Ciro Santilli @cirosantilli 34

 Incoming links: Action (physics)

Lagrangian density  Updated 2024-12-15  +Created 1970-01-01

When we particles particles, the action is obtained by integrating the Lagrangian over time:

A c t i o n = \int_{t_{0}}^{t} L (x (t), \frac{\partial x ( t )}{\partial t}, t) d t

(1)

In the case of field however, we can expand the Lagrangian out further, to also integrate over the space coordinates and their derivatives.

Since we are now working with something that gets integrated over space to obtain the total action, much like density would be integrated over space to obtain a total mass, the name "Lagrangian density" is fitting.

E.g. for a 2-dimensional field

f (x, y, t)

A c t i o n = \int_{t_{0}}^{t} L (f (x, y, t), \frac{\partial f ( x , y , t )}{\partial x}, \frac{\partial f ( x , y , t )}{\partial y}, \frac{\partial f ( x , y , t )}{\partial t}, x, y, t) d x d y d t

(2)

Of course, if we were to write it like that all the time we would go mad, so we can just write a much more condensed vectorized version using the gradient with

x \in R^{2}

A c t i o n = \int_{t_{0}}^{t} L (f (x, t), \nabla f (x, t), x, t) d x d t

(3)

And in the context of special relativity, people condense that even further by adding

t

to the spacetime Four-vector as well, so you don't even need to write that separate pesky

t

The main point of talking about the Lagrangian density instead of a Lagrangian for fields is likely that it treats space and time in a more uniform way, which is a basic requirement of special relativity: we have to be able to mix them up somehow to do Lorentz transformations. Notably, this is a key ingredient in a/the formulation of quantum field theory.

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Richard Feynman Quantum Electrodynamics Lecture at University of Auckland (1979)  Updated 2024-12-15  +Created 1970-01-01

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Talk title shown on intro: "Today's Answers to Newton's Queries about Light".

6 hour lecture, where he tries to explain it to an audience that does not know any modern physics. This is a noble effort.

Part of The Douglas Robb Memorial Lectures lecture series.

Feynman apparently also made a book adaptation: QED: The Strange Theory of Light and Matter. That book is basically word by word the same as the presentation, including the diagrams.

According to www.feynman.com/science/qed-lectures-in-new-zealand/ the official upload is at www.vega.org.uk/video/subseries/8 and Vega does show up as a watermark on the video (though it is too pixilated to guess without knowing it), a project that has been discontinued and has has a non-permissive license. Newbs.

4 parts:

Part 1: is saying "photons exist"
Part 2: is amazing, and describes how photons move as a sum of all possible paths, not sure if it is relativistic at all though, and suggests that something is minimized in that calculation (the action)
Part 3: is where he hopelessly tries to explain the crucial part of how electrons join the picture in a similar manner to how photons do.
He does make the link to light, saying that there is a function $P (A, B)$ which gives the amplitude for a photon going from A to B, where A and B are spacetime events.
And then he mentions that there is a similar function $E (A, B)$ for an electron to go from A to B, but says that that function is too complicated, and gives no intuition unlike the photon one.
He does not mention it, but P and E are the so called propagators.
This is likely the path integral formulation of QED.
On Quantum Mechanical View of Reality by Richard Feynman (1983) he mentions that $E$ is a Bessel function, without giving further detail.
And also mentions that:
$E = f (1, 2, m) P = f (1, 2, 0)$
(1)
where m is basically a scale factor.
such that both are very similar. And that something similar holds for many other particles.
And then, when you draw a Feynman diagram, e.g. electron emits photon and both are detected at given positions, you sum over all the possibilities, each amplitude is given by:
$c \times E (A, D) \times E (D, B) \times P (B, C)$
(2)
summed over all possible $D$ Spacetime points.
This is basically well said at: youtu.be/rZvgGekvHes?t=3349 from Quantum Mechanical View of Reality by Richard Feynman (1983).
TODO: how do electron velocities affect where they are likely to end up? $E (A, D)$ suggests the probability only depends on the spacetime points.
Also, this clarifies why computations in QED are so insane: you have to sum over every possible point in space!!! TODO but then how do we calculate anything at all in practice?
Part 4: known problems with QED and thoughts on QCD. Boring.

This talk has the merit of being very experiment oriented on part 2, big kudos: how to teach and learn physics

Video 1.

Richard Feynman Quantum Electrodynamics Lecture at University of Auckland (1979) uploaded by Trev M (2015)

Source. Single upload version. Let's use this one for the timestamps I guess.

youtu.be/Alj6q4Y0TNE?t=2217: photomultiplier tube
youtu.be/Alj6q4Y0TNE?t=2410: local hidden-variable theory
youtu.be/Alj6q4Y0TNE?t=6444: mirror experiment shown at en.wikipedia.org/w/index.php?title=Quantum_electrodynamics&oldid=991301352#Probability_amplitudes
youtu.be/Alj6q4Y0TNE?t=7309: mirror experiment with a diffraction grating pattern painted black leads to reflection at a weird angle
youtu.be/Alj6q4Y0TNE?t=7627: detector under water to explain refraction
youtu.be/Alj6q4Y0TNE?t=8050: explains biconvex spherical lens in terms of minimal times
youtu.be/Alj6q4Y0TNE?t=8402: mentions that for events in a series, you multiply the complex number of each step
youtu.be/Alj6q4Y0TNE?t=9270: mentions that the up to this point, ignored:
- amplitude shrinks down with distance
- photon polarization
but it should not be too hard to add those
youtu.be/Alj6q4Y0TNE?t=11697: finally starts electron interaction. First point is to add time of event detection.
youtu.be/Alj6q4Y0TNE?t=13704: electron between plates, and mentions the word action, without giving a clear enough idea of what it is unfortunately
youtu.be/Alj6q4Y0TNE?t=14467: mentions positrons going back in time, but does not clarify it well enough
youtu.be/Alj6q4Y0TNE?t=16614: on the fourth part, half is about frontiers in quantum electrodynamics, and half full blown theory of everything. The QED part goes into renormalization and the large number of parameters of the Standard Model

Video 2.

Richard Feynman Lecture on Quantum Electrodynamics 1/8

. Source.

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