Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Question

Want to see more full solutions like this?

Answer 1

Textbook Question

Chapter 5, Problem 5.1P

Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

you dont need to solve the question i just wanna know the steps and how to find the angle between the voltage difference and the current . thanks so much

istics of diodes, bipolar junction transistors, and plain the structure, operation, 1. The purpose of doping in semiconductor diodes is: a) To control their electrical properties b) To increase their physical size c) To enhance their mechanical strength d) To improve their thermal stability 2. In electronics production, your team wants to manufacture a very cheap diode rectifier. Which of the following rectifier configurations would you select? a) Half-wave rectifier c) Full-wave rectifier b) Bridge rectifier d) Controlled rectifier 3. The region that a Zener diode operates to provide voltage regulation is: a) Saturation c) Reverse bias b) Breakdown d) Forward bias 4. In NMOS transistors, the depth of the channel is primarily changed by: a) VDS b) lp c) VGS d) None of these 5. NMOS transistors have than PMOS, resulting in better current conduction: b) Long channel a) High mobility c) Low mobility d) Short channel 6. You are working in electronic production, and your team is asked to…

8.46 The generator circuit shown in Fig. P8.46 (on page 494) isconnected to a distant load via a long coaxial transmission line.The overall circuit can be modeled as in Fig. P8.46(b), in whichthe transmission line is represented by an equivalent impedanceZline = (5+ j2) W.(a) Determine the power factor of voltage source Vs.(b) Specify the capacitance of a shunt capacitor C that wouldraise the power factor of the source to unity when connectedbetween terminals (a,b). The source frequency is 1.5 kHz.

Answer 2

Textbook Question

Chapter 5, Problem 5.1P

Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Textbook Question

Chapter 5, Problem 5.1P

Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Textbook Question

Chapter 5, Problem 5.1P

Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Answer 8

Expert Solution & Answer

To determine

The Helmholtz equation for magnetic field H .

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

The Helmholtz equation for magnetic field H .

Answer 12

Answer to Problem 5.1P

The Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Answer 13

Explanation of Solution

Given:

The Maxwell’s equations are simple and the media is free of any charge.

Concept used:

The equation of Ampere’s circuital law for simple and charge free media is shown below.

∇×H=σE+ε∂E∂t ....... (1)

The equation of Faraday’s law is shown below.

∇×E=−μ∂H∂t

Calculation:

The condition for charge free media is ∇⋅H=0 .

Take curl on both sides of equation (1) as shown below.

∇×(∇×H)=∇×(σE+ε ∂E ∂t)=∇×(σE)+∇×(ε ∂E ∂t)=σ(∇×E)+ε(∇× ∂E ∂t)

Since, the right side of above equation is a position derivative that acts on time derivative, so the above equation can be written as,

∇×(∇×H)=σ(∇×E)+ε∂∂t(∇×E)

Substitute −μ∂H∂t for ∇×E in above equation.

∇×(∇×H)=σ(−μ ∂H ∂t)+ε∂∂t(−μ ∂H ∂t)=−μσ∂H∂t−με∂∂t( ∂H ∂t)=−μσ∂H∂t−με∂2H∂t2

The curl of curl of any vector is equal to the divergence and Laplacian, so the above equation can be written as,

∇⋅H−∇2H=−μσ∂H∂t−με∂2H∂t2

Due to charge free medium the value of divergence of magnetic field ∇⋅H is equal to 0 .

Now, the above equation can be written as,

−∇2H=−μσ∂H∂t−με∂2H∂t2∇2H=μσ∂H∂t+με∂2H∂t2

The above equation is known as Helmholtz wave equation for magnetic field H .

Therefore, the Helmholtz equation is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Conclusion:

Thus, the Helmholtz equation for magnetic field H is ∇2H=μσ∂H∂t+με∂2H∂t2 .

Answer 14

Ch. 5 - Starting with Maxwells equations for simple,...Ch. 5 - Derive (5.10) by starting with the phasor point...Ch. 5 - A wave with =6.0cm in air is incident on a...Ch. 5 - Suppose Hs(z)=Hys(z)ay. Start with (5.14) and...Ch. 5 - Given =1.0105S/m,r=2.0,r=50., and f=10.MHz, find...Ch. 5 - In some material, the constitutive parameters are...Ch. 5 - Prob. 5.7P Ch. 5 - Prob. 5.8P Ch. 5 - Prob. 5.9P Ch. 5 - A 100-MHz wave in free space propagates in the y...

Starting with Maxwell’s equations for simple, charge free media, derive the Helmholtz equation for H.

Concept explainers

Videos

Answer to Problem 5.1P

Explanation of Solution

Want to see more full solutions like this?

Chapter 5 Solutions