I'm a theoretical physicist currently working on quantum gravity and black hole thermodynamics. My current work focuses on exploring connections between quantum error correction, loop quantum gravity, and black hole physics. My research aims to understand how quantum gravity emerges from more fundamental building blocks, particularly through the lens of quantum information theory and error correction. I've published extensively on black hole thermodynamics, investigating phase transitions and critical behavior of various black hole solutions. I've also made contributions showing how elementary particles can be viewed as quantum computational gates in a loop quantum gravity framework.
More recently, I've been studying the thermodynamic geometry and microscopic structure of black holes in massive gravity and anti-de Sitter spacetimes. This work explores how quantum gravitational effects manifest in black hole physics and aims to better understand the connection between gravity, quantum mechanics, and information theory. I'm particularly interested in how quantum error correction principles may help explain the emergence of classical spacetime geometry.
C. Rizwan, D. Vaid
D. Vaid
D. Madison, A. Dasgupta, K. Bartschat, D. Vaid
A. Dasgupta, K. Bartschat, D. Vaid, A. Grum-Grzhimailo, D. Madison, M. Blaha, J. Giuliani
A. Dasgupta, K. Bartschat, D. Vaid, A. Grum-Grzhimailo, D. Madison, M. Blaha, J. Giuliani
C. Rizwan, A. Kumara, D. Vaid
S. Alexander, Tirthabir Biswas, A. Notari, D. Vaid
D. Vaid