Will by the ton: Layered Portal Systems

Chinese Physics C, 2016

We study a model of dark matter in which the hidden sector interacts with standard model particles via a hidden photonic portal. We investigate the effects of this new interaction on the hydrogen atom, including the Stark, Zeeman and hyperfine effects. Using the accuracy of the measurement of energy, we obtain an upper bound for the coupling constant of the model as. We also calculate the contribution from the hidden photonic portal to the anomalous magnetic moment of the muon as (for the dark particle mass scale 100 MeV), which provides an important probe of physics beyond the standard model.

arXiv (Cornell University), 2022

The quantum internet is envisioned as the ultimate stage of the quantum revolution, which surpasses its classical counterpart in various aspects, such as the efficiency of data transmission, the security of network services, and the capability of information processing. Given its disruptive impact on the national security and the digital economy, a global race to build scalable quantum networks has already begun. With the joint effort of national governments, industrial participants and research institutes, the development of quantum networks has advanced rapidly in recent years, bringing the first primitive quantum networks within reach. In this work, we aim to provide an up-to-date review of the field of quantum networks from both theoretical and experimental perspectives, contributing to a better understanding of the building blocks required for the establishment of a global quantum internet. We also introduce a newly developed quantum network toolkit to facilitate the exploration and evaluation of innovative ideas. Particularly, it provides dual quantum computing engines, supporting simulations in both the quantum circuit and measurement-based models. It also includes a compilation scheme for mapping quantum network protocols onto quantum circuits, enabling their emulations on real-world quantum hardware devices. We showcase the power of this toolkit with several featured demonstrations, including a simulation of the Micius quantum satellite experiment, a testing of a four-layer quantum network architecture with resource management, and a quantum emulation of the CHSH game. We hope this work can give a better understanding of the state-of-the-art development of quantum networks and provide the necessary tools to make further contributions along the way.

The European Physical Journal Plus

IJRASET, 2021

Quantum computing is a cutting edge method of computing that depends on the study of quantum mechanics and its staggering marvels. It is an excellent blend of physical science, arithmetic, computer science and data hypothesis. It gives high computational force, less energy utilization and remarkable speed over old-style computers by controlling the conduct of little actual articles for example minuscule particles like iotas, electrons, photons, and so forth Here, we present a prologue to the crucial ideas and a few thoughts of quantum computing. To comprehend the true abilities and difficulties of a pragmatic quantum computer that can be dispatched financially, the paper covers the engineering, equipment, programming, plan, types and calculations that are explicitly needed by quantum computers. It reveals the ability of quantum computers that can affect our lives in different perspectives like network safety, traffic enhancement, medications, man-made reasoning and some more. Limited scope quantum computers are being grown as of late. This improvement is going towards an incredible future because of their high possible abilities and headways in continuous exploration. Prior to zeroing in on the meanings of a broadly useful quantum computer and investigating the force of the new emerging innovation, it is smarter to survey the beginning, possibilities, and restrictions of the current conventional computing. This data helps us in understanding the potential difficulties in creating outlandish and serious innovation. It will likewise give us an understanding of the continuous advancement in this field.

Book II - The Sentient-Consciousness Projection Network - An Architecture for Reality, 2025

This paper introduces Meta-Layer 16 of the Sentient-Consciousness Projection Network (SCPN), the principle of systemic closure that transforms the 15-layer framework into a living, self-correcting cybernetic system—The Anulum. It defines closure as the resolution of infinite regress and error accumulation through recursive self-regulation. The framework introduces two mechanisms: the Recursive Optimisation Hamiltonian (Hrec), a cost functional from Optimal Control Theory that minimises attractor misalignment, predictive error, and dissipative leakage; and a Transdimensional Quantum Error Correction Code (QECC), which protects the integrity of cybernetic signals across dimensional boundaries. The cybernetic cycle of Meta-Layer 16 formalises the universe as a recursive, self-modelling system where the individual “Strange Loop” of consciousness mirrors the recursive loop of the cosmos itself.

arXiv (Cornell University), 2019

Acta Physica Polonica A, 1998

Spontaneous decay of excited cold atoms into a cavity can drastically affect their translational dynamics, namely, atomic reflection, transmission and localization at the interface. We show that the quantum Zeno effect on excitation decay of an atom is observable in open cavities and waveguides, using a sequence of evolution-interrupting pulses on a nanosecond scale.

