Magnetic Field on the Axis of a Circular Current Loop: Introduction & Derivation

Jasmine Grover Content Strategy Manager

Content Strategy Manager

Magnetic field is generated when there is a conductor carrying current. This phenomenon was elucidated through Biot-Savart Law. Biot-Savart Law states that if a current-carrying conductor of length dl produces a magnetic field dB, the force on another similar current carrying conductor depends upon the size, orientation and length of the first current carrying element. The equation of Biot-Savart law is given by,

\(dB = \frac{\mu_0}{4\pi} \frac{Idl sin \theta}{r^2}\)

Here, the current element is a vector quantity. The Magnetic field at the axis of a current-carrying loop can either be derived through Biot-Savart Law or Ampere Circuital law. In this article, we shall look into the derivation of the magnetic field at the axis of a current-carrying loop.

Table of Content

Magnetic Field at the Axis of a Current-Carrying Loop Derivation
Things to Remember
Sample Questions

Key Terms: Magnetic Field, Biot-Savart Law, Current Carrying Loop, Displacement Vector, Ampere circuital law, Conductor, Phenomenon

Magnetic Field at the Axis of a Current-Carrying Loop Derivation

[Click Here for Sample Questions]

Consider a circular loop carrying a stable current I as shown in the figure. The loop is located in the y-z plane with its Centre at the source O also radius R. The X axis is the alignment of the circle. We compute the magnetic field at the point P on this axis. Let x denote the distance of P from the Centre O of the loop.

Circular Loop carrying a Stable Current

Circular Loop carrying a Stable Current

From the figure, r² = x² + R²

Consider a very small conducting element ‘dl’ of the loop. The magnitude dB of the magnetic field due to dl is specified by the Biot-Savart law.

If we consider a conducting element dl of the loop, the magnetic field at point P can be given by Biot Savart Law:

\(dB = \frac{\mu_0}{4\pi} \frac{I |dl \times r|} {r^3}\)

As explained, r² = x² + R²

Also, any element on the loop is perpendicular to the displacement vector on the X-axis. This is because they are in different planes. Hence, |dl x r| = rdl. So the formula given above becomes :

\(dB = \frac{\mu_0}{4\pi} \frac{Idl} {(x^2 +R^2)}\)--------(1)

This calculated dB is shown in the figure as well. It has two components, dB_xand dB_y. The component perpendicular to the X axis cancels each other because the field is generated from a loop and the diametrically opposite element dl will cancel out the vertical component. The net contribution along the x-direction can be obtained by integrating dB_x = dB cos θ over the loop.

Read More:

Physics Practicals
Potentiometer Experiment	Converting Galvanometer Into Ammeter	Converting Galvanometer Into Voltmeter
Determine Equivalent Resistance of Resistors	Determine Minimum Deviation for given Prism	Determine Refractive Index of a Glass Slab
Determine the Internal Resistance of a given Primary Cell	Drawing the i v characteristic Curve for p n junction	Finding focal length of concave lens using convex lens
Finding resistance of given wire using metre bridge	Finding v value for different u values of concave mirror	Characteristics of common emitter of npn or pnp transistor

\(cos \theta= \frac{R} {(x^2 +R^2)^{\frac{1}{2}}}\)--------(2)

From equations (1) and (2),

\(dB_x = \frac{\mu_0 Idl}{4\pi} \frac{R} {(x^2 +R^2)^{\frac{3}{2}}}\)

Since dl is a small element of a circular loop, the summation of dl leads to 2πR, the loop circumference. The magnetic field thus becomes:

\(B =B_xi = \frac{\mu_0 IR^2}{2(x^2 +R^2)^\frac{3}{2}} i\)

Special Case: As a special case, when x = 0, we get the magnetic field at the center of the current-carrying loop. The formula is given below:

\(B= \frac{\mu_0 I}{2R} \hat{i}\)

The magnetic field lines are illustrated in the figure below.

