Visualizing Quantum Tunneling Through a Gaussian Barrier! Witness how... a wave packet interacts with a Gaussian potential barrier, demonstrating the probabilistic nature of subatomic particles. This video breaks down the Schrodinger equation and the WKB approximation to explain how particles can tunnel through barriers they should not be able to pass classically. Whether you are a physics student or just curious about the universe, see the math come to life as we track incident, reflected, and transmitted waves. #QuantumPhysics #QuantumMechanics #SchrodingerEquation #QuantumTunneling #Manimshow more

Equationsinmotion
30,333 просмотров • 4 дней назад
Under the hood of every gaussian splat lives a... point cloud - what this mean is we can do some really cool things! With points and particles being so relative - you can actually treat them as if they were the same. Here we're using INSYDIUM X-Particles to drive a nexus particle simulation from the millions of splat points directly. This opens the doors to tons of creative opportunities for splats via XP with the full stack of modifiers and controls to take your splat assets to the next level! Rendered with OTOY Octane 2026show more

Spenser Dickerson
12,055 просмотров • 6 месяцев назад
🚨 PHYSICISTS JUST SPLIT A SINGLE PHOTON AND IT... TURNED INTO AN IMPROBABLE SWARM OF PARTICLES. In a striking experiment, researchers have shown that a photon can be split apart in such a way that it produces a large number of particles, creating what they describe as a “mixture from zero to infinity.” Instead of the usual clean splitting into two photons (as seen in spontaneous parametric down-conversion), this process generated a complex, broad swarm of particles. The result challenges conventional intuition about how photons behave when pushed into extreme nonlinear regimes. Why this matters: • It demonstrates a rare and complex form of photon splitting that was previously very difficult to observe cleanly • Such processes could help simulate high-energy particle physics in table-top experiments • It opens new possibilities for generating exotic quantum states of light • It provides deeper insight into nonlinear quantum electrodynamics (QED) in strong fields The deeper implication: Photons are usually thought of as indivisible quanta of light. But under the right extreme conditions, a single photon can effectively “break apart” into many particles. This isn’t just a curiosity it touches on fundamental questions about the nature of light and matter, and could eventually lead to new tools for quantum technologies and for studying physics that normally requires particle accelerators. We’re seeing light behave in ways that blur the line between a single quantum and a many-particle system. How do you think being able to controllably split photons into swarms of particles could impact quantum optics or fundamental physics research? Follow for more frontier quantum physics and breakthroughs in light-matter interaction.show more

TheNewPhysics
25,874 просмотров • 23 дней назад
If you come over the top, you should set... up a barrier during every range session. @theswingplate makes a great, functional barrier to use. I explain this mistake and how to keep good body moves in Golf Swing Fully Explained.show more

Slomoswinglibrary
52,104 просмотров • 2 месяцев назад
🚨 BREAKING: Scientists just made topology visible in a... spinning fluid. Not in a quantum computer. Not in a particle collider. In water. By sending standing waves through a vortex, researchers watched quantized nodal lines appear across the whole system lines where the wave amplitude drops to zero. Why that matters: → It’s a fluid analogue of the Aharonov–Bohm effect → The response is non-local → Topology didn’t stay near the core… it shaped the entire wave field That’s the deeper point: Physics isn’t always hidden in particles. Sometimes it shows up as structure in motion. If wave topology can be seen this clearly in fluids, what else in quantum physics might be hiding in plain sight? Follow me for the next wave of physics breakthroughs.show more

TheNewPhysics
24,005 просмотров • 2 месяцев назад
The Basics of Electromagnetic Waves: Electricity and magnetism can... sit still, like static electricity in your hair or a magnet stuck to your fridge. But when they move and change, they actually create each other. Together, they team up to form invisible ripples of energy called electromagnetic waves. Unlike ocean waves or sound waves, which need water or air to ripple through, electromagnetic waves don't need any material at all. They can easily travel through the completely empty vacuum of space. Maxwell's Big Idea: In the 1860s and 1870s, a Scottish scientist named James Clerk Maxwell figured out how this works. He wrote down the math showing exactly how electricity and magnetism link together to make these travelling waves. Today, scientists call his famous rules Maxwell's Equations. Hertz Proves It: Later, a German physicist named Heinrich Hertz took Maxwell's ideas and brought them to life. He was the first person to actually create and catch radio waves. To honour his work, we use the word hertz to measure how fast a wave vibrates (one cycle per second). Hertz's experiments proved two massive ideas: Radio waves are just invisible light: He showed that radio waves travel at the exact same speed as light, proving that they are actually a form of light we just can't see. Going wireless: He finally figured out how to detach these energy fields from physical wires, allowing the waves to fly freely through the air exactly as Maxwell had predicted.show more

