Ashtekar quantum cosmology paper new this month

In summary, Ashtekar and colleagues have made progress in resolving the big-bang singularity and addressing questions about the origin of the universe through their work on loop quantum cosmology. Their novel approach involves a discrete time evolution and a quantum Hamiltonian constraint that does not break down at the singularity. This paradigm shift requires a reevaluation of our traditional understanding of space and time, and the formulation of new questions within the context of quantum space-times.
  • #1
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What I suspect is a major paper by Ashtekar (and others) appeared in arXiv this month----on June 9.

Mathematical structure of loop quantum cosmology

Ashtekar, Bojowald, Lewandowski

arXiv:gr-qc/0304074

http://www.arxiv.org/abs/gr-qc/0304074

Here is the concluding paragraph:

"We conclude with a general observation. The way in which the big-bang singularity is resolved has potentially deep implications on questions about the origin of the universe. For instance, the question of whether the universe had a beginning at a finite time is now ‘transcended’. At first, the answer seems to be ‘no’ in the sense that the quantum evolution does not stop at the big bang. However, since space-time geometry ‘dissolves’ near the big-bang, there is no longer a notion of time, or of ‘before’ or ‘after’ in the familiar sense. Therefore, strictly, the question is no longer meaningful. The paradigm has changed and meaningful questions must now be phrased differently, without using notions tied to classical space- times. A similar shift of paradigm occurred already with the advent of general relativity. Before Einstein, philosophers argued that the universe could not have a finite beginning because, if it did, one could ask what there was before. However, this question pre-supposes that space-time is an eternal, passive arena and matter simply evolves in it. With general relativity, we learned that space and time are ‘born with matter’, whence the question of ‘what was there before’ is no longer meaningful. Loop quantum cosmology brings about a
further shift of paradigm, weeding out certain questions that seemed meaningful in classical general relativity and requiring that they be replaced by more refined questions, formulated in the context of quantum space-times."
 
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progress towards solving the problem of time-evolution

Ashtekar et al appear to have made some progress is constructing a Hamiltonian operator with which to model time-evolution of the universe---in a way, moreover, naturally compatible with the idea of quantizing time in discrete steps.

Here is a quote from page 23 of the paper that just came out this month---"Mathematical structure of loop quantum cosmology."

"Therefore, to obtain a well-defined operator, we used loops enclosing an area ao, the smallest non-zero quantum of area in quantum geometry. The resulting operator can be regarded as a ‘good’ quantization of the classical constraint function because it has the correct classical limit. The resulting quantum constraint equation has novel and physically appealing properties. First, it is a difference –rather than differential— equation and thus provides a ‘discrete time evolution’. Second, the coefficients in this difference equation are such that the ‘evolution’ does not break down at the singularity; quantum physics does not stop at the big-bang! This occurs without fine tuning matter or making it violate energy conditions. Furthermore, while in consistent discrete models the singularity is often ‘avoided’ because discrete ‘time steps’ are such that one simply leaps over the point where the singularity is expected to occur, here, one can and does confront the singularity head on only to find that it has been resolved by the quantum ‘evolution’. Furthermore, these features are robust. However, near the big-bang, the state is ‘extremely quantum mechanical,’ with large fluctuations. Thus, the classical space-time ‘dissolves’ near the big-bang. In this regime, we can analyze the structure only in quantum mechanical terms; we can no longer use our classical intuition which is deeply rooted in space-times and small fluctuations around them."

The quantum Hamiltonian contraint (e.g. equation 4.10 on page 17) necessarily contains a matter term.

This form of the LQG Hamiltonian constraint is recognizable as a quantum version of the Einstein equation of standard GR and analogous to the earlier Wheeler-DeWitt "quantum Einstein equation" (e.g. equation 4.12 on page 18, provided for comparison.)
 
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  • #3


The release of this new paper by Ashtekar and his colleagues is certainly exciting news for the field of quantum cosmology. The paper presents a new mathematical structure for loop quantum cosmology, which has the potential to resolve the big-bang singularity and change our understanding of the origin of the universe.

One of the most interesting aspects of this paper is the shift in paradigm it brings about. As the authors mention, this is not the first time a shift in paradigm has occurred in the field of cosmology. Just as general relativity changed our understanding of space and time, loop quantum cosmology is now challenging our traditional notions of the big bang and the beginning of the universe.

The idea that time and space are not fundamental concepts, but rather emerge from quantum properties, is a fascinating concept. It highlights the importance of approaching cosmological questions from a quantum perspective, rather than relying solely on classical theories.

Furthermore, the authors make a thought-provoking point about the changing nature of meaningful questions in the context of quantum space-times. As we continue to expand our understanding of the universe, it is crucial that we adapt our ways of thinking and phrasing questions accordingly.

Overall, this paper by Ashtekar and his colleagues is a significant contribution to the field of quantum cosmology. It not only presents a new mathematical structure, but also challenges our traditional ways of thinking about the universe and encourages us to ask more refined questions. I look forward to seeing how this paper will impact future research and our understanding of the origin of the universe.
 

1. What is the significance of the Ashtekar quantum cosmology paper?

The Ashtekar quantum cosmology paper, published this month, presents a new approach to understanding the early universe using techniques from quantum mechanics and general relativity. This paper could potentially offer new insights into the fundamental laws of the universe and the origins of the cosmos.

2. How does Ashtekar quantum cosmology differ from traditional cosmology?

Traditional cosmology relies on classical physics to explain the universe, while Ashtekar quantum cosmology incorporates quantum mechanics. This allows for a more accurate and comprehensive understanding of the universe, especially in the earliest stages of its development.

3. What are the key findings of the Ashtekar quantum cosmology paper?

The Ashtekar quantum cosmology paper proposes a new mathematical framework for describing the universe at the quantum level. It also suggests that the universe may have originated from a single quantum state rather than a singularity. Additionally, the paper presents a more precise way to calculate the quantum fluctuations in the early universe.

4. How could the Ashtekar quantum cosmology paper impact future research in cosmology?

The Ashtekar quantum cosmology paper opens up new avenues for research and could potentially lead to a deeper understanding of the origins of the universe. It also provides a more accurate and comprehensive way to study the early universe, which could have implications for other areas of physics such as quantum gravity.

5. What are the implications of the Ashtekar quantum cosmology paper for the general public?

While the Ashtekar quantum cosmology paper is primarily aimed at researchers in the field of cosmology, its findings have the potential to impact our understanding of the universe and its origins. This could ultimately lead to a better understanding of our place in the cosmos and the laws that govern it.

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