Light-cone Actions, Correlators, and Soft Limits of Self-Dual Yang-Mills and Gravity in AdS4

While self-dual theories in AdS4 enjoy remarkable simplifications due to their enhanced symmetry, extending these insights to more realistic, less symmetric theories presents a considerable challenge. However, the techniques and structures uncovered in this simpler setting can serve as valuable stepping stones. Here's how: Perturbative Expansions: The self-dual sector can be viewed as a starting point for a perturbative expansion. By systematically incorporating the non-self-dual degrees of freedom, one could potentially develop a controlled approximation scheme for less symmetric theories. This approach has been fruitful in flat space scattering amplitudes, where techniques like the BCFW recursion relations, initially formulated for self-dual Yang-Mills, have been generalized to full Yang-Mills and gravity. Color-Kinematics Duality as a Guiding Principle: The presence of color-kinematics duality in the self-dual sector hints at hidden structures that might persist in more general settings. Even if the duality is not manifest, it could still offer valuable guidance in organizing and simplifying computations in less symmetric theories. Deformations of Known Structures: The deformed Poisson bracket appearing in the AdS4 self-dual gravity action suggests that familiar structures from flat space might have non-trivial generalizations in curved spacetimes. Exploring these deformations could provide insights into the behavior of gravity in more realistic scenarios. Toy Models for Specific Phenomena: Self-dual theories, despite their simplicity, can still capture certain essential features of more complex theories. For instance, they could serve as useful toy models for investigating aspects of holography, conformal bootstrap, or the emergence of spacetime from quantum entanglement. It's important to note that extending these insights to less symmetric theories will likely require significant technical advances and new conceptual breakthroughs. Nevertheless, the study of self-dual sectors provides a valuable testing ground for new ideas and a source of inspiration for tackling the challenges posed by more realistic theories.

It's certainly possible that the elegant structure of boundary correlators in the self-dual sector, particularly their relation to ϕ3 correlators, could become more intricate at higher orders in perturbation theory. Several factors could contribute to this: Loop Corrections: While tree-level correlators exhibit remarkable simplicity, loop corrections could introduce new complexities. The integration over internal momenta in loop diagrams might obscure the connection to ϕ3 theory and necessitate the development of new techniques. Contributions from Non-Self-Dual Fields: As we move beyond the self-dual sector and incorporate the dynamics of non-self-dual fields, the interactions become more involved. This could lead to a proliferation of Feynman diagrams and a breakdown of the direct correspondence with ϕ3 correlators. Emergence of New Structures: Higher-order computations might reveal novel mathematical structures and symmetries that are not apparent at lower orders. These structures could either further simplify the correlators or introduce new layers of complexity. If the simplified structure does break down at higher orders, it would have several implications: Limits of the ϕ3 Analogy: It would suggest that the connection to ϕ3 theory is primarily a feature of the self-dual sector and might not extend straightforwardly to the full theory. Need for New Techniques: The breakdown would necessitate the development of more sophisticated techniques for computing and analyzing higher-order correlators. Deeper Understanding of the Self-Dual Sector: Conversely, it would highlight the special nature of the self-dual sector and its unique simplifications, prompting further investigation into the underlying reasons for this behavior. Ultimately, exploring higher-order corrections is crucial for determining the robustness of the observed structures and for gaining a more complete understanding of the interplay between self-duality, AdS geometry, and boundary correlators.

The potential connection between soft limits in self-dual AdS4 theories and asymptotic symmetries holds profound implications for our understanding of quantum gravity in asymptotically AdS spacetimes. Here's why: Holographic Soft Theorems: Soft theorems, which dictate the behavior of scattering amplitudes as the momentum of an external particle becomes soft, have been shown to be intimately linked to asymptotic symmetries in flat space. The observed soft limits in AdS4 self-dual theories suggest that a similar connection might exist in asymptotically AdS spacetimes. This could lead to a holographic interpretation of soft theorems, relating them to symmetries acting on the boundary of AdS. Constraints on the CFT: In the context of the AdS/CFT correspondence, asymptotic symmetries in the bulk gravity theory correspond to symmetries of the dual conformal field theory (CFT) living on the boundary. The connection between soft limits and asymptotic symmetries could therefore impose non-trivial constraints on the structure of the CFT, potentially leading to new insights into its dynamics and symmetries. Quantum Gravity in the Infrared: Soft theorems are often associated with the infrared structure of quantum gravity. Understanding their holographic interpretation in AdS could shed light on the long-distance behavior of gravity in asymptotically AdS spacetimes and its interplay with the UV degrees of freedom of the dual CFT. Emergent Spacetime: The connection between soft limits, asymptotic symmetries, and holography could provide further evidence for the idea that spacetime itself might be an emergent phenomenon. The symmetries of the boundary CFT, through their connection to soft limits, could dictate the structure of the emergent bulk spacetime. Exploring this potential connection further could lead to significant progress in several key areas of theoretical physics, including: Formulating a precise holographic dictionary for soft theorems in AdS. Uncovering new symmetries and structures in CFTs dual to asymptotically AdS spacetimes. Gaining a deeper understanding of the infrared structure of quantum gravity in AdS. Shedding light on the emergence of spacetime from entanglement and quantum information in holography. While much work remains to be done, the potential connection between soft limits and asymptotic symmetries in AdS4 self-dual theories offers a tantalizing glimpse into the profound interplay between gravity, quantum field theory, and holography.