Saleh Ali Al Hamed

Work

Subjects:

Physical Sciences

Research Keywords:

Al-Hamed Equation, Nuclear Energy, Electro-Nuclear Energy, Nuclear Fission, Nuclear Fusion, Atomic Mass, Nuclear Mass, Mass-Energy Equivalence, Friction-inclusive Newtonian Dynamics, Modified Newton's Second Law, Secondary Particles in Nuclear Reactions, Mesons and Neutrons in Fission/Fusion, Charge and Voltage Contribution, Electric Potential in Nuclear Physics, Fusion Reaction Modeling, Energy Yield Calculation, Theoretical Physics, Classical vs Modern Nuclear Models, Quantum Corrections, Independent Research in Physics, Advanced Nuclear Reactor Concepts, Energy Transformation Equations, Kinetic and Potential Energy Integration, Laser-Induced Fusion, Fusion Chain Reactions, Hybrid Energy Models, Scientific Model Derivation, Open Access Physics Research,

Collaboration interests:

I seek collaboration in theoretical and nuclear physics, focusing on improved models for fusion, fission, atomic mass, and electro-nuclear energy. I welcome joint validation, simulation, and publication opportunities.

Biography:

Biography of Saleh Ali Saleh Al-Hamed Independent Theoretical Physicist – Yemen Saleh Ali Saleh Al-Hamed is an independent researcher and theoretical physicist whose work focuses on revisiting and improving foundational concepts in classical mechanics, nuclear energy, and relativistic physics. Without formal institutional affiliation, he has authored a cohesive body of original research that proposes significant extensions to long-standing physical laws, aiming to bridge the gap between idealized models and real-world complexities. His most prominent scientific contributions revolve around six interconnected areas: 1. An Improved Version of Newton's Second Law, incorporating a built-in friction term, making it applicable to realistic environments where resistance cannot be ignored. This adjustment is simple yet powerful, and it offers a refined framework for motion in engineering, education, and simulations. 2. A Corrected Nuclear Energy Model, which modifies Einstein’s E = mc² by accounting for the mass of secondary particles that do not directly contribute to energy release. This improvement addresses a key limitation in nuclear energy calculations, especially in practical fission scenarios. 3. A Fusion Energy Enhancement, through the Al-Hamed Equation, which integrates both electric energy input and nuclear mass-energy conversion. This dual-source model allows for better control and precision in fusion reactor design and simulation. 4. A Unified Electro-Nuclear Theory, which merges the dynamics of electric charge and nuclear mass into a single predictive framework. This equation serves as a conceptual platform for hybrid energy systems, space propulsion, and advanced defense applications. 5. A New Interpretation of Relativistic Mass, asserting that mass remains constant even at high velocities. This interpretation aligns with modern quantum field theory and resolves ambiguities in relativistic dynamics by treating energy, not mass, as the changing quantity with velocity. 6. The Theoretical Design of an Electro-Nuclear Reactor, based on his unified equation. This concept combines nuclear and electric input into a scalable, compact energy system with potential uses in defense, space, and remote energy generation. Al-Hamed’s philosophy is grounded in clarity, simplicity, and physical relevance. His research is both mathematical and conceptual, offering practical insights while remaining rooted in theoretical rigor. Despite limited access to laboratories or formal research grants, he continues to produce detailed models, calculations, and technical illustrations to support his theories. His publications, which include technical papers, encyclopedic entries, and illustrative diagrams, aim to inspire open scientific dialogue and encourage independent innovation. He believes that fundamental physics must continuously evolve—not through radical departure, but through thoughtful refinement. Al-Hamed advocates for the recognition of independent researchers in the scientific community and strives to build bridges between traditional scientific frameworks and forward-thinking alternatives. His long-term vision is to help shape a more accurate, accessible, and application-driven future for physics.

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