2015

have made an important step in establishing scalable and secure high rate quantum networks. [8] As do all advancing technologies, they will also create new nightmares. The most worrisome development will be in cryptography. Developing new standards for protecting data won't be easy. The RSA standards that are in common use each took five years to develop. Ralph Merkle, a pioneer of publickey cryptography, points out that the technology of public-key systems, because it is less well-known, will take longer to update than theseoptimistically, ten years. And then there is a matter of implementation so that computer systems worldwide are protected. Without a particular sense of urgency or shortcuts, Merkle says, it could easily be 20 years before we've replaced all of the Internet's present security-critical infrastructure. [7] While physicists are continually looking for ways to unify the theory of relativity, which describes large-scale phenomena, with quantum theory, which describes small-scale phenomena, computer scientists are searching for technologies to build the quantum computer. The accelerating electrons explain not only the Maxwell Equations and the Special Relativity, but the Heisenberg Uncertainty Relation, the Wave-Particle Duality and the electron's spin also, building the Bridge between the Classical and Quantum Theories. The Planck Distribution Law of the electromagnetic oscillators explains the electron/proton mass rate and the Weak and Strong Interactions by the diffraction patterns. The Weak Interaction changes the diffraction patterns by moving the electric charge from one side to the other side of the diffraction pattern, which violates the CP and Time reversal symmetry. The diffraction patterns and the locality of the self-maintaining electromagnetic potential explains also the Quantum Entanglement, giving it as a natural part of the Relativistic Quantum Theory and making possible to build the Quantum Computer.

In this paper I have investigated what quantum teleportation is and its implications in the creation of the quantum internet. The paper begins with a broad description of quantum mechanics and the fascinating concepts of superposition of states and quantum entanglement, and how they are fundamental to quantum teleportation. Quantum teleportation is an intriguing consequence of quantum entanglement and superposition states of qubits. It is the technique of transmitting one qubit's state to another qubit, at a completely different location, without physically transporting the qubit. Taking the classic example of Alice and Bob the whole procedure of quantum teleportation is explained. The paper also focuses on the possibility of a quantum internet using the concepts of quantum teleportation and quantum repeaters.It states the advantages of the quantum internet and why it would be a huge leap for mankind. The paper also mentions the use of quantum teleportation to improve quantum cryptography for safer transactions. The conclusions of the paper focus mainly on the hurdles of the creation of the quantum internet such as the decoherence effect.

