Field Quantization: Confined in Cube or Whole Space?

In summary, the use of periodic or box boundary conditions in field quantization, specifically for the EM field, is a common practice to simplify problems and obtain discrete energies. However, working directly with continuous spectra is becoming more popular. The concept of "photon" is easily obtained through box quantization, but it may not be the most efficient method for quantizing gauge classical field theories. The Casimir force is an example where boundary conditions do make a difference.
  • #1
zhangpujumbo
18
0
I see in many textbooks that all authors start field quantization with EM field confined in a cube of finite size, certainly some B.C. is imposed, usually periodic B.C., finally the cube goes to whole space.

I have some questions on this procedure:
1, Is periodic(or other) B.C. reasonable? Doesn't the B.C. have any influence on final results?
2, Is this cube necessary? Why not just do the decomposition in the whole space(continuous decompostition spectrum encounterd?)?

I heared that this method of quantizing EM field was originally proposed by Dirac in his Lectures on Quantum Field Theory. Would anyone be kind enough to share it?

Thank you all for attention!:smile:
 
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  • #2
Periodic and box boundry conditions lead to discrete energies. They have been used in virtually all branches of physics, to simplify some of the problems associated with continuous spectra. You can find discussions of this in virtually any text on QM or QFT -- this trick goes back many, many years, before 1900, for many types of boundary value problems as well.

These days, working directly with the continuous spectra is more in vogue.

Regards,
Reilly Atkinson.
 
  • #3
Box quantization for the EM field simply is a nice way to get to the concept of "photon" by evading the headaches one gets when he tries to quantize a gauge classical field theory described in [itex] \mathbb{M}_{4} [/itex].

Daniel.
 
  • #4
One obvious phenomenon where the boundary conditions do matter is the Casimir force.
 
Last edited:
  • #5
Physics Monkey said:
One obvious phenomenon where the boundary conditions do matter is the Casimir force.

Then sometimes the boundary conditions do make a difference.
 

1. What is field quantization?

Field quantization is a method used in theoretical physics to describe the behavior of quantum fields. It involves splitting the field into discrete units, or quanta, in order to better understand and predict its properties.

2. What is the difference between being confined in a cube and being in the whole space?

In the context of field quantization, being confined in a cube means that the field is limited to a specific volume or region, while being in the whole space means that the field extends infinitely in all directions. These different configurations can have an impact on the behavior of the field and its quanta.

3. What is the significance of field quantization in physics?

Field quantization is a fundamental concept in quantum field theory, which is a framework for combining quantum mechanics and special relativity. It allows us to better understand and predict the behavior of particles and fields at the subatomic level, and has been crucial in the development of many modern theories in physics.

4. How is field quantization related to the uncertainty principle?

The uncertainty principle, which states that certain pairs of physical properties cannot be precisely measured at the same time, is a consequence of field quantization. This is because the discrete nature of quanta means that certain properties, such as position and momentum, cannot be known with absolute precision.

5. What are some practical applications of field quantization?

Field quantization has many practical applications in fields such as quantum mechanics, particle physics, and condensed matter physics. It is used in the development of new technologies, such as quantum computers, and has also played a crucial role in our understanding of the universe and its origins.

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