, shown coming out of the plane of the page, decreases uniformly with time at the same rate for each circuit. Rank the circuits for the brightness of the bulb labeled R1 from brightest to dimmest.

A solenoid is oriented end-on so that its opening is perpendicular to the circuit containing the two light bulbs as drawn in figure C1. For figure C2 and C3, a shorting wire of negligible resistance is added as shown. Assume that the magnetic field from the solenoid, shown coming out of the plane of the page, decreases uniformly with time at the same rate for each circuit. Rank the circuits for the brightness of the bulb labeled R1 from brightest to dimmest.

physics-General

A wire frame as shown in figure is made to rotate about a vertical axis passing through O. There exists a uniform horizontal magnetic field of induction B = 1 Tesla if $O A equals square root of 2 m & A B equals 2 m.$ If the frame rotates (slowly) about 'O' with angular velocity directed along Z-axis having magnitude w = 4rad/s, the potential difference between O & B is

A wire frame as shown in figure is made to rotate about a vertical axis passing through O. There exists a uniform horizontal magnetic field of induction B = 1 Tesla if $O A equals square root of 2 m & A B equals 2 m.$ If the frame rotates (slowly) about 'O' with angular velocity directed along Z-axis having magnitude w = 4rad/s, the potential difference between O & B is

physics-General

There exists a uniform but time varying magnetic field B = a + bt normal to plane of paper in a cylindrical region as shown. A rectangular conducting loop is placed as shown. Induced emf in branches AB and BC are

There exists a uniform but time varying magnetic field B = a + bt normal to plane of paper in a cylindrical region as shown. A rectangular conducting loop is placed as shown. Induced emf in branches AB and BC are

physics-General

parallel

In given figure, a wire loop has been bent so that it has three segments: segment ab (a quarter circle), bc (a square corner), and ca (straight). Here are three choices for a magnetic field through the loop:

$text 1) end text stack B with rightwards arrow on top subscript 1 end subscript equals 3 stack i with hat on top plus 7 stack j with hat on top minus 5 t stack k with hat on top comma text 2) end text stack B with rightwards arrow on top subscript 2 end subscript equals 5 t stack i with hat on top minus 4 stack j with hat on top minus 15 stack k with hat on top comma text 3) end text stack B with rightwards arrow on top subscript 3 end subscript equals 2 stack i with hat on top minus 5 stack t with hat on top minus 12 stack k with hat on top$
Where $stack B with rightwards arrow on top$ is in milliteslas and t is in seconds. If the induced current in the loop due to $stack B with rightwards arrow on top subscript 1 end subscript comma stack B with rightwards arrow on top subscript 2 end subscript text and end text stack B with rightwards arrow on top subscript 3 end subscript$ are $i subscript 1 end subscript comma i subscript 2 end subscript text and end text i subscript 3 end subscript$ respectively then

In given figure, a wire loop has been bent so that it has three segments: segment ab (a quarter circle), bc (a square corner), and ca (straight). Here are three choices for a magnetic field through the loop:

$text 1) end text stack B with rightwards arrow on top subscript 1 end subscript equals 3 stack i with hat on top plus 7 stack j with hat on top minus 5 t stack k with hat on top comma text 2) end text stack B with rightwards arrow on top subscript 2 end subscript equals 5 t stack i with hat on top minus 4 stack j with hat on top minus 15 stack k with hat on top comma text 3) end text stack B with rightwards arrow on top subscript 3 end subscript equals 2 stack i with hat on top minus 5 stack t with hat on top minus 12 stack k with hat on top$
Where $stack B with rightwards arrow on top$ is in milliteslas and t is in seconds. If the induced current in the loop due to $stack B with rightwards arrow on top subscript 1 end subscript comma stack B with rightwards arrow on top subscript 2 end subscript text and end text stack B with rightwards arrow on top subscript 3 end subscript$ are $i subscript 1 end subscript comma i subscript 2 end subscript text and end text i subscript 3 end subscript$ respectively then

physics-General

Three wire loops and an observer are positioned as shown in the figure. From the observer's point of view, a current I flows counterclockwise in the middle loop, which is moving towards the observer with a velocity v. Loops A and B are stationary. This same observer would notice that

Three wire loops and an observer are positioned as shown in the figure. From the observer's point of view, a current I flows counterclockwise in the middle loop, which is moving towards the observer with a velocity v. Loops A and B are stationary. This same observer would notice that

physics-General

At t = 0 a charge q is at the origin and moving in the y-direction with velocity $stack v with rightwards arrow on top equals v stack j with hat on top$ in a magnetic field that is for y > 0 out of page and given by $B subscript 1 end subscript stack z with hat on top text and for end text y less than 0$ into the page and given $negative B subscript 2 end subscript stack z with hat on top.$ The charge's subsequent trajectory is shown in the sketch. From this information, we can deduce that

