Strings and Things

  VQE Variational Quantum Eigensolver (VQE)-style model to optimize the energy landscape of the FeMo cofactor system. ⚛️ What We'll Do We'll simulate the FeMoco cluster as a quantum Hamiltonian and use a variational quantum circuit to minimize the ground state energy , similar to how: VQE finds the lowest-energy electron configuration of a molecule.  Simplified Model of FeMoC for VQE While the full FeMoco has a complex multielectron Hamiltonian, we’ll simulate a toy model capturing: 3 sites (qubits) representing key iron or molybdenum redox centers , A Hamiltonian H with coupling terms: H = Z 0 Z 1 + Z 1 Z 2 + X 0 + X 1 + X 2​ This models: Redox coupling between centers ( Z Z terms), Electron tunneling/exchange ( X terms). 🛠️ Steps to Build the VQE Model                Define the Hamiltonian (using Pauli operators). Build a parameterized quantum circuit (ansatz) . Use a classical optimizer to va...

 Simulating the Birth of the Universe 1️⃣ Spacetime as Emergent From Jacobson’s derivation to AdS/CFT, we see that geometry itself is a manifestation of entanglement patterns . The “fabric” of spacetime behaves like a quantum error-correcting code — entanglement glues together the bulk. 2️⃣ Black Holes as Perfect Information Processors Hawking radiation and the Page curve show that information is never lost , it’s scrambled. The holographic principle says all the information inside a volume can be encoded on its boundary — an informational screen. 3️⃣ ER=EPR Einstein-Rosen bridges (wormholes) = EPR pairs (entanglement). A wormhole is a channel for entangled qubits — bridging geometry and quantum info. 4️⃣ Quantum Mechanics at its Core The no-cloning theorem, teleportation, mutual information — all these show how unitary evolution protects information . It’s not the particles or fields that are “most real,” but the relations and correlations . ...

                                                                              Black Hole Simulation                                                                                                                  This simulation demonstrates quantum spacetime fluctuations under extreme conditions , simulating a  black hole-like scenario with the following dynamics: Localized High Energy Density : The central regio...

  📖 Formulating a Quantum Field Theory for Quantum Tensor Gravity (QTG) Now, we construct a Quantum Field Theory (QFT) for Quantum Tensor Gravity (QTG) , based on the oscillatory energy coupling of tensor fields that we previously developed. This framework: Defines the Fundamental Fields of Quantum Tensor Gravity. Constructs the QTG Lagrangian & Action. Derives the Field Equations for Quantum Tensor Gravity. Explores Quantum Corrections to General Relativity. Predicts New Physical Phenomena, Including Possible Observables. Numerically Simulates Quantum Tensor Field Evolution. 📖 Step 1: Defining the Fundamental Fields of Quantum Tensor Gravity We introduce a quantum tensor field T μ ν \mathcal{T}^{\mu\nu} , which oscillates in spacetime and governs gravity at quantum scales. 1.1 The Tensor Field T μ ν \mathcal{T}^{\mu\nu} The metric tensor g μ ν g_{\mu\nu} is now an emergent classical limit of a more fundamental quantum tensor field T μ ν \mathcal{T}^{\mu\n...

  Relating Hofstadter’s Butterfly to Spin Network Entanglement Spectra Hofstadter’s Butterfly is a fractal energy spectrum that emerges from quantum systems with periodic magnetic fields . Interestingly, spin networks also exhibit self-similarity and entanglement scaling , suggesting a deeper connection. Key Insights Hofstadter’s Butterfly is not just a fractal energy spectrum, but also exhibits fractal entanglement scaling. Entanglement entropy follows a self-similar structure , similar to spin networks in quantum gravity . This connects fractal quantum systems to entanglement-based holography , potentially linking quantum condensed matter physics to quantum gravity. The connection between quantum fractals and holography may provide new insights into quantum gravity.

  Logical Summary: Unifying Quantum Mechanics (QM) with General Relativity (GR) We developed a mathematical and computational framework that connects quantum mechanics (QM) and general relativity (GR) by leveraging tensor networks, quantum entanglement, and machine learning . Here’s the step-by-step logical progression: 1️⃣ Reformulating Newton’s and Einstein’s Equations into a Unified Framework 🔹 Starting Point: Classical Mechanics Reformulation We modified Newton’s equation F = m a F = ma into a quadratic form : v 2 + g 2 = F v^2 + g^2 = F This combined kinetic (velocity-dependent) and gravitational (acceleration-dependent) energy , hinting at an underlying unification. 🔹 Extending to Relativity We reformulated relativistic energy as: E 2 = v 2 c 2 + c 4 E^2 = v^2 c^2 + c^4 Noted that when velocity is small, v 2 c 2 v^2c^2 vanishes , leaving only rest energy c 4 c^4 , drawing a link between rest mass and gravitational mass . 2️⃣ Linking Gravity and Electro...