Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lienard-Wiechert Potentials

Published byClyde Lamb Modified over 5 years ago

Similar presentations

Presentation on theme: "Lienard-Wiechert Potentials"— Presentation transcript:

1 Lienard-Wiechert Potentials
LL2 Section 63

2 Lienard-Wiechert are the retarded potentials of a point charge
Potentials at the field point are determined by the state of motion at the earlier time t’, where t = “now”.

3

4 Information about the state of motion at t’ propagates to P at speed c.
The time t’ , when the signal that arrives to P at time t was sent, is determined by the root of this equation.

5 The charge is momentarily at rest in an inertial reference frame at time t’
E-field line at t

6 In that inertial frame, the potentials at P at time t are
(since charge is at rest in that frame) E-field line at t

7 Potentials for the lab frame are found from potentials in the charge’s frame by Lorentz transform
E-field line at t

8 If v = 0, then the lab frame coincides with the rest frame of the charge, and the potentials coincide. If we can guess a 4-vector that has this property, then we know the 4-potential in any other frame Four-velocity of the charge (Abbreviated as r’ in the text)

9 The equation that determines t’ , R(t’) = c (t - t’), is equivalent to RkRk = 0 (HW).
Lienard-Wiechert Potentials (HW) R and v are evaluated at t’

10 Fields Differentiations are with respect to coordinates of the field point P(x,y,z) at time of observation t. Potentials are functions of t’, which depends on r & t through r - r0(t’) = c (t-t’) We need the derivatives of t’ with respect to t, x, y, & z.

11

12

13

14 All right side terms are evaluated at t’.
H and E are perpendicular.

15 E-field has two terms The 1st depends only on v, not dv/dt. Goes as 1/R2. This is the field of a uniformly moving charge. The 2nd depends on dv/dt. Goes as 1/R, i.e. falls off more slowly. This is the radiation term.

16 Constant velocity Vector in the first term = The distance from charge to field point at the moment of observation Denominator in the first term See derivation on the next page

17 Electric field points along the line from the present position of the charge, even through the “message” originated at the retarded position. Sin2q factor flattens field in the forward and backward directions. First term Field of a uniformly moving charge. Same formula as (38.8). R and q are evaluated at the present time t, not the retarded time t’.

18

19

Download ppt "Lienard-Wiechert Potentials"

Similar presentations

Building Spacetime Diagrams PHYS 206 – Spring 2014.

Building Spacetime Diagrams PHYS 206 – Spring 2014.
Position, Velocity and Acceleration

Position, Velocity and Acceleration
Invariants of the field Section 25. Certain functions of E and H are invariant under Lorentz transform The 4D representation of the field is F ik F ik.

Invariants of the field Section 25. Certain functions of E and H are invariant under Lorentz transform The 4D representation of the field is F ik F ik.
Physics 311 Special Relativity Lecture 5: Invariance of the interval. Lorentz transformations. OUTLINE Invariance of the interval – a proof Derivation.

Physics 311 Special Relativity Lecture 5: Invariance of the interval. Lorentz transformations. OUTLINE Invariance of the interval – a proof Derivation.
Feb 25, 2011. RETARDED POTENTIALS At point r =(x,y,z), integrate over charges at positions r’ (7) (8) where [ρ]  evaluate ρ at retarded time: Similar.

Feb 25, RETARDED POTENTIALS At point r =(x,y,z), integrate over charges at positions r’ (7) (8) where [ρ]  evaluate ρ at retarded time: Similar.
Ch. 4: Velocity Kinematics

Ch. 4: Velocity Kinematics
March 28, 2011 HW 7 due Wed. Midterm #2 on Monday April 4 Today: Relativistic Mechanics Radiation in S.R.

March 28, 2011 HW 7 due Wed. Midterm #2 on Monday April 4 Today: Relativistic Mechanics Radiation in S.R.
Antennas Hertzian Dipole –Current Density –Vector Magnetic Potential –Electric and Magnetic Fields –Antenna Characteristics.

Antennas Hertzian Dipole –Current Density –Vector Magnetic Potential –Electric and Magnetic Fields –Antenna Characteristics.
March 2, 2011 Fill in derivation from last lecture Polarization of Thomson Scattering No class Friday, March 11.

March 2, 2011 Fill in derivation from last lecture Polarization of Thomson Scattering No class Friday, March 11.
Day18: Electric Dipole Potential & Determining E-Field from V

Day18: Electric Dipole Potential & Determining E-Field from V
The Lorentz transformations Covariant representation of electromagnetism.

The Lorentz transformations Covariant representation of electromagnetism.
Chapter 14 Section 14.3 Curves. x y z To get the equation of the line we need to know two things, a direction vector d and a point on the line P. To find.

Chapter 14 Section 14.3 Curves. x y z To get the equation of the line we need to know two things, a direction vector d and a point on the line P. To find.
Relative Velocity Two observers moving relative to each other generally do not agree on the outcome of an experiment However, the observations seen by.

Relative Velocity Two observers moving relative to each other generally do not agree on the outcome of an experiment However, the observations seen by.
Special Relativity Quiz 9.4 and a few comments on quiz 8.24.

Special Relativity Quiz 9.4 and a few comments on quiz 8.24.
General Lorentz Transformation Consider a Lorentz Transformation, with arbitrary v, : ct´ = γ(ct - β  r) r´ = r + β -2 (β  r)(γ -1)β - γctβ Transformation.

General Lorentz Transformation Consider a Lorentz Transformation, with arbitrary v, : ct´ = γ(ct - β  r) r´ = r + β -2 (β  r)(γ -1)β - γctβ Transformation.
Advanced EM - Master in Physics 2011-2012 1 The (GENERAL) solution of Maxwell’s equations Then for very small r, outside the charge region but near it,

Advanced EM - Master in Physics The (GENERAL) solution of Maxwell’s equations Then for very small r, outside the charge region but near it,
Elementary Particles in the theory of relativity Section 15.

Elementary Particles in the theory of relativity Section 15.
Special relativity.

Special relativity.
1 1.Einstein’s special relativity 2.Events and space-time in Relativity 3. Proper time and the invariant interval 4. Lorentz transformation 5. Consequences.

1 1.Einstein’s special relativity 2.Events and space-time in Relativity 3. Proper time and the invariant interval 4. Lorentz transformation 5. Consequences.
Tuesday June 7, 2005 1 PHYS 1443-001, Summer I 2005 Dr. Andrew Brandt PHYS 1443 – Section 001 Lecture #5 Tuesday June 67 2005 Dr. Andrew Brandt Reference.

Tuesday June 7, PHYS , Summer I 2005 Dr. Andrew Brandt PHYS 1443 – Section 001 Lecture #5 Tuesday June Dr. Andrew Brandt Reference.

Similar presentations

Ads by Google