Advanced DUT Simulation Technology Reproduces 'Impossible' Galaxies Observed by JWST and Challenges ΛCDM
New simulations reproduce high-redshift galaxies seen by JWST and propose a radical cosmological shift beyond ΛCDM.
'To simulate the universe with mathematical precision is to dismantle myths with data and disprove fiction through gravity.' — Joel Almeida -CEO
CURITIBA, PARANá, BRAZIL, June 29, 2025 / EINPresswire.com / -- A newly released preprint by cosmology researcher and lead developer of the DUT Simulator, Joel Almeida, introduces a groundbreaking computational simulation based on the Dead Universe Theory (DUT), capable of reproducing the observed properties of massive galaxies at redshifts z > 8, including CEERS-1019 and GLASS-z13. These galaxies, detected by the James Webb Space Telescope (JWST), have challenged the predictions of the standard ΛCDM cosmological model.
Using DUT's entropy-gradient-driven gravitational collapse, the simulations achieve under 5% accuracy in stellar mass, sub-kpc radius, and formation timescales below 100 million years—outperforming ΛCDM expectations by factors of ~5. Crucially, DUT offers falsifiable predictions and proposes that the universe is not expanding, but retracting within a non-singular, structural black hole.
The full simulator is open-source and fully reproducible, available through ExtractoDAO for researchers worldwide.
🛰️ JWST Observes 'Impossible' Galaxies — A New Theory and Quantum Simulator Challenge the Big Bang
A new study published as a preprint by researcher Joel Almeida, in collaboration with the scientific startup ExtractoDAO S/A, proposes a bold solution to one of modern cosmology's greatest mysteries: how could massive, compact galaxies have formed so early in the universe?
Recent observations from the James Webb Space Telescope (JWST) identified galaxies such as CEERS-1019 (z = 8.67) and GLASS-z13 (z = 13.1), with stellar masses above 10¹⁰ M☉ and cores smaller than 1 kiloparsec—structures that, according to Big Bang and ΛCDM models, should not exist at such early epochs.
In response to this enigma, the Dead Universe Theory (DUT) and its computational simulator presented remarkable results: the observed properties of these galaxies were reproduced with up to 5% accuracy, simulating ultrafast star formation (<100 million years) without requiring cosmic inflation or exotic dark matter.
'The simulations show that the universe doesn't need to have emerged from a singular point or to be expanding indefinitely. JWST data can be reinterpreted as evidence of asymmetric gravitational retraction within a larger, stable, non-singular cosmic structure,' says Almeida.
The DUT model considers the observable universe to be an entropic bubble embedded in the core of a 'structural black hole'—non-singular, governed by a regularized oscillatory gravitational potential, capable of stabilizing galaxy formation without violating Einstein's equations. The computational tool used, named DarkStructSim™, is fully auditable, reproducible, and operates 100% offline, with future optional integration to quantum clouds such as IBM Quantum.
Research Highlights:
<5% accuracy in mass and size of z > 8 galaxies
Explicit computation of core temperature, gravitational entropy , and cosmological constants
ΛCDM refuted under extreme mass and redshift regimes
Falsifiability proposed: if no galaxy with z > 12 and M > 10¹⁰ M☉ is observed by end of 2024, DUT will be considered refuted
The research is available on Research Square under the title:
📝 Preprint 1.0: JWST High-z Galaxies in the Dead Universe Theory (DUT) Cosmological Framework
👉 Read the full paper: https://www.researchsquare.com/article/rs-6952094/v1
Any researcher can now reproduce the same simulation by downloading the offline code:
🔗 https://extractodao.com/dut
🔗 https://zenodo.org/records/15750860
🔗 https://zenodo.org/records/15765004
About the author:
Joel Almeida is a cosmology researcher and founder of ExtractoDAO, a blockchain startup developing scientific technologies based on gravitational simulations, decentralized computing, and secure research infrastructures.