Magnetic Field Lines

Magnetic Field Lines

Read More:

Related Topics
Magnetic Spectrum	Faraday's Law	Magnetic Properties of Materials
Magnetization and Magnetic Intensity	NCERT Solutions Chapter 4 Moving Charges and Magnetism	Gauss’s Law
Magnetism and Matter	Magnetic Properties	Moving Charges and Magnetism
Applications of Gauss’s Law	Earth’s Magnetic field	Force multiple charges

Things to Remember

Magnetic field is generated when there is a conductor carrying current.
Biot-Savart Law states that if a current carrying conductor of length dl produces a magnetic field dB, the force on another similar current carrying conductor depends upon the size, orientation and length of the first current carrying element.
Magnetic field at the axis of a current carrying loop can either be derived through Biot-Savart Law or Ampere Circuital law.

Also Read:

Important Chapter Related Links
Solenoid and Toroid	Universal Motor	Velocity Selector
Angular Momentum of Electron	Electricity and Magnetism	Relation between gauss and tesla
The Moving Coil Galvanometer	The Solenoid and the Toroid	Derivation of Biot Savart Law
Gauss Rifle	Mu Naught Value	Parallel current carrying conductor

Sample Questions

Ques. Draw the magnetic field lines due to a current-carrying loop. (CBSE Delhi 2013 C) (1 Mark)

Ans. The field lines are constructed according to the right-hand thumb rule. The drawing is given below:

Ques. What is the formula for magnetic field lines due to a current-carrying loop. (1 Mark)

Ans. The formula for magnetic fields due to a current carrying loop is given by,

\(B =B_xi = \frac{\mu_0 IR^2}{2(x^2 +R^2)^\frac{3}{2}} i\)

Ques. Two identical circular loops P and Q, each of radius r and carrying equal currents are kept in the parallel planes having a common axis passing through O. The direction of current in P is clockwise and in Q is anti-clockwise as seen from O which is equidistant from the loops P and Q. Find the magnitude of the net magnetic field at O. (CBSE Delhi 2012) (3 Marks)

Ans. The answer is as follows:

Ans. The answer is as follows:

Ques. A circular coil of radius R carries a current /. Write the expression for the magnetic field due to this coil at its centre. Find out the direction Of the field. (All India 2008 C) (5 Marks)

Ans.

Circular Loop carrying a Stable Current

Consider a very small conducting element ‘dl’ of the loop. This is given in the above figure. The magnitude dB of the magnetic field due to dl is specified by the Biot-Savart law.

If we consider a conducting element dl of the loop, the magnetic field at point P can be given by Biot Savart Law:

\(dB = \frac{\mu_0}{4\pi} \frac{I |dl \times r|} {r^3}\)

r^₂ = x² + R²

Also, any element on the loop is perpendicular to the displacement vector on the X-axis. This is because they are in different planes. Hence, |dl x r| = rdl. So the formula given above becomes :

\(dB = \frac{\mu_0}{4\pi} \frac{Idl} {(x^2 +R^2)}\)-----------------(1)

This calculated dB is shown in the figure as well. It has 2 components, dBx and dBy. The component perpendicular to the X axis cancel each other (Because the field is generated from a loop and the diametrically opposite element dl will cancel out the vertical component). The net contribution along x-direction can be obtained by integrating dBx = dB cos θ over the loop.

\(cos \theta= \frac{R} {(x^2 +R^2)^{\frac{1}{2}}}\)-----------------(2)

From equations (1) and (2),

\(dB_x = \frac{\mu_0 Idl}{4\pi} \frac{R} {(x^2 +R^2)^{\frac{3}{2}}}\)

Since dl is a small element of a circular loop, summation of dl leads to 2πR, the loop circumference. The magnetic field thus becomes:

\(B =B_xi = \frac{\mu_0 IR^2}{2(x^2 +R^2)^\frac{3}{2}} i\)

Special Case : As a special case, when x = 0, we get the magnetic field at the center of the current carrying loop. The formula is given below:

\(B= \frac{\mu_0 I}{2R} \hat{i}\)

Ques. Two very small identical circular loops (1) and (2) carrying equal current I am placed vertically (with respect to the plane of the paper) with their geometrical axes perpendicular to each other as shown in the figure. Find the magnitude and direction of the net magnetic field produced at the point O. (CBSE Delhi 2014) (5 Marks)

