Kamala is returning. I can feel it.

As I understand the story of Babylon the Jews were freed from captivity because Babylon had become hopelessly corrupt, and undeniably evil, which was ending their civilization. Jews were then a hope for a renewed world that would face similar situations. And now we are in that moment. It is not up to the Jews to change people's hearts on that matter. You are more at that helm, and what you wish to do, to think of God can have ripples. If you want God, than God is right there, right in front of you, above, you, everywhere.

The sexiest most romantic man ever!

What if everything you thought you knew about time was completely wrong? A physicist is now proposing that time itself isn’t the simple, one-way flow we experience, but actually has three separate dimensions. This wild idea might even finally solve some of the biggest mysteries in science. MY LATEST VIDEOS Gunther Kletetschka from the University of Alaska Fairbanks has developed a mathematical model suggesting that our familiar sense of time ticking forward is like seeing only the tip of an iceberg. Beneath the surface, he argues, time has a hidden three-dimensional structure that could explain everything from why certain particles exist to how the entire universe works. Right now, physics has a major problem. Scientists have two incredibly successful theories that describe how the universe works, but they contradict each other. Einstein’s relativity explains big things like planets and black holes perfectly. Quantum mechanics explains tiny particles flawlessly. But when scientists try to combine them (like when studying what happens inside a black hole) the math breaks down completely. It’s like having two different instruction manuals for the same machine, and they give you opposite directions. Kletetschka’s three-dimensional time theory, published in World Scientific Connect, could be the missing piece that makes both instruction manuals work together. Hubble constant: Measuring the expanding universe Does the universe carry a third dimension of time? (Credit: © Irfanbm03 | Dreamstime.com) How Three-Dimensional Time Actually Works Think of time like a braided rope. From far away, it looks like a single strand moving in one direction. But up close, you can see it’s actually made of three separate cords twisted together. That’s essentially what Kletetschka is proposing about time itself. In his model, time has three different “directions” that operate at completely different scales: The first time dimension controls the tiniest processes in the universe — things happening inside atoms in less than a trillionth of a trillionth of a second. This is where quantum mechanics rules. The second time dimension acts like a bridge, connecting the microscopic quantum world to the everyday world we can see and touch. The third time dimension governs the slowest, most massive changes in the universe, like how galaxies form and evolve over billions of years. This is where Einstein’s gravity takes over. We only experience one dimension of time because the other two only matter at extremes we never encounter in daily life. It’s like living in a house and only noticing the ground floor, while the basement and attic exist but don’t affect your daily routine. The Theory Makes Stunning Predictions, And They’re Right Unlike many physics theories that are too abstract to test, Kletetschka’s model makes specific predictions about the real world. When scientists check those predictions against actual measurements, they match almost perfectly. Take subatomic particles, the building blocks of everything in the universe. These particles come in three distinct “families” or generations, kind of like three different sizes of the same basic tool. Scientists have known about this pattern for decades, but nobody could explain why there are exactly three families, or why their weights follow such specific patterns. Kletetschka’s theory says this happens because of the three time dimensions. It predicts that particles in these three families should have weight ratios of roughly 1 to 4.5 to 21. Here’s another way to make sense of it: if the lightest particle in a family weighs as much as a paperclip, the middle one should weigh like a smartphone, and the heaviest should weigh like a large textbook. This pattern shows up consistently across different types of particles, and the theory says it’s not a coincidence. It’s a direct result of how three-dimensional time is structured. The theory gets the exact measurements right with incredible precision. Scientists measure particle weights using special units called GeV and MeV (think of them like very precise scales for weighing things smaller than atoms). The theory predicted the top quark (the heaviest fundamental particle we know) should weigh 173.21 units. The actual measured weight? 173.2 units. Even more impressive, it predicted the weight of the muon (a heavier cousin of the electron that makes up atoms) correctly to seven decimal places. In the world of physics, that kind of accuracy really is like hitting a bullseye from miles away. Why Some Forces Act Weird—And How Time Explains It The theory also explains one of nature’s strangest behaviors. There’s a force called the weak nuclear force that governs radioactive decay, which is the process that makes some atoms unstable and break apart over time. This force has a bizarre quirk: it only interacts with particles that “spin” in one direction, like a cosmic preference for left-handed screws over right-handed ones. Scientists call this “parity violation,” and it’s like discovering that all the locks in the universe only turn clockwise, never counterclockwise. Nobody really understood why nature has this preference. Kletetschka’s model suggests the answer lies in the geometry of three-dimensional time itself. Just like a spiral staircase naturally curves in one direction, the structure of time creates this built-in asymmetry. It’s not an arbitrary rule, but rather a fundamental feature of how time is shaped. The theory also makes predictions about gravitational waves. These are ripples in space and time caused by massive cosmic events, like when two black holes crash into each other. These waves were only detected for the first time in 2015, confirming one of Einstein’s predictions about gravity. According to three-dimensional time theory, these waves should travel at slightly different speeds than light, being off by only 1.5 parts in a quadrillion. To put that in perspective, that’s like measuring the distance from New York to Los Angeles and being off by less than the width of a human hair. It’s an incredibly tiny difference, but our most sensitive detectors might be able to measure it. Testing the Theory: What Scientists Will Look For The beauty of this theory is that it doesn’t just make vague philosophical claims. It actually tells scientists exactly what to look for in their experiments. New particles: The theory predicts that scientists should discover specific new particles when they smash protons together at very high energies—energies about 2,000 to 4,000 times heavier than a proton. The Large Hadron Collider, the world’s most powerful particle accelerator, is being upgraded and might be able to find these particles in the next few years. Gravitational wave differences: Space-based detectors like LISA (Laser Interferometer Space Antenna) should be sensitive enough to measure those tiny speed differences in gravitational waves. If the theory is right, these waves