Preface to the Special Issue: Quantum Probability and Randomness V

This study investigates the generation of a three-qubit GHZ state using digitized adiabatic quantum computing. The authors analyze the dynamics of entropy, fidelity, and entanglement throughout the adiabatic process, providing insights into the efficiency and reliability of this quantum computing approach.

This paper explores the hypothesis that human judgments of real versus fake faces exhibit quantum-like contextuality. Through experimental data and analysis, the authors demonstrate that these judgments cannot be fully explained by classical probability theory, suggesting the need for quantum-inspired models in cognitive science.

The authors examine the interplay between Bohmian mechanics and quantum entanglement in a two-qubit system. They identify critical points in the Bohmian flow and analyze their relationship with the onset of chaos, providing a deeper understanding of quantum dynamics in entangled systems.

This article reinterprets the double-slit experiment by establishing a novel connection between the experiment and quantum entanglement. The author argues that this perspective offers new insights into the fundamental nature of quantum phenomena and challenges traditional interpretations.

The paper presents a path integral approach to describing the motion of quantum particles. By analyzing the probabilities of various paths, the author provides a comprehensive framework for understanding quantum trajectories and their implications for quantum mechanics.

This work introduces a semi-device-independent randomness expansion protocol utilizing parity-oblivious quantum random access codes. The authors demonstrate how true quantum randomness can be certified through the violation of a two-dimensional quantum witness, enhancing the robustness of randomness generation.

The authors explore the information-theoretic properties of separable quantum processes, focusing on intrinsic and measured information. They provide methods for approximating information sources with independent and identically distributed models, offering insights into the structure of quantum stochastic processes.

This paper discusses the relativistic transformation properties of quantum stochastic calculus. The author derives the transformation rules between inertial observers and examines the implications for quantum open system dynamics in relativistic contexts.

The study introduces the concept of chromatic quantum contextuality, extending the framework of quantum contextuality to include color-based structures. The author explores the implications of this extension for understanding the non-locality and non-contextuality in quantum systems.

This article addresses the problem of fitting copulas with maximal entropy. The author presents methods for constructing copulas that maximize entropy, providing tools for modeling dependencies in multivariate distributions within the context of quantum information theory.

The paper extends the concept of quantum contextuality to higher dimensions using hypergraphs. The author develops operator inequalities and explores their applications, offering a geometric perspective on quantum contextuality and its implications for quantum mechanics.

This study investigates the problem of the existence of a joint distribution on quantum logic. The author examines the conditions under which such distributions can exist, contributing to the understanding of the foundations of quantum probability theory.

The authors discuss statistical methods for testing random number generators and propose improvements using randomness extraction techniques. They highlight the importance of these methods in ensuring the reliability and security of quantum random number generation.

This paper explores the effects of the quantum vacuum on a cosmic scale, particularly in relation to dark energy. The author examines how quantum fluctuations contribute to the accelerated expansion of the universe, offering insights into the interplay between quantum mechanics and cosmology.

The study analyzes the statistical properties of superpositions of coherent phase states with opposite arguments. The author investigates the implications for quantum coherence and interference, providing a deeper understanding of quantum state superpositions.

This article examines negative result experiments in quantum mechanics, focusing on their role in testing the foundations of quantum theory. The author discusses the significance of these experiments in challenging and refining quantum mechanical models.

The paper introduces the concept of conditional values in quantum mechanics, extending the framework of quantum measurements. The author explores how these values can be used to model conditional probabilities and their implications for quantum state determination.

This study identifies statistical signatures of quantum contextuality, providing experimental criteria for detecting contextual effects in quantum systems. The author discusses the significance of these signatures in understanding the non-classical nature of quantum mechanics.

The authors investigate the correlations in the EPR state observables, focusing on the violation of Bell inequalities. They analyze the implications for quantum entanglement and non-locality, contributing to the foundational understanding of quantum correlations.

This paper presents a group-algebraic formalism of quantum probability, applying it to quantum statistical mechanics. The author develops a framework for understanding quantum probabilities in terms of group theory, offering new perspectives on quantum statistical systems.