Ans. The magnetic field due to a circular loop at an axial point is given by:

\(B =B_xi = \frac{\mu_0 IR^2}{2(x^2 +R^2)^\frac{3}{2}} i\)

For both the loops, the magnitude of force will be the same (since the parameters a and r are the same) but the direction will differ. The net force acting at this point will be the vector sum of the two individual forces. The direction of forces and the net force is given in the diagram below:

The net force can be calculated as:

Ques. State Biot-Savart’s law and give the mathematical expression for it. Use law to derive the expression for the magnetic field due to a circular coil carrying current at a point along its axis. How does a circular loop carrying current behave as a magnet? (CBSE Delhi 2011) (5 Marks)

Ans. The Biot Savart law gives the mathematical relation to calculate the magnetic field generated due to a current-carrying conductor. Its formula is given below:

\({\displaystyle \mathbf {B} (\mathbf {r} )={\frac {\mu _{0}}{4\pi }}\int _{C}{\frac {I\,d{\boldsymbol {\ell }}\times \mathbf {r'} }{|\mathbf {r'} |^{3}}}}\)

The Figure below portrays a circular loop carrying a stable current I. The loop is located in the y-z plane with its Centre at the source O also radius R. The X-axis is the alignment of the circle. We compute the magnetic field at the point P on this axis. Let x denote the distance of P from the Centre O of the loop.

Circular Coil

Consider a very small conducting element ‘dl’ of the loop. This is given in Fig. 4.1. The magnitude dB of the magnetic field due to dl is specified by the Biot-Savart law.

Currently, r² = x² + R²

If we consider a conducting element dl of the loop, the magnetic field at point P can be given by Biot Savart Law:

As explained, r² = x² + R²

Also, any element on the loop is perpendicular to the displacement vector on the X-axis. This is because they are in different planes. Hence, |dl x r| = rdl. So the formula given above becomes :

-----------------(1)

This calculated dB is shown in the figure as well. It has 2 components, dB_xand dB_y. The component perpendicular to the X axis cancel each other (Because the field is generated from a loop and the diametrically opposite element dl will cancel out the vertical component). The net contribution along x-direction can be obtained by integrating dB_x = dB cos θ over the loop.

-----------------(2)

From equations (1) and (2),

Since dl is a small element of a circular loop, summation of dl leads to 2πR, the loop circumference. The magnetic field thus becomes:

Special Case : As a special case, when x = 0, we get the magnetic field at the center of the current carrying loop. The formula is given below:

The magnetic field lines are illustrated in the figure below. It is very similar to a magnet.

For Latest Updates on Upcoming Board Exams, Click Here: https://t.me/class_10_12_board_updates

Check-Out:

PCMB Study Guides
NCERT Solutions for Class 12 Physics	Class 12 Physics Notes	Formulas in Physics
Topics for Comparison in Physics	Choice-based questions in physics	Topics in relation to physics
Physics Study Notes	Class 12 Physics Book PDF	Class 12 Physics Practicals
Important Derivations in Physics	SI units in Physics	Important Physics Constants and Units
Class 12 Physics Syllabus	Mendeleev's Periodic Table	NCERT Solutions for Class 12 Biology
NCERT Solutions for Class 12 English	NCERT Solutions for Class 11 Chemistry	Class 12 Chemistry Practicals
Class 12 Chemistry Notes	Important Chemical Reactions	Class 12 Maths Notes
Class 12 PCMB Notes	NCERT Class 12 Biology Book	NCERT Class 12 Maths Book
NCERT Class 12 Textbooks	NCERT Solutions for Class 11 Maths	NCERT Solutions for Class 11 Physics
NCERT Solutions for Class 12 Maths	NCERT Solutions for Class 11 Biology	NCERT Solutions for Class 11 English
NCERT Class 11 Chemistry Book	NCERT Class 11 Physics Book	NCERT Class 11 Biology Book
Class 11 Notes	Important Maths Formulas	Important Chemistry Formulas
Class 11 PCMB Syllabus	Chemistry Study Notes	Biology Study Notes
Periodic Table in Chemistry	Important Chemical Reactions	Comparison topics in Chemistry
Comparison Topics in Maths	Biology MCQs	Important Named Reactions
Maths MCQs	Comparison Topics in Biology	Chemistry MCQs

Magnetic Field on the Axis of a Circular Current Loop: Introduction & Derivation

Magnetic Field at the Axis of a Current-Carrying Loop Derivation

Things to Remember

Sample Questions

CBSE CLASS XII Related Questions

2.
The ends of six wires, each of resistance R (= 10 \(\Omega\)) are joined as shown in the figure. The points A and B of the arrangement are connected in a circuit. Find the value of the effective resistance offered by it to the circuit.

