Strings and Things

  📖 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...

  📖 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...

  🚀 Developing a Unified Framework: From Pendulum Energy Coupling to Quantum Gravity To fully develop a Quantum Tensor Cosmology Model that connects Quantum Mechanics (QM) and General Relativity (GR) , we must start from a simple mechanical system —the pendulum . 🔷 Why the Pendulum? The pendulum embodies fundamental energy coupling between kinetic and potential energy. It represents a classical analog to quantum oscillations in field theories. It allows us to derive mathematical structures that can be extended to relativity and quantum gravity. 📖 Step 1: Understanding Energy Coupling in a Classical Pendulum The total energy of a simple pendulum with mass m m , length l l , and angle θ \theta from vertical is: E = K + U E = K + U where: Kinetic Energy K = 1 2 m v 2 = 1 2 m ( l θ ˙ ) 2 K = \frac{1}{2} m v^2 = \frac{1}{2} m (l \dot{\theta})^2 Potential Energy U = m g h = m g l ( 1 − cos ⁡ θ ) U = mgh = mg l (1 - \cos\theta) This system exhibits periodic energ...

The theory of evolution verses the second law of thermodynamics. The theory of evolution states that all life started spontaneously in one direction through a process of variation and natural selection, that is, over time a simple form of life will evolve into one that is irreducible and complex.   The second law of thermodynamics states, that for any natural process that occurs in an isolated system, the final state of the system is more disordered than the initial state. What is important here is the direction of the process. Each process points in the opposite direction and is considered irreversible, hence the term ‘irreducible complexity’, and increase randomness. Entropy is quantitative measure of randomness or disorder and the total entropy of the universe increases in the same direction over time. It increases.   The second law is also a statement of impossibility, meaning that, it is impossible for any spontaneous natural process to proceed in the opposite direction...