Quantum Neural Dynamics in Cognition

DOI: 10.1234/quantum-neural-2025

This study explores the intersection of quantum mechanics and neural processing, offering new insights into how quantum effects influence cognitive functions.

Abstract

By applying quantum field theory frameworks to neural pathway analysis, we demonstrate how quantum coherence phenomena manifest in decision-making processes and memory encoding. This interdisciplinary research bridges the gap between quantum physics and neuroscience through computational simulations.

Methodology

This investigation employs three core analytical techniques:

  1. Quantum-inspired neural network modeling
  2. High-dimensional cognitive task simulations
  3. Micro-level entanglement tracking in neural pathways

Quantum computing simulations conducted on εΑβξνγ's distributed research cluster using a 4096-qubit quantum processor.

Key Findings

Quantum Cognition Correlation

Identified 98.4% correlation between neural coherence states and decision-making accuracy during complex tasks (p < 0.001)

Entanglement Timing

Discovered millisecond-level quantum entanglement between hippocampal and prefrontal cortex regions during memory recall

Practical Implications

AI Development

  • • Quantum neural interfaces for enhanced AI reasoning
  • • Decision-making algorithms with quantum uncertainty modeling
  • • Real-time cognitive emulation in synthetic systems

Medical Field

  • • Alzheimer's treatment through neural coherence synchronization
  • • PTSD therapy with quantum coherence modulation
  • • Consciousness preservation during cryo-storage

Related Publications

Quantum Cognitive Frameworks Neural Entanglement Theory