3.
A beam of red light and a beam of blue light have equal intensities. Which of the following statements is true?

4.
A vertically held bar magnet is dropped along the axis of a copper ring having a cut as shown in the diagram. The acceleration of the falling magnet is:

5.
The electric field at a point in a region is given by \( \vec{E} = \alpha \frac{\hat{r}}{r^3} \), where \( \alpha \) is a constant and \( r \) is the distance of the point from the origin. The magnitude of potential of the point is:

6.
Two point charges \( q_1 = 16 \, \mu C \) and \( q_2 = 1 \, \mu C \) are placed at points \( \vec{r}_1 = (3 \, \text{m}) \hat{i}\) and \( \vec{r}_2 = (4 \, \text{m}) \hat{j} \). Find the net electric field \( \vec{E} \) at point \( \vec{r} = (3 \, \text{m}) \hat{i} + (4 \, \text{m}) \hat{j} \).

Similar Physics Concepts

Comments

SUBSCRIBE TO OUR NEWS LETTER

Magnetic Field on the Axis of a Circular Current Loop: Introduction & Derivation

Magnetic Field at the Axis of a Current-Carrying Loop Derivation

Things to Remember

Sample Questions

CBSE CLASS XII Related Questions

2.The ends of six wires, each of resistance R (= 10 \(\Omega\)) are joined as shown in the figure. The points A and B of the arrangement are connected in a circuit. Find the value of the effective resistance offered by it to the circuit.

3.A beam of red light and a beam of blue light have equal intensities. Which of the following statements is true?

4.A vertically held bar magnet is dropped along the axis of a copper ring having a cut as shown in the diagram. The acceleration of the falling magnet is:

5.The electric field at a point in a region is given by \( \vec{E} = \alpha \frac{\hat{r}}{r^3} \), where \( \alpha \) is a constant and \( r \) is the distance of the point from the origin. The magnitude of potential of the point is:

6.Two point charges \( q_1 = 16 \, \mu C \) and \( q_2 = 1 \, \mu C \) are placed at points \( \vec{r}_1 = (3 \, \text{m}) \hat{i}\) and \( \vec{r}_2 = (4 \, \text{m}) \hat{j} \). Find the net electric field \( \vec{E} \) at point \( \vec{r} = (3 \, \text{m}) \hat{i} + (4 \, \text{m}) \hat{j} \).

Similar Physics Concepts

Comments

SUBSCRIBE TO OUR NEWS LETTER

2.
The ends of six wires, each of resistance R (= 10 \(\Omega\)) are joined as shown in the figure. The points A and B of the arrangement are connected in a circuit. Find the value of the effective resistance offered by it to the circuit.

3.
A beam of red light and a beam of blue light have equal intensities. Which of the following statements is true?

4.
A vertically held bar magnet is dropped along the axis of a copper ring having a cut as shown in the diagram. The acceleration of the falling magnet is:

5.
The electric field at a point in a region is given by \( \vec{E} = \alpha \frac{\hat{r}}{r^3} \), where \( \alpha \) is a constant and \( r \) is the distance of the point from the origin. The magnitude of potential of the point is:

6.
Two point charges \( q_1 = 16 \, \mu C \) and \( q_2 = 1 \, \mu C \) are placed at points \( \vec{r}_1 = (3 \, \text{m}) \hat{i}\) and \( \vec{r}_2 = (4 \, \text{m}) \hat{j} \). Find the net electric field \( \vec{E} \) at point \( \vec{r} = (3 \, \text{m}) \hat{i} + (4 \, \text{m}) \hat{j} \).