Part (a) To Determine: Expressions for Magnetic fields inside a toroid

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Answer 1

Question

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Expert Solution & Answer

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Check out a sample textbook solution

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Answer 2

Question

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 3

Question

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 4

Question

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 5

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Answer 6

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

Answer 7

Chapter 20, Problem 49P

To determine

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

Answer 8

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

Answer 9

To determine

To find magnetic field inside the toroid:

Consider a closed loop inside the toroid having radius r,

Let I be the current through the coil, then total current enclosed by the loop is given by,

$I_{e} = N I$ ……….. (eq.2)

Where,

N → Total number of turns of wire in toroid

I → Current through Coil

Then Ampere’s law for loop 1 can be written as,

$\oint B \cdot d l = μ_{0} N I$

Here B and elemental length dl are in same direction and magnetic field is uniform along toroid. Therefore we can write,

$B \oint d l = μ_{0} N I$ ……….. (eq.3)

Then,

$\oint d l = 2 π r_{}$

Appling on eq.3,

$B = \frac{μ_{0} N I}{2 π r_{}}$ ……….. (eq.4)

Answer 10

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

Answer 11

To determine

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

Answer 12

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

Answer 13

To determine

To find magnetic field outside the toroid:

Now consider a closed path outside the toroid as shown in figure.

It can be shown that total current enclosed by the loop, $I_{e} = 0$

Since the current coming outwards from the plane of paper is cancelled by current going into it.

Therefore, Eqn.1 can be written as

$\oint B \cdot d l = 0$

I.e. Magnetic field outside the toroid, B=0

Answer 14

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Answer 15

To determine

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Answer 16

Expert Solution & Answer

Answer 17

Expert Solution & Answer

Answer 18

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 19

Ch. 20 - Prob. 1OQ Ch. 20 - Prob. 1Q Ch. 20 - Prob. 2Q Ch. 20 - Prob. 3Q Ch. 20 - Prob. 4Q Ch. 20 - Prob. 5Q Ch. 20 - Two iron bars attract each other no matter which...Ch. 20 - Prob. 7Q Ch. 20 - Prob. 8Q Ch. 20 - Prob. 9Q

Part (a) To Determine: Expressions for Magnetic fields inside a toroid

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Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

Part (c) To Determine:

How magnetic fields inside a toroid if varies

Want to see the full answer?

Chapter 20 Solutions

Part (a) To Determine: Expressions for Magnetic fields inside a toroid

Videos

Part (a) To Determine: Expressions for Magnetic fields inside a toroid

Part (b) To Determine: Expressions for Magnetic fields outside a toroid

Part (c) To Determine: How magnetic fields inside a toroid if varies

Want to see the full answer?

Chapter 20 Solutions

Part (a) To Determine:

Expressions for Magnetic fields inside a toroid

Part (b) To Determine:

Expressions for Magnetic fields outside a toroid

Part (c) To Determine:

How magnetic fields inside a toroid if varies