toplogo
Giriş Yap

Conformal Field Theories with Large Gaps Constructed from Barnes-Wall Lattice Orbifolds


Temel Kavramlar
This paper presents a novel method for constructing conformal field theories (CFTs) with large gaps, a desirable property in theoretical physics, by utilizing orbifolds of Barnes-Wall lattice VOAs and leveraging the properties of extraspecial 2-groups.
Özet
  • Bibliographic Information: Keller, C. A., Roberts, A. W., & Roberts, J. (2024). CFTS WITH LARGE GAP FROM BARNES-WALL LATTICE ORBIFOLDS. arXiv preprint arXiv:2411.13646.

  • Research Objective: This paper aims to construct conformal field theories (CFTs) with large gaps, a property referring to the relatively large weight of the lightest non-vacuum primary fields in the theory. This is motivated by applications in areas like AdS3/CFT2 holography.

  • Methodology: The authors utilize the mathematical framework of vertex operator algebras (VOAs) and their orbifolds. They focus on Barnes-Wall lattices, known for their lack of short vectors, and construct orbifolds using extraspecial 2-groups. The properties of these groups allow for the projection out of light states, leading to CFTs with larger gaps. The authors investigate the twisted modules of the lattice VOAs and their projective representations to construct the orbifold CFTs.

  • Key Findings: The paper presents two main findings. First, by orbifolding the Barnes-Wall lattice in d=128 by the extraspecial group E(7), they construct a CFT with central charge c=128 and gap 2, notable for having a minimal number of light states. Second, they conjecture the existence of a holomorphic CFT with c=128 and gap 4, achievable if a specific anomaly 3-cocycle vanishes. While not providing a complete proof, they offer evidence supporting this conjecture.

  • Main Conclusions: The paper provides a novel method for constructing CFTs with large gaps, a significant advancement in the field. The conjectured existence of a holomorphic CFT with gap 4 opens up new avenues for research in areas like AdS3/CFT2 holography.

  • Significance: This research contributes significantly to the understanding and construction of CFTs with desired properties. The construction of CFTs with large gaps has implications for theoretical physics, particularly in the context of holography and string theory.

  • Limitations and Future Research: The existence of the holomorphic CFT with gap 4 relies on the unproven conjecture about the vanishing of the anomaly 3-cocycle. Future research could focus on proving this conjecture or exploring alternative methods to construct CFTs with even larger gaps. Additionally, exploring the properties and applications of the constructed CFTs, particularly in the context of holography, presents a promising direction for future work.

edit_icon

Özeti Özelleştir

edit_icon

Yapay Zeka ile Yeniden Yaz

edit_icon

Alıntıları Oluştur

translate_icon

Kaynağı Çevir

visual_icon

Zihin Haritası Oluştur

visit_icon

Kaynak

İstatistikler
The Barnes-Wall lattice in d=128 is used. The extraspecial group E(7) is used for orbifolding. The constructed CFT has a central charge of c=128. The first CFT has a gap of 2. The conjectured holomorphic CFT has a gap of 4.
Alıntılar
"To our knowledge this is the CFT with the fewest such states known in the literature." "To our knowledge this is the first example of a CFT in two dimensions with gap larger than 2."

Önemli Bilgiler Şuradan Elde Edildi

by Christoph A.... : arxiv.org 11-22-2024

https://arxiv.org/pdf/2411.13646.pdf
CFTs with Large Gap from Barnes-Wall Lattice Orbifolds

Daha Derin Sorular

How do the properties of the constructed CFTs, particularly the large gaps, manifest in the context of AdS3/CFT2 correspondence and what implications do they have for the understanding of gravity in the bulk?

CFTs with large gaps are of particular interest in the context of AdS3/CFT2 correspondence because they correspond to weakly coupled gravitational theories in the bulk. This connection stems from the relationship between the central charge $c$ of the CFT and the AdS radius $l_{AdS}$ in units of the Planck length $l_P$: $$ \frac{l_{AdS}}{l_P} \sim \sqrt{c} $$ A large central charge implies a large AdS radius, indicating a weakly curved AdS spacetime. Furthermore, the gap in the CFT spectrum, $\Delta_{gap}$, is related to the mass of the lightest non-vacuum state in the bulk: $$ \Delta_{gap} \sim \frac{m_{lightest} l_{AdS}}{\hbar c} $$ Therefore, a large gap in the CFT spectrum translates to a large mass for the lightest bulk excitation compared to the Planck scale. This implies that the bulk theory is weakly coupled, as the gravitational interactions between these heavy particles are suppressed. The construction of CFTs with large gaps, like the one presented in the paper using Barnes-Wall lattice orbifolds, provides valuable examples for exploring the weakly coupled regime of gravity in AdS3. These CFTs can be used to: Test the AdS3/CFT2 dictionary: By studying the properties of these CFTs, we can make predictions about the behavior of gravity in the weakly coupled regime and compare them to existing knowledge or future calculations in the bulk theory. Understand black hole physics: Large gap CFTs could provide insights into the microscopic origin of black hole entropy and the information paradox, as they offer a tractable framework for studying black holes in a controlled, weakly coupled setting. Explore novel phases of gravity: The existence of CFTs with large gaps hints at the possibility of novel phases of gravity in AdS3, potentially with exotic properties that differ significantly from our current understanding of classical gravity.

