ABOUT ME
Postdoctoral Researcher
Instituto de Física Teórica (IFT)
Universidad Autónoma de Madrid
Consejo Superior de Investigaciones Científicas
I am a Severo-Ochoa Postdoctoral Fellow at the Institute for Theoretical Physics (IFT) UAM-CSIC in Madrid, specializing in quantum field theory, gravity, and quantum information theory. My research primarily utilizes holography (AdS/CFT) to explore quantum gravity and model the dynamics of strongly interacting quantum field theories. My current research interests include:
Entanglement, quantum information, and holography
Anomalous transport, hydrodynamics, and non-equilibrium dynamics
Quantum chaos and black holes
My recent papers, available on the INSPIRE-HEP database, provide interesting findings relevant to these areas of research.
Research Topics
Holographic Principle
Holographic principle
Gauge/gravity duality
AdS/CFT correspondence
String theories and quantum gravity
Quantum Information
Measures of quantum entanglement
Complexity in field theory and gravity
Many-body entanglement, chaos, and holographic theories
Black hole information paradox
Strongly Coupled Physics
Collective dynamics near equilibrium
Many-body chaos and hydrodynamics
Anomalous transport phenomenology
Fundamental bounds of transport
Featured Research
Quantum Gravity and Quantum Information Science
I am interested in the interplay between quantum information theory and gravity to address fundamental challenges in quantum gravity. Key areas of interest include:
Emergent space-time :
Investigating holographic gravity duals arising from diverse entanglement measures (e.g., entanglement/reflected entropy).
The construction of bulk space-time from boundary data utilizing machine learning techniques.
Quantum nature of black holes :
Studying the black hole information paradox, particularly focusing on entanglement entropy and Page curve.
Analyzing the properties of black hole horizons and the role of quantum chaos (e.g., maximal chaos and butterfly velocity).
Developing and studying toy models to understand aspects of quantum black holes (e.g., Fuzzballs and spectral features).
Singularity :
Examining the Kasner universe model and the interiors of black holes.
Employing information-theoretic methods to probe and explore various types of singularities.
Strongly Interacting Systems, Black Holes, and Effective Field Theories
I am dedicated to developing holographic gravitational models that align with experimental data from strongly coupled systems and effective field theories. Additionally, I am interested in applying the idea of quantum information theory to the study of quantum field theories (QFTs).
Transport phenomenology :
Investigating anomalous transport phenomena in high-Tc superconductors and non-Fermi liquids.
Establishing fundamental bounds on the diffusion constant.
Hydrodynamics and non-equilibrium dynamics :
Exploring hydrodynamics and effective field theories with broken symmetries (e.g., magneto-hydrodynamics, Ginzburg-Landau theory of high-Tc superconductor).
Studying collective excitations of strongly coupled systems and quasi-normal modes in holography.
Quantum complexity and many-body entanglement in holographic theories :
Examining the intricate relationships between Krylov complexity, quantum chaos and conventional observables in QFTs (or quantum mechanics) such as correlation functions.
Analyzing how internal and spacetime symmetries, as well as RG flows, affect measures of entanglement and complexity across different phases of strongly coupled systems in holography.