Frontiers in Quantum Computing

Contents
Preface
Chapter 1
Quantum (Hyper)Computation by Means of Water Coherent Domains – Part I: The Phsyical Level
Abstract
An Overview of QED Coherence in Matter and the Dynamics of Coherent Liquid Water
Quantum Dynamics of Coherent Domains in Liquid Water
Spatial Behavior of the Coherent Electromagnetic Field
Thermodynamics of “Interfacial” Water
Excited Spectrum of Coherent Domains in Water
The Quantum Tunneling – Coupling Interaction between Water Coherent Domains
Quantum Dynamics of “Evanescent” Electromagnetic Fields and the Tunneling of Virtual Photons
Quantum Coupling between Water Coherent Domains and Their Interaction through Virtual Photons
Conclusion
References
Chapter 2
The Quantum Phase Operator and Its Role in Quantum Computing
Abstract
Introduction
Coherent Quantum States
The Quantum Phase Operator
Phase - Shift Operator and Its Effect on the Coherent Domains
Phase Operator, Time-Evolution and Quantum Computing
Conclusion
References
Chapter 3
Quantum (Hyper)Computation by Means of Water Coherent Domains – Part II: The Computational Level
Abstract
Introduction
The Amplification and Stabilization of Tunnelling – Coupling Interaction between Water Coherent Domains
Universal Quantum (Hyper) Computation by Water Coherent Domains
The Concept of Universal Quantum Computation
The Realization of Two-Qubits Quantum Gates through Water Coherent Domains
The Realization of Single Qubit Quantum Gates through Water Coherent Domains
Controlling Quantum Gates Composed of Water Coherent Domains
Speed and Memory of Quantum Computation through Tunneling - Coupled Water Coherent Domains
Conclusion
References
Chapter 4
Computing Hyperincursive Discrete Relativistic Quantum Majorana and Dirac Equations and Quantum Computation
Abstract
1. Introduction
2. Presentation Step by Step of the Two Incursive Discrete Harmonic Oscillators
3. The Two Dimensionless Incursive Discrete Harmonic Oscillators
4. Rotation of the Incursive Discrete Oscillators to Recursive Discrete Oscillators
5. The Hyperincursive Discrete Klein-Gordon Equation Bifurcates to the Majorana and Dirac Relativistic Quantum Equations
6. The Hyperincursive Discrete Klein-Gordon Equation Bifurcates to the 16 Proca Equations
7. Chiral Representation of the Majorana Equations in 2 Components
8. Solutions of the Non-Relativistic Quantum Majorana and Dirac Equations
9. The Generic Majorana 4-Spinors Equation
10. The Generic Dirac 4-Spinors Equation
11. A New Invariant of the Non-Relativistic Quantum Majorana and Dirac Wave Functions
12. Quantum Computation with Reversible Gates
References
Chapter 5
Quantum Computing and the Quantum Mind: A New Approach to Quantum Gravity
Abstract
1. Introduction
2. The “BIG WOW” and the Quantum Mind
3. The Non-Algorithmic Side of the Mind
4. The QML is Physically Interpreted as a Dissipative Quantum Field Theory (DQFT) of the Brain
5. Quantum Logic, the Collective Unconscious and the Biological Basis of Psychopathology
6. Entangled Spacetime
7. Meta-Entanglement
References
Chapter 6
Can Instantaneous Quantum Algorithms Be Developed?
Abstract
Introduction
Realistic Quantum Algorithms
Fourier Transform Based Algorithms
Exponential Speed-Up of Processing
Holographic Algorithms
Ontological-Phase Holographic IQCA
Bohm and Istantaneous Algorithms
Evolution of M-Theory
Lorentz Condition in Complex 8-Space and Tachyonic Signaling
Instantaneity in Complex 8-Space
Conclusion
References
Chapter 7
Sentient Androids
Abstract
Introduction
Extracellular Containment of Natural Intelligence
New Direction for Mind-Body Research
Mind-Body Problem-Nature of Sentience
Physical Basis of Qualia
Psychon Unit Measuring Energy of Mind
Testing Unified Field Theory
Bulk Universal Quantum Computing
The Case For Relativistic Qubits
The Noetic Transformation
QC P Operational Android Design
Conclusion – Criteria for Sentience
References
Chapter 8
Imminent Advent of Universal Quantum Computing (UQC)
Abstract
Introduction – Bits, Qubits and XD Space
Overview of QC Architecture
Quantum Logic Gates and Properties
Evading Uncertainty and Decoherence
P Experimental Design
Measurement with Certainty
The Problem of Decoherence
Quantum Phenomenology – UFM Ontology
Empirical Tests of UFM
References
Chapter 9
Brain - Quantum Hypercomputing System
Abstract
Introduction
What Is a Quantum Computer?
Signal Processing by Using Tunneling Photons
Energy Cost for Quantum Computation Utilizing Tunneling Photons
Decoherence Problem of Quantum States to Conduct Quantum Computation
Possibility of Quantum Computation inside Microtubles in the Brain
Difficulties of the Orch OR Model Proposed by Penrose
High Performance Computation in the Brain Utilizing Tunneling Photons
Holographic Memory in Human Biological Systems
Mechanism of Holographic Memory Based on Evanescent Superluminal Photons in the Microtubule
Holonomic Model of the Brain Function
Hypercomputing by Superluminal Particles
Computational Time Required to Perform Infinite Steps of Computation
Computational Time by Using Superluminal Elementary Particles
Human Intuition from the Standpoint of Superluminal Hypercomputation
Discussion and Conclusion
References
Chapter 10
Parametric Resonance and Particle Stochastic Interactions with a Periodic Medium
About the Editor
Index
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