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Research Paper#Holography, Quantum Field Theory, Supergravity, Giant Gravitons🔬 ResearchAnalyzed: Jan 3, 2026 06:16

Semiclassical Probes and Extremal Correlators

Published:Dec 31, 2025 17:25
1 min read
ArXiv

Analysis

This paper addresses inconsistencies in previous calculations of extremal and non-extremal three-point functions involving semiclassical probes in the context of holography. It clarifies the roles of wavefunctions and moduli averaging, resolving discrepancies between supergravity and CFT calculations for extremal correlators, particularly those involving giant gravitons. The paper proposes a new ansatz for giant graviton wavefunctions that aligns with large N limits of certain correlators in N=4 SYM.
Reference

The paper clarifies the roles of wavefunctions and averaging over moduli, concluding that holographic computations may be performed with or without averaging.

PermalinkArXiv
Physics#Supergravity, Domain Walls, Holography🔬 ResearchAnalyzed: Jan 3, 2026 17:09

Non-SUSY Domain Walls in ISO(7) Gauged Supergravity

Published:Dec 31, 2025 08:04
1 min read
ArXiv

Analysis

This paper explores non-supersymmetric domain walls in 4D maximal ISO(7) gauged supergravity, a theory derived from massive IIA supergravity. The authors use fake supergravity and the Hamilton-Jacobi formalism to find novel domain walls interpolating between different AdS vacua. The work is relevant for understanding holographic RG flows and calculating quantities like free energy and anomalous dimensions.
Reference

The paper finds novel non-supersymmetric domain walls interpolating between different pairs of AdS extrema.

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Research Paper#Theoretical Physics, Supergravity, Black Holes, Higher-Form Symmetries🔬 ResearchAnalyzed: Jan 3, 2026 16:25

Higher-Form Symmetries in Supergravity and Black Hole Thermodynamics

Published:Dec 27, 2025 11:45
1 min read
ArXiv

Analysis

This paper explores the relationship between higher-form symmetries, scalar charges, and black hole thermodynamics in the context of 5-dimensional supergravity and its dimensional reduction to 4-dimensional supergravity. It investigates the role of symmetries, including higher-form symmetries, in determining the behavior of black holes and their thermodynamic properties. The study focuses on the connection between 5D and 4D quantities and the constraints required for consistency. The results are generalized to Einstein-Maxwell-like theories.
Reference

The paper finds that a 2-dimensional subgroup of SL(2,R) acts as a higher-form symmetry group and computes Smarr formulas for black holes, showing their equivalence under specific field constraints.

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Research#Supergravity🔬 ResearchAnalyzed: Jan 10, 2026 09:19

Supergravity Insights from Calabi-Yau Modularity

Published:Dec 20, 2025 00:26
1 min read
ArXiv

Analysis

This ArXiv article explores a highly specialized area of theoretical physics, bridging supergravity and string theory through the mathematical properties of Calabi-Yau threefolds. The research focuses on the implications of modularity for understanding fundamental physical phenomena.
Reference

The article's context revolves around using the modularity of Calabi-Yau threefolds.

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Research#physics🔬 ResearchAnalyzed: Jan 4, 2026 09:25

The Use of Torsion in Supergravity Uplifts and Covariant Fractons

Published:Dec 18, 2025 04:37
1 min read
ArXiv

Analysis

This article likely explores advanced theoretical physics, specifically focusing on the role of torsion in supergravity models and its connection to covariant fractons. The subject matter is highly specialized and requires a strong background in theoretical physics and mathematics. The title suggests a focus on mathematical frameworks and their physical implications.

Key Takeaways

    Reference

    PermalinkArXiv
    Science & Technology#Physics/AI📝 BlogAnalyzed: Dec 29, 2025 17:42

    Jim Gates: Supersymmetry, String Theory, and Proving Einstein Right

    Published:Dec 25, 2019 16:09
    1 min read
    Lex Fridman Podcast

    Analysis

    This article summarizes a podcast episode featuring Jim Gates, a theoretical physicist, discussing his work on supersymmetry, supergravity, and superstring theory, as well as his involvement in a book about proving Einstein's theory of relativity. The episode, part of the Artificial Intelligence podcast, touches upon various topics related to physics, cosmology, and the potential of artificial intelligence. The article provides a brief overview of the episode's content, including questions about space exploration, the search for extraterrestrial life, and the nature of consciousness. It also includes links to the podcast and its sponsors.
    Reference

    The article doesn't contain any direct quotes.

    PermalinkLex Fridman Podcast