ABOUT ME
Postdoctoral Researcher
Instituto de Física Teórica (IFT)
Universidad Autónoma de Madrid
Consejo Superior de Investigaciones Científicas
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
My research is based on quantum field theory, information theory, and gauge/gravity duality to pursue the theoretical description of
foundational nature of spacetime, quantum gravity
fundamental aspects of strongly coupled quantum physics
Quantum Information & Gravity
I am interested in general inquiries pertaining to the interplay between quantum information theory and gravity. These topics include
developing measures of entanglement (& complexity) from both quantum field theories and gravitational theories
physical application of quantum information theory in both quantum mechanical and black hole physics
information-theoretic constraint on strongly coupled field theories
In recent years, I have been particularly interested in exploring complexity in quantum field theory and gravity for its relation with many-body quantum chaos, as well as entanglement entropy for the black hole information paradox and its role in illuminating the emergent spacetime.
Quantum information technology, including neural networks & deep learning, quantum communication, and phenomena related to traversable wormholes, is also of interest. It not only offers a new perspective on emergent spacetime arising from quantum entanglement but also aids in the development of more realistic gravitational models for particle physics and condensed matter physics.
Strongly Coupled Physics & Black Holes
I am interested in developing phenomenological gravitational theory that can produce consistent results with experimental findings and other effective field theories (e.g., hydrodynamics and Ginzburg-Landau theory). These topics include
fundamental bounds of diffusion constant observed from quark-gluon plasma and condensed matter theories including SYK models
anomalous transport phenomenology from strange metals and high-temperature superconductors
collective dynamics out of equilibrium from strongly interacting fluids and condensed matter
In recent years, I have been particularly interested in elucidating the intricate relationship between transports, many-body chaos and hydrodynamics, as well as the near-equilibrium collective dynamics in strongly coupled matters (e.g., Anderson-Higgs mechanism in high-temperature superconductors), which play a pivotal role in the realm of elementary particle physics.
