Exploring Quantum Heider Balance Theory

TL;DR

This paper extends classical Heider balance theory into the quantum domain, modeling social triads as quantum states to explore superposition, entanglement, and phase transitions in social network dynamics.

Contribution

It introduces a quantum framework for social balance, incorporating superposition and entanglement, and analyzes quantum phase transitions in social networks.

Findings

Quantum superposition and entanglement states emerge in social triads.

Phase transitions occur as a function of quantum temperature.

Novel dynamical behaviors are identified in quantum social systems.

Abstract

Classical Heider balance theory models the evolution of social networks towards balanced states with stress minimization. Triad relationships are classically either balanced or imbalanced. However, real-world relationships often exhibit uncertainty, complexity, and interconnected dynamics that transcend this classical framework, and we will sometimes see the synchronicity of balance and imbalance states. When these triadics are simultaneously balanced and imbalanced, they form superposition and entanglement states that necessitate the introduction of quantum balance. This study introduces a framework that extends classical Heider balance theory from social network analysis by incorporating principles of quantum mechanics. In the framework, each triad is a quantum state of spin systems embedded in various network topologies. Using a quantum transformation operator, we investigate the emergence of balanced and imbalanced states and identify ground and steady states. In the quantum state, developments towards balance will occur by introducing the Hamiltonian within the creation and annihilation operators framework. In these developments, we witness the emergence of superposition and entanglement quantum states with no classical equivalent, which form an uncertainty in the states. When the quantum evolution is a functional temperature, we investigate the emergence of balanced and imbalanced states, analyze ground and steady states, and examine phase transitions as a function of temperature. Our results reveal novel dynamical behaviors unique to quantum social systems and offer a new perspective on collective decision-making, conflict resolution, and emergent order in complex networks.