Posted on 12/25/2024 10:33:07 AM PST by Eleutheria5
Dark matter could be the result of fermions pushed into a warped fifth dimension. This theory builds on an idea first stated in 1999, but is unique in its findings. Dark matter makes up 75 percent of matter but has never been observed ... yet. Scientists say they can explain dark matter by positing a particle that links to a fifth dimension.
While the “warped extra dimension” (WED) is a trademark of a popular physics model first introduced in 1999, this research, published in The European Physical Journal C, is the first to cohesively use the theory to explain the long-lasting dark matter problem within particle physics.
Our knowledge of the physical universe relies on the idea of dark matter, which takes up the vast majority of matter in the universe. Dark matter is a kind of pinch hitter that helps scientists explain how gravity works, because a lot of features would dissolve or fall apart without an “x factor” of dark matter. Even so, dark matter doesn’t disrupt the particles we do see and “feel,” ...
(Excerpt) Read more at popularmechanics.com ...
😁
Caddycorner... that’s the dimension you forgot.
Marilyn McCoo is alive and well at 81. No need for more research.
A real scientist would write a paper and grift for government funding...
They’re so “pretty sure” that it really won’t take that big of a grant for them to find it the rest of the way for certain.
Until next year.
I too postulate, maybe it is all the unpopped pop corn that is balancing their perceived imbalance in the universe. In actuality the seemingly perfect harmony of what we observe in our universe is an illusion according to a group of scientists who said so .
Don’t forget the dimensional stabilizer and time space element.
No bigee. Just another super collider.
What? She was in Hair?
Yup—”dark matter” reminds me of accounting students who can’t get balance sheets to balance so they just throw in an account called “unknown”.
Lol.
If you lived in San Francisco, it would be.
I thought it was a rock group.
Hiding behind Hadron's Wall.
The word “portal” suggests you could go there. Imagine a stick figure on a piece of paper. He’s two dimensional. He can’t “find a portal” to the third dimension. It’s there, but it’s a theoretical property of his two dimensional world. If there is a fifth dimension then it is all around us.Was
There’s billions of dimensions... like ripples in a big bang pond.
This is my query to ChatGPT:
You are a physicist. Please give a critical analysis of string theory. Please provide an answer that's not a numbered list.
Here is ChatGPT’s response:
String theory, as a framework for unifying all of the fundamental forces of nature, presents a bold and elegant vision. At its core, string theory proposes that the fundamental constituents of the universe are not point-like particles, as traditionally conceived in particle physics, but rather one-dimensional “strings” that vibrate at different frequencies. These vibrations are thought to give rise to the various particles and forces observed in nature. String theory holds promise for reconciling the apparent incompatibility between quantum mechanics and general relativity, with the ultimate goal of providing a “Theory of Everything” (TOE) that explains all physical phenomena under a single, unified framework. However, despite its mathematical beauty and intellectual appeal, string theory is not without significant challenges and unresolved issues.
One of the most fundamental criticisms of string theory is the lack of empirical evidence supporting its predictions. Unlike other well-established physical theories, such as quantum mechanics and general relativity, string theory has not yet made any predictions that can be tested with current experimental techniques. The energy scales at which string theory's effects would become noticeable are on the order of the Planck scale (around \(10^{19}\) GeV), far beyond the reach of any particle accelerator in existence today. This raises a crucial question: how can string theory be considered a scientific theory if it cannot be empirically tested? Critics argue that without the possibility of experimental verification or falsification, string theory risks crossing into the realm of metaphysics rather than remaining a testable scientific theory.
Another significant challenge is the so-called “landscape problem.” String theory predicts a vast number of possible vacuum states—each corresponding to a different way the strings can vibrate. Some estimates suggest that there are around \(10^{500}\) possible solutions, a number so large that it makes it difficult to explain why our universe appears to have the specific physical properties that it does. The vast number of possible configurations raises doubts about string theory's predictive power: if any vacuum state can explain any set of physical laws, does string theory truly make meaningful predictions about our universe, or does it simply offer a framework that can explain anything in hindsight? This issue is particularly problematic from the perspective of falsifiability, a core tenet of scientific theory. The landscape problem has led some physicists to question whether string theory can ever deliver on its promise of unification or if it will remain a highly abstract mathematical structure with little connection to observable reality.
The mathematical complexity of string theory also poses a significant barrier to its acceptance. String theory requires the existence of additional spatial dimensions—usually ten or eleven—beyond the familiar four dimensions of spacetime. These extra dimensions, while mathematically consistent, are compactified at extremely small scales, making them virtually unobservable at current energy levels. The theory's reliance on highly abstract concepts such as Calabi-Yau manifolds and higher-dimensional geometries has made it challenging to interpret in a physically intuitive way. Moreover, while the mathematics of string theory is elegant and internally consistent, some critics argue that its abstract nature makes it more of a “mathematical physics” framework rather than a physical theory grounded in real-world observations.
Supersymmetry (SUSY), a key ingredient in many versions of string theory, has also faced significant challenges. Supersymmetry posits a symmetry between bosons (force-carrying particles) and fermions (matter particles), suggesting that every boson has a corresponding fermion partner, and vice versa. However, no experimental evidence for supersymmetric particles has been found, even after extensive searches at high-energy particle colliders like the Large Hadron Collider (LHC). The lack of direct evidence for supersymmetry raises concerns about the viability of string theory itself, as SUSY is often considered a crucial element for the theory's internal consistency. While supersymmetry remains an attractive theoretical idea, its failure to manifest in experimental data undermines confidence in the theory's physical realism.
Furthermore, string theory's ability to unify the four fundamental forces of nature—gravitational, electromagnetic, weak, and strong interactions—remains speculative. Although string theory does incorporate gravity in a quantum framework, it has not yet provided a complete, fully realized quantum theory of gravity. The long-standing goal of unifying all four forces into a single, coherent theory remains elusive. While string theory offers a promising path toward this goal, it has not yet delivered concrete predictions that can be directly tested, and some aspects of its approach, such as the reliance on higher-dimensional spaces, remain speculative.
Finally, there is a broader philosophical concern regarding the status of string theory as a scientific theory. The theory's reliance on abstract mathematics, combined with the lack of experimental testability, has led some to question whether string theory is truly a scientific theory or whether it has become a speculative framework that attempts to explain everything but is in danger of explaining nothing. The lack of experimental verification, coupled with the difficulty of translating the theory into testable predictions, has prompted some critics to argue that string theory is more a product of mathematical beauty and intellectual ambition than a testable scientific theory.
In conclusion, while string theory remains one of the most ambitious and mathematically rich areas of theoretical physics, it faces significant challenges that prevent it from being accepted as a definitive theory of everything. The lack of experimental evidence, the vast number of possible solutions (the landscape problem), the untested nature of supersymmetry, and the theory's reliance on highly abstract mathematics all pose serious hurdles. While string theory has provided valuable insights and deepened our understanding of the mathematical structures that may underlie the universe, it has not yet yielded a concrete, experimentally verified description of the physical world. Until string theory can make verifiable predictions or be tested in ways that allow us to rule out competing theories, it will remain an exciting but speculative framework for understanding the fundamental forces of nature.
hate to tell you but your lawn IS covered in dark matter. you just can’t see it in the dark.
The dark matter capitol of the USA!
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