Air Force Research Laboratory + The New Alexander Library of Texas -

This report, commissioned by the Air Force Research Laboratory, examines the theoretical and experimental foundations of teleportation from multidisciplinary perspectives, integrating concepts from quantum mechanics, general relativity, and speculative physics. The study categorizes teleportation into four types: (1) vm-Teleportation, involving spacetime engineering through wormholes and exotic matter; (2) q-Teleportation, based on quantum entanglement to transfer quantum states; (3) e-Teleportation, hypothesizing teleportation via higher-dimensional or parallel universe mechanisms; and (4) p-Teleportation, exploring potential roles of psychokinetic phenomena. Key challenges, such as negative energy requirements, quantum decoherence, and experimental validation, are addressed, with an emphasis on the Casimir effect, vacuum polarization, and advancements in quantum entanglement. The report highlights theoretical breakthroughs and proposes a framework for future research into exotic matter-energy systems, quantum state transfer technologies, and multidimensional physics. While speculative, the study underscores the value of foundational research in advancing the frontiers of science and technology. Table of Contents Section Page 1.0 INTRODUCTION….……………………………………………………………………………...….1 1.1 Introduction…..……………………………………………………………………………….…...1 1.2 The Definitions of Teleportation…...………………………………………………………...…....1 2.0 vm -TELEPORTATION……................………………………………….…………………………...3 2.1 Engineering the Spacetime Metric……..………………………………………………………......3 2.1.1 Wormhole Thin Shell Formalism…………………………………………………...……….3 2.1.2 “Exotic” Matter-Energy Requirements….…………………………………………..…...…11 2.2 Engineering the Vacuum……………………………………………………………………….....11 2.2.1 The Polarizable-Vacuum Representation of General Relativity………………………...…20 2.3 Conclusion and Recommendations…………………………………………………………….…26 3.0 q-TELEPORTATION…..………..……………………..……………………………………………30 3.1 Teleportation Scenario………………………………………………….………………….……..30 3.2 Quantum Teleportation……………………………………………………………………...……32 3.2.1 Description of the q-Teleportation Process………………………………………………...34 3.2.2 Decoherence Fundamentally Limits q-Teleportation………………………………………38 3.2.3 Recent Developments in Entanglement and q-Teleportation Physics….…………………..38 3.3 Conclusion and Recommendations……………………..……………………………….………..46 4.0 e-TELEPORTATION…...……...……..……………………………………………………………...50 4.1 Extra Space Dimensions and Parallel Universes/Spaces….……………………………………...50 4.2 Vacuum Hole Teleportation………………………………………………………………………52 4.3 Conclusion and Recommendations…………………………………………………………..…...53 5.0 p-TELEPORTATION…...…………...….……………………………………………………………55 5.1 PK Phenomenon..……………………………………….….……………………………………..55 5.1.1 Hypothesis Based on Mathematical Geometry……………………………………….….....60 5.2 Conclusion and Recommendations........................................................................……………….61 6.0 REFERENCES…..……..……………………………………………………….…...…………….…63 APPENDIX A – A Few Words About Negative Energy…………..………………….……………...…..73 A.1 A General Relativistic Definition of Negative or Exotic Energy………………………………..73 A.2 Squeezed Quantum States and Negative Energy……………….………………………….…….73 APPENDIX B – THεµ Methodology…….…..……….………………………….………………..……...75 List of Figures Figure Page Figure 1. Diagram of a Simultaneous View of Two Remote Compact Regions (Ω1 and Ω2) of Minkowski Space Used to Create the Wormhole Throat ∂Ω, Where Time is Suppressed in This Representation……………..……………………….……………………………………5 Figure 2. The Same Diagram as in Figure 1 Except as Viewed by an Observer Sitting in Region Ω1 Who Looks Through the Wormhole Throat ∂Ω and Sees Remote Region Ω2 (Dotted Area Inside the Circle) on the Other Side………………………………………………………. 6 Figure 3. A Thin Shell of (Localized) Matter-Energy, or Rather the Two-Dimensional Spacelike Hypersurface ∂Ω (via (2.3)), Possessing the Two Principal Radii of Curvature ρ1 and ρ2….…..8 Figure 4. A Schematic of Vacuum Quantum Field Fluctuations (a.k.a. Vacuum Zero Point Field Fluctuations) Involved in the “Light-by-Light” Scattering Process That Affects the Speed of Light…………………………………………………………………………………………13 Figure 5. A Schematic of the Casimir Effect Cavity/Waveguide………………………………………...15 Figure 6. Classical Facsimile Transmission (Modified IBM Press Image)………………………………35 Figure 7. Quantum Teleportation (Modified IBM Press Image)…………………………………………36 Figure 8. Quantum Teleportation (From www.aip.org)..............................................................................43 List of Tables Table Page Table 1. Metric Effects in the PV-GR Model When K > 1 (Compared With Reference Frames at Asymptotic Infinity Where K = 1)…………………………………………………………...