Revolutionizing Physics: Bridging Cosmic and Microscopic Realms with the Alena Tensor
A technique for rectifying curved space-time In contemporary physics, a significant hurdle lies in devising a comprehensive method to elucidate phenomena across both cosmic and microscopic scales. For over a century, general relativity, formulated by Albert Einstein, has been the preferred framework for understanding gravity on a cosmic scale, notwithstanding lingering uncertainties surrounding dark matter and dark energy. It currently stands as the most effective approach for analyzing the universe’s past and future.
Conversely, to comprehend phenomena at the atomic level, quantum mechanics, the second pivotal theory, is employed. Quantum mechanics diverges from general relativity in fundamental aspects, utilizing flat space-time and a distinct mathematical apparatus. Most notably, it perceives reality through a radically different lens, characterizing the phenomena around us as fluctuating probabilities of events measured with limited precision.
In a publication featured in Frontiers in Physics, I have successfully illustrated a method that integrates the aforementioned descriptions, yielding a somewhat surprising outcome. Can curved space-time be rectified?
Enter the Alena Tensor, a mathematical construct facilitating the portrayal of physical phenomena in a manner allowing the smooth adjustment of space-time curvature akin to using a slider. This mathematical object seamlessly transitions between Einstein Field Equations in curved space-time and classical methods of relativistic physics in flat space-time. Crucially, it remains amenable to quantum description.
Thus far, I have demonstrated the efficacy of this space-time slider in relation to gravity and electromagnetism, showcasing the Alena Tensor’s capability to accommodate additional fields. This hints at the possibility of reconciling previously conflicting explanations for other recognized fields.
A noteworthy byproduct of employing this method is the observation that a particular element of the equation, the field invariant, behaves akin to a cosmological constant in Einstein Field Equations. This revelation holds promise in elucidating the nature of dark energy. Furthermore, it suggests the presence of an additional force beyond gravity, potentially shedding light on the enigmatic nature of dark matter.
However, as is often the case with elegance, there is a price to pay. The conclusions of the article do not mark the conclusion of efforts to merge these two prominent theories. The proposed method necessitates extensive further research and meticulous refinement of field descriptions. While there is newfound hope and a promising avenue for continued exploration, the utilization of this method comes with a distinct challenge. If the method proves to be the long-sought solution, it implies that our surrounding world is an ever-undulating field, and space-time merely serves as a lens through which we perceive this field. This extraordinary conclusion stems from the equations detailed by Alena Tensor.