should arrive at detectors just a few trillionths of a second later than light from the same cosmic event. Dark energy changes: Dark energy is the mysterious force causing our universe to expand faster and faster—like an invisible hand stretching space itself. Nobody knows what it is, but it makes up about 70% of everything in the universe. Kletetschka’s theory predicts that dark energy should change its behavior in a specific pattern over cosmic time. New space telescopes like Euclid are powerful enough to detect these changes by studying how galaxies are distributed across the universe. Neutrino masses: Neutrinos are ghost-like particles that barely interact with anything—trillions of them are passing through your body right now without you noticing. The theory makes precise predictions about how much these particles should weigh. Experiments like DUNE (Deep Underground Neutrino Experiment), which uses detectors buried deep underground, are designed to measure these masses with unprecedented precision. What This Means for Our Understanding of Reality If this theory proves correct, it would fundamentally change how we think about existence itself. Instead of matter existing within time, the theory suggests that matter is actually made from time. As Kletetschka puts it in his paper, “what we perceive as mass and energy are manifestations of temporal curvature and dynamics.” In simpler terms, the particles that make up your body, the energy that powers your brain, and even the gravity holding you to Earth might all be different expressions of how time bends and flows in three dimensions. This is a radically different way of thinking about reality. It’s the kind of paradigm shift that would make every physics textbook obsolete overnight, similar to how Einstein’s relativity overturned Newton’s clockwork universe, or how the discovery that Earth orbits the sun revolutionized astronomy. The Road Ahead: Proof or Disproof Of course, extraordinary claims require extraordinary evidence. The physics community will rightly demand rigorous proof before accepting such a radical reimagining of time itself. But unlike many “theories of everything” that make untestable predictions, this one gives scientists a clear roadmap for verification. Over the next decade, experiments will be able to definitively prove whether three-dimensional time is real or just an elegant mathematical fiction. The Large Hadron Collider’s upcoming high-luminosity upgrade will probe energy ranges where the predicted new particles should appear. Advanced gravitational wave detectors will become sensitive enough to measure the tiny speed variations the theory predicts. Space telescopes will map dark energy’s behavior across cosmic history with unprecedented precision. Perhaps most importantly, the theory makes specific numerical predictions that leave little room for ambiguity. Either the neutrinos have exactly the masses it predicts, or they don’t. Either the new particles appear at the predicted energies, or they don’t. Either gravitational waves show the predicted speed differences, or they don’t. In science, theories live or die by their predictions. And this theory has given scientists plenty of targets to aim for. If experiments confirm these predictions, we’ll need to rethink our place in a universe where time itself has hidden dimensions we never imagined. If the predictions fail, it will join the long list of beautiful ideas that couldn’t survive contact with reality. Either way, we’re about to learn something profound about the nature of time itself. Paper Summary Methodology Kletetschka built his theory by extending Einstein’s equations from four dimensions (three space, one time) to six dimensions (three space, three time). He used mathematical tools called tensors—essentially multi-dimensional spreadsheets that track how things change in all directions at once. The theory uses a specific mathematical signature (written as +,+,+,−,−,−) that determines how the different dimensions interact. He then calculated how particles would behave in this expanded framework and derived conservation laws—mathematical rules that ensure energy and momentum are never created or destroyed, just moved around. Results The model naturally produces three families of particles with mass ratios of 1:4.5:21.0, matching observed reality. It correctly predicts known particle masses, including the top quark (173.21 ± 0.51 GeV vs. measured 173.2 ± 0.9 GeV) and muon (105.6583745 MeV vs. measured 105.6583755 MeV). For neutrinos, it predicts specific masses: tau neutrino at 0.058 ± 0.004 eV and muon neutrino at 0.0086 ± 0.0003 eV. The theory predicts new particles should appear at energies of 2.3 ± 0.4 TeV and 4.1 ± 0.6 TeV. It also predicts gravitational waves should travel at speeds differing from light by 1.5 ± 0.3 parts in a quadrillion, and that dark energy should evolve according to a specific mathematical formula over cosmic time. Limitations This is purely theoretical work—there’s no direct way to observe extra time dimensions. The theory’s validity depends entirely on whether its predictions match future experimental results. Many of the predicted effects require cutting-edge detectors and particle accelerators that are just now coming online or still under construction. The mathematical complexity means that even small errors in the framework could lead to completely wrong predictions. Additionally, the concept of three-dimensional time challenges such fundamental assumptions about reality that it may face significant resistance from the scientific community regardless of experimental evidence. Funding and Disclosures The research was supported by grant 23-06075S from the Czech Science Foundation. Kletetschka acknowledged doctoral student Nicholas Hasson at University of Alaska Fairbanks for philosophical discussions about the three-dimensional time framework. The paper was published under an open access license, meaning anyone can read it for free. No conflicts of interest were reported. Publication Information The paper “Three-Dimensional Time: A Mathematical Framework for Fundamental Physics” by Gunther Kletetschka was published in Reports in Advances of Physical Sciences, Volume 9 (2025), article number 2550004. The journal received the paper on November 27, 2024, accepted it on February 24, 2025, and published it on April 21, 2025. Kletetschka is affiliated with both the Geophysical Institute at University of Alaska Fairbanks and the Faculty of Science at Charles University in Prague, Czech Republic. Share: Pin Facebook Tweet Yummly Email About StudyFinds Analysis Called "brilliant," "fantastic," and "spot on" by scientists and researchers, our acclaimed StudyFinds Analysis articles are created using an exclusive AI-based model with complete human oversight by the StudyFinds Editorial Team. For these articles, we use an unparalleled LLM process across multiple systems to analyze entire journal papers, extract data, and create accurate, accessible content. Our writing and editing team proofreads and polishes each and every article before publishing. With recent studies showing that artificial intelligence can interpret scientific research as good as (or even better) than field experts and specialists, StudyFinds was among the earliest to adopt and test this technology before approving its widespread use on our site. We stand by our practice and continuously update our processes to ensure the very highest level of accuracy. Read our AI Policy (link below) for more information.

Be it may that Jews are God's People, does not mean a special favor, but in the event that Jews are killed as in genocide (Holocaust) is the same act as killing God. The killers know the symbolism and therefore would be into EVIL: LOGIC.

The garden of earth delights, for your moonlit pleasure, make yourself comfortable and do the dance. Then night is warm, warm enough, and the tiger is closing in, you wonder, if its an illusion, the flamingos dance also, stars spin like celestial tops.

The best is yet to come.

Multiple countries employ police security measures to protect Jewish communities, especially around synagogues, schools, and community centers. This heightened security has been observed in various locations, especially following incidents like the October 7th attacks in Israel. In response to increased antisemitism and threats, several countries have enhanced police security for Jewish communities. This includes heightened surveillance around synagogues, schools, and community centers in countries such as France, Germany, the United Kingdom, and Spain. Other countries that have taken measures include: Italy, which has bolstered police protection. The United States, where the government has allocated increased funding for security at religious organizations. Australia, which has committed funding for security at Jewish community sites. Switzerland, which has increased its annual contributions towards the security of Jewish institutions. Additionally, Canada and Argentina have seen calls for increased security due to rising antisemitism. Greece, Brazil, and South Africa also provide financial aid to Jewish institutions for security.

The provided information suggests that several European countries have increased police security around Jewish institutions, particularly in response to concerns about antisemitism and the Israel-Hamas conflict. Countries with increased police security for Jewish communities: France: Has the largest Jewish population in Europe and has seen a notable increase in police surveillance and arrests related to antisemitic incidents. The government spends millions on protecting Jewish institutions and has deployed soldiers to guard community buildings. Germany: Authorities have intensified security around synagogues, community centers, and Israeli diplomatic sites. The head of Germany's largest police union has highlighted the commitment to Jewish security and called for broader measures against antisemitism and extremism. United Kingdom: Police have increased patrols and surveillance around synagogues and other Jewish institutions. The Community Security Trust (CST) also advises Jewish residents to remain vigilant. Spain: Police have increased surveillance around synagogues and other institutions. Italy: Has also adopted measures to bolster police protection of Jewish communities.

America loves smart people!

The river runs red, and all the apples dies in one night, she was running fast, she said, I took too many things in life, took things for granted, thought it was a collecting game, had my craps and dice to play.

It is hard to imagine beauty with out some degree of moral courage.

This blog will be playing a more limited role in the future. Success has happened to the degree that makes me happy.

The Better World Project started as just an idea, but I liked enough. Then when it showed that some powerful people liked it I was lifted in my hopes for it. Yet after working for the idea to succeed I was met with something similar to death threats and discouragement. I was shocked.