Research Interests

Black Holes

Black hole research delves into understanding the complex processes behind the formation and evolution of these massive celestial objects. Unraveling their origins and the mechanisms governing their behavior can provide invaluable insights into the fundamental principles that govern the universe.

Specifically, I am interested in finding horizon-less, singularity-ridden solutions to Einstein equations in String Theory which mimic classical black holes in Thermodynamics. These solutions have two significant advantages: First, they address the Black Hole Information Paradox, and second, they provide new insights into the framework of String Theory.

Read this: https://arxiv.org/abs/2305.12003v2

String Cosmology

The primary motivation driving this fascinating direction of research is to gain profound insights into the very origins of time itself. String cosmology, with its intriguing concepts and theoretical frameworks, holds the potential to unravel the enigmatic initial conditions that gave rise to our universe. By delving into these fundamental origins, we may take a significant step forward in comprehending the essence of the arrow of time.

In summary, the focus on understanding the beginnings of time through the lens of string cosmology offers an enticing opportunity to explore the underlying fabric of our reality, pushing the boundaries of human knowledge and enriching our understanding of the universe's majestic unfolding.

Time

The exploration of the arrow of time is a captivating journey that beckons researchers to fathom the profound concept of temporal asymmetry in our universe. The motivation behind studying the arrow of time is to grasp the fundamental nature of time's unidirectional flow, which contrasts with the symmetric laws governing most physical processes at the microscopic level.

The quest to unravel the arrow of time has spurred groundbreaking research, delving into the realms of quantum mechanics, statistical mechanics, and cosmology. Moreover, advances in understanding temporal asymmetry could have practical applications in fields such as quantum computing and communication.