At t = 0 a charge q is at the origin and moving in the y-direction with velocity $stack v with rightwards arrow on top equals v stack j with hat on top$ in a magnetic field that is for y > 0 out of page and given by $B subscript 1 end subscript stack z with hat on top text and for end text y less than 0$ into the page and given $negative B subscript 2 end subscript stack z with hat on top.$ The charge's subsequent trajectory is shown in the sketch. From this information, we can deduce that

physics-General

parallel

A conducting bar rolls down a slope made of conducting rails. The bottom ends of the rails are connected by another conducting rail as shown in the figure. There is a uniform magnetic field B pointing upward. Due to the bar's motion, there is an induced current in the bar-rail circuit. What is the direction of the magnetic force on the bar?

A conducting bar rolls down a slope made of conducting rails. The bottom ends of the rails are connected by another conducting rail as shown in the figure. There is a uniform magnetic field B pointing upward. Due to the bar's motion, there is an induced current in the bar-rail circuit. What is the direction of the magnetic force on the bar?

physics-General

A conducting rod AC of length 4l is rotated about a point O in a uniform magnetic field $stack B with rightwards arrow on top$ directed into the paper. AO = l and OC = 3l. Then

A conducting rod AC of length 4l is rotated about a point O in a uniform magnetic field $stack B with rightwards arrow on top$ directed into the paper. AO = l and OC = 3l. Then

physics-General

A capacitor of capacitance 0.1 $mu$ F is connected to a battery of emf 8V as shown in the fig. Under steady state condition

A capacitor of capacitance 0.1 $mu$ F is connected to a battery of emf 8V as shown in the fig. Under steady state condition

physics-General

parallel

In the circuit shown in the figure, switches S₁ and S₂ have been closed for a long time

In the circuit shown in the figure, switches S₁ and S₂ have been closed for a long time

physics-General

In the circuit shown, the charge on the 3 $mu$ F capacitor at steady state will be

In the circuit shown, the charge on the 3 $mu$ F capacitor at steady state will be

physics-General

The figure below shows four parallel plate capacitors : A, B, C and D. Each capacitor carries the same charge q and has the same plate area A. As suggested by the figure, the plates of capacitors A and C are separated by a distance d while those of B and D are separated by a distance 2d. Capacitors A and B are maintained in vacuum while capacitors C and D contain dielectrics with constant k = 5.

The figure below shows four parallel plate capacitors : A, B, C and D. Each capacitor carries the same charge q and has the same plate area A. As suggested by the figure, the plates of capacitors A and C are separated by a distance d while those of B and D are separated by a distance 2d. Capacitors A and B are maintained in vacuum while capacitors C and D contain dielectrics with constant k = 5.

physics-General

parallel

The figure below shows four parallel plate capacitors : A, B, C and D. Each capacitor carries the same charge q and has the same plate area A. As suggested by the figure, the plates of capacitors A and C are separated by a distance d while those of B and D are separated by a distance 2d. Capacitors A and B are maintained in vacuum while capacitors C and D contain dielectrics with constant k = 5.

Which list below places the capacitors in order of increasing capacitance?

The figure below shows four parallel plate capacitors : A, B, C and D. Each capacitor carries the same charge q and has the same plate area A. As suggested by the figure, the plates of capacitors A and C are separated by a distance d while those of B and D are separated by a distance 2d. Capacitors A and B are maintained in vacuum while capacitors C and D contain dielectrics with constant k = 5.

Which list below places the capacitors in order of increasing capacitance?

physics-General

Two identical capacitors 1 and 2 are connected in series. The capacitor 2 contains a dielectric slab of constant K as shown. They are connected to a battery of emf V0 volts. The dielectric slab is then removed. Let Q₁ and Q₂ be the charge stored in the capacitors before removing the slab and Q₁ ¢, and Q₂ ¢ be the values after removing the slab. Then

Two identical capacitors 1 and 2 are connected in series. The capacitor 2 contains a dielectric slab of constant K as shown. They are connected to a battery of emf V0 volts. The dielectric slab is then removed. Let Q₁ and Q₂ be the charge stored in the capacitors before removing the slab and Q₁ ¢, and Q₂ ¢ be the values after removing the slab. Then

physics-General

Its tangential acceleration at time 't' is

Its tangential acceleration at time 't' 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.