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A method for straightening curved spacetime

One of the best difficulties of current material science is to track down an intelligible technique for portraying peculiarities on the vast and microscale. For nearly 100 years, to portray reality on an inestimable scale, we have been utilizing the general relativity hypothesis, which has effectively gone through rehashed endeavors at misrepresentation.

Albert Einstein bended space-time to depict gravity, and regardless of still-open inquiries concerning dim matter or dull energy, it appears today to be the best technique for breaking down the past and fate of the universe.

To depict peculiarities in the size of molecules, we utilize the second extraordinary hypothesis: quantum mechanics, which contrasts with general relativity in essentially everything. It utilizes level space-time and something else entirely device, and in particular, sees reality profoundly in an unexpected way.

In the quantum portrayal, the peculiarities around us are just faltering probabilities of occasions that we can quantify with restricted precision.

In an article distributed in Outskirts in Material Science, I figured out how to exhibit that there is a technique that joins the above portrayals, despite the fact that it prompts a seriously astonishing end.

Could bended space-time be fixed?
It just so happens that there is a sure numerical article called the Alena Tensor, which permits the depiction of actual peculiarities so that the shape of room time can be flawlessly changed as though utilizing a slider. In bended space-time, conditions normally change into Einstein Field Conditions, and in level space-time, they permit the utilization of traditional strategies for relativistic material science and, in particular, are dependent upon quantum depiction.

Up to this point, I have figured out how to exhibit that such a space-time slider works for gravity and electromagnetism and that the Alena Tensor permits the addition of further fields. It appears feasible to accommodate already problematic portrayals in other known fields.

A symptom of utilizing the above technique is that a specific component of the situation (the field invariant) acts like a cosmological steady in Einstein Field Conditions, which might assist with making sense of the idea of dull energy. It likewise turns out that there should be an extra power notwithstanding gravity, which could assist with making sense of the idea of dim matter.

In any case, all that looks delightful has its cost.

What is the universe around us?
The conclusion of the article doesn’t spell almost certain doom for work on joining both extraordinary hypotheses. The proposed strategy requires a lot of further examination and a cautious change in field depictions. There is positively new expectation and a promising new course for additional exploration, so maybe we will before long catch wind of additional fields lined up with the space-time slider.

In any case, there is a sure cost associated with utilizing the proposed technique, which is by all accounts the greatest test. Assuming that the technique I have created ends up being the right one that we have been searching for a considerable length of time, it will likewise imply that the whole world around us is only a continually waving field, and space-time itself is just an approach to seeing this field. This is the most phenomenal ending that has come about because of the situations depicted by Alena Tensor.

This story is important for Science X Discourse, where analysts can report discoveries from their distributed exploration articles. Visit this page for data about ScienceX Exchange and how to take an interest.

More information: Piotr Ogonowski, Developed method: interactions and their quantum picture, Frontiers in Physics (2023). DOI: 10.3389/fphy.2023.1264925www.frontiersin.org/articles/1 … 89/fphy.2023.1264925

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