Providing specific energy levels and experimental strategies for testing Vibrational Field Dynamics (VFD) predictions at the Large Hadron Collider (LHC) Abstract The Vibrational Field Dynamics (VFD) framework offers a novel approach to particle physics by modeling particles as manifestations of underlying vibrational fields. This article provides detailed predictions from the enhanced VFD model, focusing on…

The following table lists all the known particles from the Standard Model and new particles predicted by the Vibrational Field Dynamics (VFD) framework that could potentially be discovered at the Large Hadron Collider (LHC). For each particle, we provide its name, symbol, mass, electric charge, spin, status, possible production mechanisms at the LHC, and additional…

October 30, 2024 Introduction In the ever-evolving field of particle physics, the quest to uncover the fundamental constituents of matter continues to drive theoretical and experimental research. Vibrational Field Dynamics (VFD) offers a novel perspective by modeling particles as manifestations of vibrational energy modes within a field. This article explores a prediction made by the…

In physics, accurately determining the mass of particles like protons and neutrons requires going beyond simple calculations. Vibrational Field Dynamics (VFD) offers a robust framework grounded in first principles, incorporating vibrational modes, ground states, gravity, and negative energy to explain particle mass with unprecedented accuracy. What is Vibrational Field Dynamics (VFD)? VFD views particles as…

Introduction In the realm of particle physics, understanding the mass of fundamental particles like protons and neutrons is crucial for comprehending atomic structure and the forces governing it. The accepted masses are approximately: This article revisits the modeling of proton and neutron masses using Vibrational Field Dynamics (VFD), incorporating a refined approach that calculates vibrational…

Introduction This model is already outdated – see here for the new model (https://vibrationalfielddynamics.org/modeling-proton-and-neutron-masses-using-vibrational-field-dynamics-an-improved-approach/) In the realm of particle physics, the mass of the proton is a fundamental constant that plays a crucial role in our understanding of atomic structure and the forces that govern it. The accepted mass of the proton is approximately 938.272…

Introduction to Vibrational Field Dynamics (VFD) Context and Motivation In the quest to unify the fundamental forces and particles that govern the universe, quantum field theory (QFT) and the Standard Model of particle physics have been immensely successful but remain incomplete. Despite accurately predicting many observable phenomena, these models struggle with certain inconsistencies, particularly when…

Reinterpreting the Building Blocks of Matter as Resonant Field Nodes In Vibrational Field Dynamics (VFD), quarks—the fundamental particles forming protons, neutrons, and other hadrons—are reimagined as localized vibrational nodes within a unified field. Instead of existing as isolated particles with static properties, quarks in VFD are understood as resonant points that, when combined in specific…

Exploring Potential Discoveries Inspired by the VFD Framework In Vibrational Field Dynamics (VFD), the universe is understood as a unified vibrational field where resonances create the effects we observe as forces, particles, and even mass. This framework offers unique predictions for observable phenomena, proposing new ways to understand concepts like dark matter, dark energy, quantum…

Understanding Mass and the Higgs Field Through Vibrational Resonance In Vibrational Field Dynamics (VFD), the Higgs boson and Higgs field are reinterpreted as expressions of vibrational alignment within the universal field. Instead of viewing the Higgs boson as an isolated particle that interacts with a separate field, VFD sees the Higgs as a specific vibrational…