📩 Contact: [email protected]
🔗 ORCID: 0000-0003-4015-7694
🔬 Simulation Platform: https://zenodo.org/records/15716055
Joel almeida
ExtractoDAO S.A
email us here
Visit us on social media:
LinkedIn
Instagram
YouTube
Legal Disclaimer:
EIN Presswire provides this news content 'as is' without warranty of any kind. We do not accept any responsibility or liability for the accuracy, content, images, videos, licenses, completeness, legality, or reliability of the information contained in this article. If you have any complaints or copyright issues related to this article, kindly contact the author above.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Associated Press
5 hours ago
- Associated Press
DUT Quantum Blockchain Simulator Refutes Theory That a Black Hole Created the Universe
ExtractoDAO Launches DUT Quantum Simulator: Refuting Black Hole Universe Theories with Einstein-Based Decentralized Science 'To simulate the universe with mathematical precision is to dismantle myths with data and disprove fiction through gravity.'— Joel Almeida, CEO CURITIBA, PARANá, BRAZIL, June 30, 2025 / / -- Was the Observable Universe Created by a Black Hole? The blockchain technology and advanced scientific research startup in computational simulations has launched the DUT Quantum and DUT General Relativity simulators, focused on expanding Albert Einstein's theory. Many speculative hypotheses have fueled media discussions about the possibility that the universe was created by black holes—or have simply evoked science fiction to explain phenomena that can, in fact, be observed and explained through mathematical and epistemological rigor. Image simulator: 'The mathematical simulations conducted by the DUT General Relativity model unequivocally demonstrate that hypotheses claiming the universe was created by black holes are mathematically unsustainable, conceptually fragile, and empirically incompatible with observational data. The refutation results are detailed in the research available at and can be independently replicated by any researcher using the DUT General Relativity and DUT RG simulators.' While many black hole simulations focus on dazzling visualizations or modeling observational phenomena (like those from NASA, or those exploring magnetic effects, or even those using artificial intelligence to create realistic models), the DUT Simulator adopts a distinct and crucial approach: the direct refutation of cosmological hypotheses through fundamental physical laws. What makes it unique is its ability to rigorously apply advanced concepts of theoretical physics to validate or, more importantly, refute the viability of hypothetical scenarios. Specifically, it aims to test the idea that our universe could have emerged from a black hole. It is precisely these characteristics that make the Quantum and Unified General Relativity Simulator by ExtractoDAO—developed from the scientific research of its CEO and simulator project leader, Joel Almeida—stand out as a powerful tool, now available on the market and entirely free for the global scientific community. The DUT Quantum Simulator presents a high standard of computational security and scientific integrity, with fully readable and verifiable code that operates without any external API calls. Its operation is 100% offline, requiring no internet connection, and it incorporates a built-in ledger and hashing system, allowing all simulations and results to be recorded immutably and auditable through blockchain technology. In perfect alignment with the Dead Universe Theory (DUT), the simulator avoids singularities and event horizons, modeling regular geometries with mathematical precision. Among its computational capabilities are geodesic simulations, gravitational lensing, Einstein and Ricci tensors, and scalar invariants—all structured in independent modules that allow separate testing of collapse, curvature, and gravitational dynamics. Moreover, it enables comparative transitions between classical General Relativity solutions, such as the Schwarzschild metric, and the regularized solutions proposed by DUT, broadening its applicability to both innovative researchers and physicists aligned with the Einsteinian paradigm. The computational architecture of DUT Quantum and General Relativity is compatible with future integration into high-performance computing environments, including quantum clouds such as those offered by IBM, Amazon Braket, or similar platforms. This will allow, when desired, the execution of more intensive calculations or parallel simulations in hybrid environments—while maintaining full integrity and control of source code and data by the researcher. In the field of research in General Relativity and Cosmology, the ability to test complex hypotheses is essential. It is in this context that the DUT Universal Simulator stands out as a truly innovative and powerful tool. Instead of showing what a black hole looks like or how it behaves on a visual level, the DUT Simulator dives into the intrinsic and measurable properties of these objects. It calculates and compares critical parameters such as: Entropy: a measure of disorder or the number of possible microstates of a system. Effective Cosmological Constant: a value that describes the vacuum energy density in the universe, crucial for its expansion. Hawking Temperature: the hypothetical temperature of radiation emitted by a black hole. The simulator allows users to adjust the mass of black holes and, based on these calculations, graphically and numerically demonstrates that the resulting conditions for an emerging universe drastically violate the parameters observed in our own universe. This discrepancy is not a mere divergence, but a physics-based refutation that invalidates the hypothesis in question. This type of simulation represents a significant breakthrough because: It Provides Concrete Proof: It offers a practical platform to test complex cosmological theories. It Advances Knowledge: In science, refuting a hypothesis is just as important as confirming one. It's a Powerful Didactic Tool: It allows users to manipulate parameters and see the direct consequences of physical laws in cosmological scenarios. In short, the DUT Universal Simulator transcends merely illustrative simulations or observational modeling. It positions itself as a rigorous analytical tool for the validation (or refutation) of major cosmological questions, empowering researchers and enthusiasts to test the limits of our understanding of the universe. Andrew Frantesch ExtractoDAO S.A +55 41 98792-2340 email us here Visit us on social media: LinkedIn Instagram YouTube X Legal Disclaimer: EIN Presswire provides this news content 'as is' without warranty of any kind. We do not accept any responsibility or liability for the accuracy, content, images, videos, licenses, completeness, legality, or reliability of the information contained in this article. If you have any complaints or copyright issues related to this article, kindly contact the author above.
