Global particles, local particles (Colosi, Rovelli)

In summary, the conversation discusses a paper by Daniele Colosi and Carlo Rovelli on global and local particles in quantum field theory. The paper argues that while the distinction between global and local states can be neglected in concrete applications, it is conceptually important in understanding the ontology of quantum field theory. The authors also connect their work to Grothendiek's attempts to generalize particles and the beauty of string theory in incorporating concepts from topology and algebraic geometry. The conversation ends with the idea that the world is more subtle than just a collection of particles.
  • #1
marcus
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We already had some brief discussion (2 posts) of this paper in the "Intuitive...Program" thread that is serving as a catch-basket for Loop-and-allied Quantum Gravity links. It probably could use its own thread, to allow space for more discussion, if desired. After I posted this mention of the new paper, selfAdjoint responded drawing some connections to interesting mathematics----I quote his full post in a moment. First, here's the paper:

Daniele Colosi, Carlo Rovelli
Global particles, local particles
http://arxiv.org/abs/gr-qc/0409054

---exerpt from conclusions section---

...the distinction between global and local states can therefore be safely neglected in concrete utilizations of QFT. However, the distinction is conceptually important because it bears on three related issues: (i) whether particles are local or global objects in conventional QFT; (ii) the extent to which the quantum field theoretical notion of particle can be extended to general contexts where gravity cannot be neglected; and furthermore, more in general, (iii) whether particles can be viewed as the fundamental reality (the “ontology”) described by QFT. Let us discuss these three issues separately. ...

...Can we base the ontology of QFT on local particles? Yes, but local particle states are very different from global particle states. Global particle states such as the Fock particle states are defined once and for all in the theory, while each finite size detector defines its own bunch of local particle states. Since in general the energy operators of different detectors do not commute ([HR, HR'] nonzero) there is no unique “local particle basis” in the state space of the theory, as there is a unique Fock basis. Therefore, we cannot interpret QFT by giving a single list of objects represented by a unique list of states. In other words, we are in a genuine quantum mechanical situation in which distinct particle numbers are complementary observables. Different bases that diagonalize different HR operators have equal footing. Whether a particle exists or not depends on what I decide to measure. In such a context, there is no reason to select an observable as “more real” than the others.

The world is far more subtle than a bunch of particles that interact.
---end exerpt from Colosi-Rovelli---
https://www.physicsforums.com/showthread.php?p=313419#post313419

selfAdjoint said:
Apropos of this Colosi-Rovelli attempt to generalize particles, see today's post on Peter Woit's Not Even Wrong about Grothendiek and his toposes. He generalized the Nullstellenstatz view, which you have explicated so clearly, Marcus, in which the points of a continuum are represented as the prime ideals of the algebra of continuous functions on it. G. represents points of a space X as sheafs over X; a sheaf is a kind of category, and this leads to G.'s definition of topos, which we have had some discussion about in connection with Chris Isham's papers. G. was looking to define the "group of a point", and he actually reached a good definition.

Much of the perceived beauty of string theory is actually the beauty of G. and his generation's work in topology and algebraic geometry, which people like Witten have scarfed up and instantiated in physical models, orbifolds, for example. See the survey of this work by Jacques Cartier which Woit gives a link to.
 
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This paper by Colosi and Rovelli is interesting in light of Grothendiek's work as well as the discussions we've had here on PF about particles being local or global objects. It also makes one think about the ontology of quantum field theory and the concept of particles being fundamental reality. It certainly leaves one with the idea that the world is far more subtle than just a bunch of particles that interact.
 
  • #3


SelfAdjoint, thank you for bringing this connection to Peter Woit's Not Even Wrong and Grothendiek's toposes to our attention. It is indeed fascinating to see how ideas from pure mathematics can inspire and inform concepts in theoretical physics. In the case of Grothendiek's toposes, it seems that the idea of a sheaf, which is a structure that captures the local properties of a space, can be seen as analogous to the distinction between global and local particles in Colosi and Rovelli's paper.

This connection also highlights the importance of considering different perspectives and approaches in theoretical physics. While the traditional view of particles as fundamental objects may still hold in certain contexts, it is important to keep an open mind and explore alternative frameworks such as toposes, which may provide new insights and solutions to long-standing problems in physics.

Furthermore, the idea that the world is more subtle than a bunch of interacting particles is a powerful reminder that our current understanding of the universe is far from complete. By continuously questioning and reevaluating our theories, we can hope to gain a deeper understanding of the fundamental nature of reality.
 

1. What is the concept of global particles and local particles?

The concept of global particles and local particles is a fundamental aspect of quantum field theory. In this theory, particles are not seen as discrete, individual objects, but rather as excitations of underlying fields. Global particles are those that are spread out over all of space and time, while local particles are confined to a small region of space and time. This distinction is important in understanding the behavior of particles at the quantum level.

2. How are global particles and local particles related to the uncertainty principle?

The uncertainty principle states that the position and momentum of a particle cannot be known simultaneously with absolute precision. This is related to the concept of global particles and local particles because global particles have a more uncertain position and momentum, as they are spread out over all of space and time. Local particles, on the other hand, have a more well-defined position and momentum, thus minimizing the uncertainty principle.

3. How do global particles and local particles behave differently in quantum interactions?

In quantum interactions, global particles have a higher probability of interacting with other particles, as they are spread out over a larger area. Local particles, on the other hand, have a smaller probability of interaction due to their confined nature. This can lead to different outcomes in quantum processes and is a key aspect of understanding the behavior of particles at the quantum level.

4. Can global particles and local particles be observed in experiments?

No, global particles and local particles cannot be directly observed in experiments. This is because they are not individual, discrete objects, but rather excitations of underlying fields. However, their effects can be observed through various experiments and measurements, such as the behavior of particles in particle colliders or the properties of atoms in a solid.

5. How do global particles and local particles relate to the concept of quantum entanglement?

Quantum entanglement is a phenomenon where two or more particles become connected in such a way that the state of one particle is dependent on the state of the other, even when separated by large distances. The concept of global particles and local particles is important in understanding quantum entanglement, as global particles have a higher likelihood of being entangled due to their spread-out nature, while local particles have a lower likelihood of being entangled due to their confined nature.

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