Yes, maybe in an introductory section. It would be good if each of the articles in the sequence would begin with an initial section summarizing what is to follow, what it means in terms of buzzwords (to be explained later), and giving basic sources for further reading.[URL='https://www.physicsforums.com/insights/author/urs-schreiber/']Urs Schreiber[/URL] said:
A. Neumaier said:
Indeed, for the whole articles, you have it - but in too overwhelming detail. I'd prefer if the chapter introductions are more elementary and less detailed, and if the overview over the details are delegated to the top of each section. (I wrote the comment since the section ''Covariant phase space'' started without introduction, and I had mistakenly taken it for the start of the whole chapter.) And if possible the same again on a subsection level.[URL='https://www.physicsforums.com/insights/author/urs-schreiber/']Urs Schreiber[/URL] said:
Putting this somewhere at the top of the section ''Covariant phase space'' would be a way of satisfying both you and me.[URL='https://www.physicsforums.com/insights/author/urs-schreiber/']Urs Schreiber[/URL] said:
A. Neumaier said:
Mathematical quantum field theory is a branch of theoretical physics that uses mathematical models to describe the behavior of subatomic particles and their interactions. It combines elements of quantum mechanics and classical field theory to provide a framework for understanding the fundamental forces of nature.
In quantum field theory, phase space refers to the space of all possible states of a system at a given time. It is a mathematical construct that allows us to describe the positions and momenta of particles in a quantum system. It is an important concept in understanding the dynamics of particles and their interactions.
Phase space is widely used in quantum field theory to calculate scattering amplitudes, study particle interactions, and understand the behavior of quantum systems. It also plays a crucial role in the development of quantum computing and quantum information theory.
One of the main challenges in studying phase space in quantum field theory is dealing with the infinite number of degrees of freedom that arise in the calculations. This requires advanced mathematical techniques such as renormalization and regularization to handle divergent integrals and ensure meaningful results.
Recent developments in phase space methods in quantum field theory include the use of geometric and topological methods to study the structure of phase space, and the application of machine learning techniques to improve calculations and simulations. There is also ongoing research in using phase space to better understand the behavior of black holes and the nature of spacetime.