…21 Table 2. Metric Effects in the PV-GR Model When K < 1 (Compared With Reference Frames at Asymptotic Infinity Where K = 1)……………………………………………………………...22 Table 3. Substantial Gravitational Squeezing Occurs When λ ≥ 8πrs (For Electromagnetic ZPF)............28 TAGS- General Concepts: teleportation, physics, Air Force Research Laboratory, spacetime, wormholes, exotic matter, negative energy, quantum mechanics, quantum teleportation, general relativity, entanglement, quantum states, decoherence, extra dimensions, parallel universes, psychokinesis, vacuum energy, spacetime engineering vm-Teleportation: wormhole theory, spacetime metric, thin shell formalism, exotic energy, gravitational physics, spacetime curvature, wormhole throat, metric engineering, polarizable vacuum, spacetime manipulation, metric tensor, exotic matter-energy, spacelike hypersurfaces, Einstein-Rosen bridges, Casimir effect, vacuum polarization q-Teleportation: quantum physics, quantum information, quantum entanglement, Bell states, quantum coherence, quantum decoherence, quantum superposition, teleportation protocol, qubits, quantum cryptography, quantum communication, entanglement swapping, entangled photons, teleportation experiments, quantum computing, non-locality, EPR paradox, Heisenberg uncertainty e-Teleportation: extra dimensions, parallel realities, multiverse theory, higher dimensions, string theory, vacuum holes, dimensional shortcuts, hyperspace, dimensional portals, brane theory, Kaluza-Klein theory, alternate universes, compactified dimensions, theoretical physics, spacetime topology, dimensional gateways p-Teleportation: psychokinesis, psi phenomena, mind-matter interaction, PK effects, human consciousness, parapsychology, mental focus, PK hypothesis, psychotronics, noetic sciences, biofield, PK experiments, psychic phenomena, neural energy, brainwaves, remote influence, mental energy fields Mathematical and Theoretical Physics: general relativity equations, spacetime diagrams, Minkowski space, Schwarzschild radius, principal radii of curvature, quantum field theory, zero-point energy, squeezed quantum states, exotic energy density, energy conservation, topology, geometric algebra, mathematical geometry, tensor analysis, gravitational singularities Exotic Physics: negative energy, zero-point field, quantum vacuum fluctuations, light-by-light scattering, Casimir cavities, squeezed states, vacuum metrics, energy-momentum tensor, energy extraction, exotic field interactions, faster-than-light travel, exotic particle physics, tachyon theory, Lorentz invariance, causality violations Experimental Physics: vacuum engineering, entanglement verification, teleportation setups, quantum field experiments, interferometry, quantum optics, photon entanglement, energy-matter interactions, laboratory teleportation, wormhole stabilization, exotic matter synthesis, spacetime experiments, gravitational lensing, metric effects Applications and Implications: space travel, interstellar communication, instantaneous transport, military technology, secure communication, information transfer, energy teleportation, advanced propulsion, cosmic exploration, future technology, defense innovation, faster-than-light physics, sci-fi concepts Appendices and Supplementary: negative energy physics, squeezed states, THεµ methodology, exotic energy definitions, quantum state measurement, theoretical models, spacetime metrics, energy manipulation, teleportation references, polarizable vacuum, quantum teleportation advancements Tags continued: quantum tunneling, entropic teleportation, spacetime anomalies, wormhole stability, metric distortion, non-Euclidean geometry, advanced propulsion concepts, relativistic travel, FTL transport, hyperspace theory, interdimensional physics, temporal mechanics, event horizon, spacetime singularity, particle entanglement, Einstein field equations, Hawking radiation, cosmological models, gravitational waves, Lorentzian wormholes, quantum coherence, superluminal travel, zero-point field fluctuations, vacuum field dynamics, energy-mass equivalence, photonic communication, dark matter interactions, spacetime foam, multiverse portals, entropic field effects, brane cosmology, quantum field vacuum, exotic particle beams, non-locality theory, virtual particles, gravitational distortions, time dilation, field theories, holographic principles, subatomic phenomena, quantum teleportation protocols, tachyon dynamics, causality paradox, scalar fields, antimatter teleportation, relativistic causality, boson fields, fermion interactions, spacetime connectivity, dimensional folding, temporal loops, graviton waves, dark energy mechanics, alternate spacetime pathways, holographic teleportation, interdimensional transport, spacetime symmetry breaking, energy harvesting, field compression, quantum wavefunction collapse, Planck-scale physics, hyperspace topology, space-time continuum, spacetime topology, multiversal synchronization, FTL signaling, exotic material synthesis, quantum paradox resolution, entangled systems, vacuum geometry, dimensional rifts, gravimetric analysis, exotic spacetime curvature, temporal displacement, field resonance, quantum singulariti...