Could there be alternative algebraic constructions or different choices of lattices and orbifold groups that could potentially lead to CFTs with even larger gaps, and what challenges might arise in such explorations?

Yes, exploring alternative algebraic constructions, lattices, and orbifold groups holds the potential for discovering CFTs with even larger gaps. Here are some avenues for exploration and their associated challenges: Different Lattices: Higher dimensional lattices: Moving beyond Barnes-Wall lattices to higher dimensional lattices with larger minimum vector lengths could directly lead to larger gaps. However, the complexity of their automorphism groups and the difficulty in constructing their twisted modules pose significant challenges. Lattices with special properties: Exploring lattices with specific properties, such as those exhibiting high levels of symmetry or possessing interesting sublattice structures, might offer new avenues for constructing CFTs with desirable gap properties. However, identifying and characterizing such lattices remains a challenge. Alternative Orbifold Groups: Larger groups: Utilizing larger orbifold groups with more intricate structures could potentially project out more low-lying states, leading to larger gaps. However, the analysis of their representations and the construction of modular invariants become increasingly complex. Non-abelian groups with specific properties: Focusing on non-abelian groups with specific properties, such as those with large centers or possessing specific fusion rules, might offer more control over the resulting CFT spectrum and potentially lead to larger gaps. However, identifying suitable groups and understanding their action on the lattice VOA requires careful analysis. Beyond Orbifolds: Coset Constructions: Generalizing the orbifold procedure to coset constructions, where one considers the quotient of a VOA by a sub-VOA, could provide a richer landscape for discovering CFTs with large gaps. However, the representation theory of coset VOAs is generally more intricate than that of orbifold VOAs. Fusion Categories: Exploring CFT constructions based on more general fusion categories, beyond those arising from finite groups, might offer new possibilities for achieving large gaps. However, this approach requires a deeper understanding of the relationship between fusion categories and CFTs. The main challenges in these explorations lie in: Computational complexity: Analyzing larger lattices and groups, constructing their representations, and determining modular invariants quickly become computationally demanding. Identifying suitable candidates: It is not always clear a priori which lattices or groups will lead to CFTs with large gaps. Developing efficient methods for identifying promising candidates is crucial. Understanding the underlying structures: A deeper understanding of the relationship between the algebraic properties of the lattice, the orbifold group, and the resulting CFT spectrum is essential for making progress in this direction.

What are the implications of the potential existence of a holomorphic CFT with a gap larger than 2 for the classification program of CFTs, and could it hint at undiscovered structures or principles governing these theories?

The potential existence of a holomorphic CFT with a gap larger than 2 would have profound implications for the classification program of CFTs and could point towards undiscovered structures or principles governing these theories. Challenges to Existing Classifications: Extremal CFT conjecture: The most immediate implication is a counterexample to the extremal CFT conjecture, which posits that the maximum gap for a holomorphic CFT of central charge $c$ is given by $\lfloor c/24 \rfloor + 1$. Finding a holomorphic CFT with a larger gap would necessitate a reevaluation and refinement of this conjecture. Limitations of current techniques: Current classification efforts often rely on properties like modular invariance and fusion rules, which might not be sufficient to fully capture the constraints on the CFT spectrum, particularly for large gaps. New techniques and approaches might be needed to understand and classify these theories. Hints towards New Structures and Principles: Hidden symmetries: CFTs with large gaps could possess hidden symmetries or algebraic structures that are not readily apparent from their construction. These symmetries could play a crucial role in determining the spectrum and other properties of the theory. New duality relations: The existence of such CFTs might point towards new duality relations between seemingly different CFTs or even between CFTs and other quantum field theories. These dualities could provide powerful tools for studying and classifying CFTs. Connections to other areas of mathematics: The construction of the CFT with a gap larger than 2 in the paper relies heavily on the theory of lattices and their automorphism groups. This suggests that further exploration of CFTs with large gaps could lead to fruitful connections with other areas of mathematics, such as number theory, group theory, and algebraic geometry. Overall Impact: The discovery of a holomorphic CFT with a gap larger than 2 would be a significant breakthrough in the field of CFTs. It would challenge existing classifications, necessitate the development of new techniques, and potentially unveil hidden structures and principles governing these theories. This, in turn, could lead to a deeper understanding of quantum field theory, string theory, and even quantum gravity.
0
star