Lorentz’s violation reveals the mystery of dark energy stars and prevents the singularity of black holes
The space-time structure of the universe is more mysterious than we think. Scientists have long attracted attention to the nature of dark energy and the special behavior of stars that seem to ignore traditional physical rules. A new study provides a new perspective on these cosmic riddles, suggesting that the basic principle of minimum speed may be the key to unlocking its secrets. This interesting concept challenges our understanding of space and time and has the potential to reshape our perception of the universe itself.
A study published in the physics of the Dark Universe reveals a new way to understand the dark energy stars and proposes that Lorentz violates Lorentz at a constant minimum rate, which constitutes the dark energy stars The basis of gravity bose-Nestetine condensate (GBEC). This innovative study conducted by Dr. Cláudio Nassif Cruz from Centro de Pesquisas Emfísica Teórica provides a profound transformation, a profound transformation of cosmological models, elucidating the complexity of quantum vacuum and space-time.
Dr. Cruz proposed that the introduction of an invariant minimum speed is related to the concept of symmetric special theory of relativity (SSR), which fundamentally changes the structure of space and time. This minimum velocity (denoted as V) is directly related to Planck’s length and changes the causal structure of space-time, thereby affecting the formation and behavior of GBECs in dark energy stars. Research shows that this new understanding can solve the puzzle of events, traditionally predicted in the case of gravitational collapse.
“Our research shows that the presence of an invariant minimum velocity in the space-time structure causes a phase change between gravity and countergravity, thus preventing the formation of singularity within the event range. This transition occurs before reaching the Schwarzschild radius, thus eliminating the There are problems and allow for a more stable structure.” Dr. Cruz explained.
This study outlines the important implications of this phase transition, where the repulsive core described by the GBEC indicator replaces the traditional concept of the black hole event vision. The core of this repulsion is surrounded by a phase coexistence region that bridges gravity and gravity resistance, prevents differences in space-time indicators and allows signal propagation, which is impossible in classic black hole models.
By mapping the SSR metric that explains the lowest velocity into the GBEC metric, Dr. Cruz is able to connect the cosmic constant representing the energy density of the vacuum to the constant minimum velocity. This innovative approach provides a quantum explanation of GBEC, where the minimum velocity causes strong anisotropy, resulting in the phase transition observed during star collapse.
“The SSR metrics we developed are similar to the DE Sitter metric, which is known for representing space-time and time in the universe with positive cosmic constants. However, our metrics include the lowest velocity, providing more to vacuum energy and its role in the universe. A comprehensive understanding.”
The implications of this study are enormous as it challenges the traditional view of black holes and provides new models for understanding the dark energy components of the universe. Eliminating the singularity of the event range and introducing phase transition regions provide new possibilities for exploring the behavior of extreme gravitational systems and the properties of dark energy.
“This study not only solves the long-standing singularity problem in black holes, but also opens up new avenues for exploring the interaction between quantum mechanics and general relativity, the theory of quantum gravity. Dr. Cruz said: The idea that the minimum speed may be as basic as the speed of light in space-time structures is indeed revolutionary illuminating astrophysics, cosmology, and various fields of physics. ”
In summary, Dr. Cruz’s research presents a transformative view of dark energy stars, providing a powerful theoretical framework that can reshape our understanding of the universe’s most mysterious phenomena. With the invariant minimum speeds incorporated into the GBEC model, the limitations of Lorentz violations provide a comprehensive solution to the problems raised by classical black hole theory and pave the way for future exploration to enter the mysteries of dark energy.
Journal Reference
Nasif Cruz (C. Physics of the Dark Universe (2020). doi: https://doi.org/10.1016/j.dark.2019.100454
About the Author
Cláudio Nassif Cruz He is a professor of physics at UYO Preto University (UFOP) from Minas Gerais, Brazil. He was born in August 1967 in Além Paraíba, Minas Gerais.
He received his Bachelor of Science degree in Physics from the Federal University of Minas Gerais (UFJF) in Brazil (1992).
He has a Master’s degree (1992) and a PhD degree (2002) at the UFMG Federal University (UFMG) in Minas Gerais, Brazil.
He has long experience in the field of condensation physics, focusing on equations of state, phase equilibrium and phase transition, focusing on the following topics as working lines, namely Thompsons, chemical reactions of diffusion restriction, polymers, surface growth, N-vector The model has no random field. Similarly, some topics in some field theories are dealt with on Thompsons’ approach, such as quantum electrodynamics (QED) and quantum chromosome dynamics (QCD).
In another original study he introduced himself, he devoted himself to exploring another possibility of Lorentz symmetry to give the deformed special relativity theories with an unchanged minimum velocity (symmetric special relativity), where the background field It is the low-energy dynamics generated by non-Lorentzians that explain the tiny positive values of cosmic constants and the principle of quantum uncertainty, allowing us to establish a connection between quantum physics and cosmology.