Associated Press
13 hours ago
- Associated Press
Advanced DUT Simulation Technology Reproduces 'Impossible' Galaxies Observed by JWST and Challenges ΛCDM
New simulations reproduce high-redshift galaxies seen by JWST and propose a radical cosmological shift beyond ΛCDM. 'To simulate the universe with mathematical precision is to dismantle myths with data and disprove fiction through gravity.' — Joel Almeida -CEO CURITIBA, PARANá, BRAZIL, June 29, 2025 / / -- A newly released preprint by cosmology researcher and lead developer of the DUT Simulator, Joel Almeida, introduces a groundbreaking computational simulation based on the Dead Universe Theory (DUT), capable of reproducing the observed properties of massive galaxies at redshifts z > 8, including CEERS-1019 and GLASS-z13. These galaxies, detected by the James Webb Space Telescope (JWST), have challenged the predictions of the standard ΛCDM cosmological model. Using DUT's entropy-gradient-driven gravitational collapse, the simulations achieve under 5% accuracy in stellar mass, sub-kpc radius, and formation timescales below 100 million years—outperforming ΛCDM expectations by factors of ~5. Crucially, DUT offers falsifiable predictions and proposes that the universe is not expanding, but retracting within a non-singular, structural black hole. The full simulator is open-source and fully reproducible, available through ExtractoDAO for researchers worldwide. 🛰️ JWST Observes 'Impossible' Galaxies — A New Theory and Quantum Simulator Challenge the Big Bang A new study published as a preprint by researcher Joel Almeida, in collaboration with the scientific startup ExtractoDAO S/A, proposes a bold solution to one of modern cosmology's greatest mysteries: how could massive, compact galaxies have formed so early in the universe? Recent observations from the James Webb Space Telescope (JWST) identified galaxies such as CEERS-1019 (z = 8.67) and GLASS-z13 (z = 13.1), with stellar masses above 10¹⁰ M☉ and cores smaller than 1 kiloparsec—structures that, according to Big Bang and ΛCDM models, should not exist at such early epochs. In response to this enigma, the Dead Universe Theory (DUT) and its computational simulator presented remarkable results: the observed properties of these galaxies were reproduced with up to 5% accuracy, simulating ultrafast star formation (<100 million years) without requiring cosmic inflation or exotic dark matter. 'The simulations show that the universe doesn't need to have emerged from a singular point or to be expanding indefinitely. JWST data can be reinterpreted as evidence of asymmetric gravitational retraction within a larger, stable, non-singular cosmic structure,' says Almeida. The DUT model considers the observable universe to be an entropic bubble embedded in the core of a 'structural black hole'—non-singular, governed by a regularized oscillatory gravitational potential, capable of stabilizing galaxy formation without violating Einstein's equations. The computational tool used, named DarkStructSim™, is fully auditable, reproducible, and operates 100% offline, with future optional integration to quantum clouds such as IBM Quantum. Research Highlights: <5% accuracy in mass and size of z > 8 galaxies Explicit computation of core temperature, gravitational entropy , and cosmological constants ΛCDM refuted under extreme mass and redshift regimes Falsifiability proposed: if no galaxy with z > 12 and M > 10¹⁰ M☉ is observed by end of 2024, DUT will be considered refuted The research is available on Research Square under the title: 📝 Preprint 1.0: JWST High-z Galaxies in the Dead Universe Theory (DUT) Cosmological Framework 👉 Read the full paper: Any researcher can now reproduce the same simulation by downloading the offline code: 🔗 🔗 🔗 About the author: Joel Almeida is a cosmology researcher and founder of ExtractoDAO, a blockchain startup developing scientific technologies based on gravitational simulations, decentralized computing, and secure research infrastructures. 📩 Contact: [email protected] 🔗 ORCID: 0000-0003-4015-7694 🔬 Simulation Platform: Joel almeida ExtractoDAO S.A email us here Visit us on social media: LinkedIn Instagram YouTube Legal Disclaimer: EIN Presswire provides this news content 'as is' without warranty of any kind. We do not accept any responsibility or liability for the accuracy, content, images, videos, licenses, completeness, legality, or reliability of the information contained in this article. If you have any complaints or copyright issues related to this article, kindly contact the author above.
