Quantum complexity is emerging as a key property of many-body systems, including black
holes, topological materials, and early quantum computers. A state's complexity quantifies …

We investigate the thermodynamic constraints on the pivotal task of entanglement
generation using out-of-equilibrium states through a model-independent framework with …

The second law of thermodynamics imposes a fundamental asymmetry in the flow of events.
The so-called thermodynamic arrow of time introduces an ordering that divides the system's …

Resource theory is a general, model-independent approach aiming to understand the
qualitative notion of resource quantitatively. In a given resource theory, free operations are …

Estimating the greenhouse gas emissions of research-related activities is a critical first step
towards the design of mitigation policies and actions. Here we propose and motivate a …

Recently, new insights have been obtained by jointly studying communication and resource
theory. This interplay consequently serves as a potential platform for interdisciplinary …

We investigate the thermodynamic constraints on the pivotal task of entanglement
generation using out-of-equilibrium states through a model-independent framework with …

Tensor networks are an invaluable tool for the study of quantum systems. In this thesis we
use tensor networks, and more directly matrix product states, to simulate both open and …

(English) As one of our most successful theories, quantum theory has greatly strengthened
our understanding of nature and significantly advanced technologies. Specifically, quantum …

Quantum thermodynamics is a blossoming research program that uses tools and ideas from
quantum information theory to extend the laws of thermodynamics to the domain of systems …