Gaze at the vastness of the universe, imagine if the secrets of its most complex laws were written not in complex equations, but in the shapes and curves of space and time itself. This interesting premise is at the heart of a groundbreaking study that aims to shed light on how particles behave and the mysteries of their mysteries by examining the geometry of the universe. By delving into the geometric properties of the universe, the study reveals a novel idea that both the complex dance of celestial bodies and the subtle interactions of subatomic particles may follow common geometric blueprints. This approach opens the door to understanding the fundamentals of the universe through lenses of geometric shapes, which suggests a profound connection between the great expansion of the universe and the details of physical phenomena.
Through this innovative work, Professor Güngör Gündüz (Orta Doğu Tekniküniversitesi) from the Middle East Technical University brings a perspective in which the laws of the universe seem to surface from its geometric makeup. Professor Gündüz explained: “Exploring deformable space-time, we have seen the dominance of the Möbius transformation over the traditional Lorentz transformation. This transformation provides us with a fresh lens to see the structure of reality, surfaces under minimal conditions The motion of the spiral reveals a pattern of spirals, similar to the möbius spiral, representing the most basic mass with inherent properties such as charge and rotation.
The study, published in the peer-reviewed journal Results of Physics, examines shapes such as spirals and streptococci, known for their unique geometric features. By transforming these two equidistant shapes in a specific way, Gündüz shows that the transformational relationship between spiral lobes and catlike bones also reveals the relativity of Lorentz factors without participating in the Maxwell equation. The unified nature of spirality and catenoid create a new shape, the so-called Mobius spiral, which brings a fascinating geometric basis for mass formation, charge and rotation. “Gündüz said.
Professor Gundüz digs further, “Our method proposes a model in which the basic properties of particles are inherently related to geometric structures in space and time. For example, the Möbius spirochete is the fundamental figure in understanding the relationship between Zitterbewegung behavior and mass relationships of Dirac electrons , which is the cornerstone of the special theory of relativity. “The de Broglie equation takes a new form during the deformable period, and the increase in relativity of mass with velocity corresponds to the increase in the Möbius spirochete winding seen at different β=V/C values.
By considering the structure of Möbius Helicoid, the principal equation is derived for the dynamic behavior of deformable space-time. By making some simplified assumptions about the parameters involved, electromagnetic waves, Schrödinger, Klein-Gordon, Dirac, Quantum Telegrapher and quantum torsion equations can be easily obtained from this main equation.
Key findings of the study involve the process of particles obtaining mass. “Our results show that the process of mass formation, including the role of the Higgs potential, is closely related to the geometric properties of space-time.” This connection between mass formation and the geometric shape of space-time is the most mysterious understanding of physics,” Gündüz said. One of the aspects opens a new door: how quality emerges.
This study by Gündüz not only questions traditional physical models, but also highlights potential avenues for future discovery. “Our model provides a new way to study the connection between geometry and physics of deformable space-time, suggesting that the nature of the universe may be closely related to the way we are just beginning to understand fundamental forces and particles,” Gündüz reflects . This exploration of the geometric basis of physics laws invites us to reconsider the nature of the universe, thus changing our understanding of the universe and the quantum domain.
Through the work of Professor Güngör Gündüz, we get a fascinating view of the universe, which suggests that the rules it follows may have originated from its geometric structures induced in deformable space-time. This view can completely change our understanding of everything from the smallest particles to the huge universe, bringing us closer to uncovering the deepest mysteries of the universe. In short, this pioneering study is how to intertwin a deep understanding of the basic laws of physics in a deep way. By bridging the gap between geometric shapes and physics, Professor Gundiz’s work paves the way for a new understanding of the universe, when and time complexity was not only the background of physical phenomena, but also the laws originated from its foundations. . As we dig deeper into the fascinating interaction between geometry and physics, the secrets of the universe may become increasingly accessible, providing new insights into the grand design of everything around us.
Journal Reference
Güngör Gündüz, Physics of Deformable Space-Time: The Law of Physics Appears from the Principle of Surface Minimum and Particle Mass, Leading to Physics, Vol. 56, 2024, 106981. DOI: DOI:
