Morteza Mahvelati

My work is organized around the development of the MM Theory and related research intended to examine physical phenomena across a broad range of scales. The MM Theory is a proposed theoretical framework based on the concepts of M particles and the motion of momenta. It is intended to provide a connected way of analyzing physical behavior, from the proposed basic constituents of nature to matter, interactions, motion, energy transfer, complex systems, and large-scale universal phenomena.

A major purpose of my research is to study physics as an interconnected structure rather than as a set of separate subjects. Within this direction, I examine how different areas of physics may be related through underlying principles of motion, momentum, matter, interaction, and energy transfer. My broader interests include gravitational behavior, electromagnetic behavior, thermodynamic processes, fluid behavior, astronomical systems, cosmological structures, and the organization of physical systems at different scales.

My published works represent the early stages of this broader research program. These works include the fundamentals of MM Theory, the introduction of centrial motion and centrial momentum, the interpretation of selected quantum-mechanics concepts through MM Theory, the possible influence of rotary magnetic systems on light propagation, and the concept of Absolute Energy. They also discuss topics such as light propagation, interference patterns, measurement, wave-particle duality, magnetic influences, reference systems, angular motion, and kinetic energy in two-body and multi-body systems.

In addition to theoretical development, my research includes experimental investigation. I seek to connect theoretical models with observable behavior through controlled experimental approaches, including optical arrangements, interferometry, rotating magnetic systems, and other physical setups. These experiments are part of a broader effort to examine whether proposed theoretical ideas can be evaluated through measurable physical effects.

Overall, my research is directed toward developing a coherent, comprehensive, and testable physical framework that connects theoretical reasoning with practical investigation, from basic physical constituents to the structure and behavior of the universe.

My achievements are centered on the development of original theoretical and experimental work directed toward a broad understanding of physical phenomena. A major achievement is the formulation of the MM Theory, a proposed theoretical framework that examines nature through the concepts of M particles and the motion of momenta. The intended scope of this work extends from the proposed basic constituents of physical reality to matter, interactions, motion, energy transfer, complex systems, and the universe as a whole.

I have developed several written research works that represent the early stages of this broader research direction. These works include the fundamentals of MM Theory, the introduction of centrial motion and centrial momentum, the interpretation of selected quantum-mechanics concepts through MM Theory, the possible influence of rotary magnetic systems on light propagation, and the concept of Absolute Energy. Together, these works form a foundation for a wider research program that aims to connect different areas of physics within a coherent physical picture.

Another achievement is the development of experimental approaches connected to theoretical questions. My experimental work includes optical arrangements, interferometric methods, rotating magnetic systems, and controlled setups intended to examine possible physical effects under defined conditions. These investigations reflect my effort to connect theoretical ideas with observation and measurement.

I have also developed the concept of Absolute Energy as a proposed way to analyze kinetic energy with respect to a specific reference point or axis, particularly in two-body and multi-body systems.

Overall, my achievements reflect a sustained effort to build original theoretical concepts, examine them systematically, and connect them with experimental investigation across a broad range of physical questions.

My current activities are focused on developing the MM Theory and related research into a broader framework for examining physical phenomena across different scales. I am studying how physical behavior may be understood from the proposed M particle level to matter, interactions, physical systems, and the structure and behavior of the universe.

A major part of my current research is directed toward examining connections among different areas of physics, including matter, motion, momentum, energy transfer, gravitational behavior, electromagnetic behavior, astronomy, cosmology, and large-scale universal structures. My aim is to explore how these phenomena may be related through underlying physical principles.

In addition to my work on the MM Theory, I am also studying selected topics in thermodynamics and fluid mechanics. These areas are important to my broader research interests because they involve motion, pressure, flow, heat, energy exchange, and interactions within physical systems.

I also continue to develop experimental approaches that may help examine theoretical ideas through observable behavior. These activities include designing and evaluating physical setups and controlled experimental conditions that can help connect theoretical reasoning with practical investigation.

Overall, my current activities are directed toward expanding a systematic research program that connects theoretical development, experimental work, and the study of physical phenomena from basic constituents to the universe as a whole.

My goals are to continue developing the MM Theory and related research into a coherent, comprehensive, and testable physical framework. I aim to examine nature across different scales, from the proposed M particle level to matter, interactions, physical systems, and the universe as a whole.

A central goal of my work is to explore how different areas of physics may be connected through underlying physical principles. Rather than treating physical phenomena only as separate subjects, I seek to develop a broader framework in which motion, matter, momentum, energy transfer, gravitational behavior, electromagnetic behavior, thermodynamic processes, fluid behavior, astronomical systems, and cosmological structures can be studied in relation to one another.

Another important goal is to strengthen the connection between theory and experiment. I intend to continue developing controlled experimental approaches that can help examine theoretical ideas through observable and measurable physical behavior. This includes improving the design, interpretation, and reproducibility of experiments related to my research.

Overall, my goal is to contribute to scientific inquiry by developing original theoretical ideas, connecting them with experimental investigation, and working toward a broader understanding of physical phenomena from basic constituents to universal structures.

My research and publications represent the early stages of a broader research program directed toward understanding physical phenomena across different scales. A central part of my written work is the development of the MM Theory, a proposed theoretical framework based on the concepts of M particles and the motion of momenta. The intended scope of this research extends from the proposed basic constituents of nature to matter, interactions, motion, energy transfer, physical systems, and the universe as a whole.

My published preprint works include studies on the fundamentals of MM Theory, the introduction of centrial motion and centrial momentum, the interpretation of selected quantum-mechanics concepts through MM Theory, the possible influence of rotary magnetic systems on light propagation, and the concept of Absolute Energy. These works form an initial foundation for a wider research direction that aims to connect different areas of physics through a coherent physical framework.

In my work on MM Theory, I have examined topics such as matter, motion, light propagation, thermal waves, electricity, magnetism, radio waves, gravitational behavior, the bending of light near massive objects, redshift and blueshift, the photoelectric effect, and dark matter. In my work on quantum-mechanics concepts, I have discussed the double-slit experiment, wave-particle duality, measurement, and interference patterns from the perspective of MM Theory.

My work on Absolute Energy presents a proposed concept for analyzing kinetic energy with respect to a specific reference point or axis, particularly in two-body and multi-body systems. My experimental research includes studies involving rotating magnetic systems and optical arrangements designed to examine possible changes in light propagation under defined conditions.

Overall, my research and publications aim to present the initial parts of a broader scientific framework that connects theoretical development with experimental investigation and the study of physical phenomena from basic constituents to universal systems.

A central highlight of my research is its broad intended scope. My work is directed toward examining physical phenomena across different scales, from the proposed M particle level to matter, physical interactions, complex systems, and the universe as a whole.

Although my published works represent the early stages of this research direction, they are part of a larger effort to develop a coherent and testable physical framework. I aim to study physics as an interconnected structure, where different phenomena may be examined through common underlying principles rather than treated only as separate subjects.

Another important highlight of my work is the combination of theoretical reasoning with practical experimental investigation. I seek not only to develop original concepts, but also to consider how these ideas may be examined through observable physical behavior and controlled experimental approaches.

Overall, my research is guided by curiosity, persistence, and the goal of developing a systematic understanding of nature from basic constituents to large-scale universal behavior.