Yahoo
2 days ago
- Yahoo
Farthest 'mini-halo' ever detected could improve our understanding of the early universe
When you buy through links on our articles, Future and its syndication partners may earn a commission. While analyzing a 10 billion-year-old radio signal, astronomers discovered a "mini-halo" — a cloud of energetic particles — around a far-off cluster of galaxies. The unexpected findings could further our understanding of the early universe. This mini-halo is the most distant one ever detected, located twice as far from Earth as the next-farthest mini-halo. It is also massive, spanning more than 15 times the width of the Milky Way, and contains strong magnetic fields. The findings have been accepted for publication in The Astrophysical Journal Letters and are available on the preprint server arXiv. "It's astonishing to find such a strong radio signal at this distance," Roland Timmerman, a radio astronomer at Durham University who co-led the study, said in a statement. Mini-halos are faint groups of charged particles that emit radio and X-ray waves in the vacuum of space between galaxies. They have been detected around galaxy clusters in the local universe, but never as far back in space and time as the one reported in the new study. There are two theories that could explain the collection of particles, according to the researchers. One possible cause is the supermassive black holes at the centers of large galaxies within the distant cluster. These black holes can shoot high-energy particles into space, but it's not clear how the particles would travel away from a powerful black hole and into a mini-halo without losing significant energy. Another possible means of creation is the collision of charged particles within the plasma in a galaxy cluster. When these high-energy particles smash into each other, often at close to the speed of light, they can break apart into the kinds of particles that can be seen from Earth. Related: James Webb telescope unveils largest-ever map of the universe, spanning over 13 billion years Observations of the mini-halo come from light so old that it changes the picture of galaxy formation, proving that these charged particles have surrounded galaxies for billions of years longer than was known. "Our discovery implies that clusters of galaxies have been immersed in such particles since their formation," Julie Hlavacek-Larrondo, an astrophysicist at the University of Montréal who also co-led the research, told Live Science in an email. It's "something which we were not expecting at first." Scientists can now study the origin of these mini-halos to determine whether black holes or particle collisions are responsible for them. These particles also have a hand in other astrophysical processes, like star formation. They can affect the energy and pressure of the gas within a galaxy or couple with magnetic fields in unique ways. These processes can keep clouds of gas from collapsing, in turn altering how stars form in the gas. RELATED STORIES —'Totally unexpected' galaxy discovered by James Webb telescope defies our understanding of the early universe —Ghostly galaxy without dark matter baffles astronomers —Astronomers discover giant 'bridge' in space that could finally solve a violent galactic mystery "We are still learning a lot about these structures, so unfortunately the more quantitative picture is still very much in development," Timmerman told Live Science in an email. New radio telescopes, like the SKA Observatory, are in development to help astronomers detect even fainter signals and learn about mini-halos. "We are just scratching the surface of how energetic the early Universe really was," Hlavacek-Larrondo said.