The Math Flow
37,313 просмотров • 2 месяцев назад
🚨 BREAKING: Physicists just observed a completely new quasiparticle:... the “ferron.” Not a magnon. Not a phonon. A ferron is a coherent polarization wave moving through a ferroelectric crystal — essentially a wave of electric order itself. Researchers fired ultrafast laser pulses into layered quantum materials and watched polarization waves propagate with long coherence times while emitting narrow-band THz radiation. This is wild because it means electric polarization can behave like a transportable quantum information carrier. Potential implications: • ferronic computing • THz communication systems • coherent electric control • entirely new information architectures Matter is starting to look less like particles… and more like organized propagating structure. The quasiparticle era is accelerating fast. Follow me if you want the frontier of quantum materials explained before it hits mainstream physics.show more

TheNewPhysics
52,576 просмотров • 2 месяцев назад
.Southwest Airlines has commenced flying a B737Max with a... secondary barrier to the flight deck designed to prevent intrusions. This is the first such aircraft in their fleet. It's fascinating to see how the barrier works in this video. #AvGeekshow more

VT-VLO
117,623 просмотров • 10 месяцев назад
🚨 SCIENTISTS JUST DETECTED QUANTUM ENTANGLEMENT IN A CENTIMETER-SIZED... PIECE OF METAL SOMETHING ONCE THOUGHT IMPOSSIBLE AT THIS SCALE. Researchers at the Vienna University of Technology have found clear evidence of high-degree quantum entanglement among particles inside a macroscopic crystal of a “strange metal” made of cerium, palladium, and silicon. This is one of the first times multipartite entanglement has been convincingly demonstrated in a solid object large enough to hold in your hand. Strange metals are already bizarre their electrons don’t behave like normal individual particles. Now it appears large numbers of them can act as a single, highly entangled quantum system even at everyday scales. Why this matters: • Quantum entanglement has almost always been limited to tiny numbers of particles in carefully isolated lab conditions • This experiment shows entanglement can persist collectively across a visible, macroscopic object • It was measured using neutron scattering, which revealed the material responding as one entangled system rather than many independent particles • This bridges the gap between microscopic quantum effects and real-world materials The deeper implication: For decades, physicists have wondered whether the strange, collective behavior seen in certain quantum materials could be explained by underlying entanglement. This result strongly suggests the answer is yes even at scales we can see and touch. It doesn’t mean your coffee mug is in a quantum superposition, but it does show that quantum correlations can dominate the physics of certain solids in ways we’re only beginning to understand. This kind of macroscopic quantum behavior could eventually help us design new materials with exotic properties, or give us new tools to study fundamental questions about quantum mechanics itself. How do you think discovering entanglement at this scale changes our understanding of where the quantum world ends and the classical world begins? Follow for more frontier quantum physics and materials science.show more

TheNewPhysics
17,001 просмотров • 20 дней назад
🚨 BREAKING: Physicists just measured “negative time” in the... lab. Not theory. Not math. Measured. What actually happened Scientists fired photons (particles of light) through a cloud of atoms. Normally, light should: • Enter • Interact • Exit Simple. But instead… The photons appeared to exit before they entered. It gets stranger They didn’t just infer this from timing. They measured how long the photon “lived” inside the atoms. Result: Negative dwell time. The atoms themselves confirm it. So is time broken? No but our intuition is. This comes from quantum mechanics: • Photons aren’t single points they’re spread-out waves • Only certain parts of the wave make it through • That skews the average timing But here’s the key: Two completely different measurements gave the same negative value That means: This isn’t a measurement error. It’s a real, observable quantum effect. Why this matters This challenges one of the deepest assumptions: That time always moves forward in a simple, measurable way. At the quantum level: • “Time spent” isn’t always positive • Interactions don’t behave classically • Reality is shaped by probability, not sequence The deeper idea What we call “time” might not be a flow… It might be a constraint on interactions. And under certain conditions? That constraint bends. Follow me I break down the moments where physics stops behaving normally.show more

TheNewPhysics
103,479 просмотров • 2 месяцев назад
Did you even listen to the members during Arirang... Notes and other interviews? Do you really think you know better than them? This isn’t about choosing Come Over over Into the Sun or the other way around. Both deserve to be heard properly. We wanted Come Over to be included in the album as well, not just as a hidden track—we genuinely find it moving and truly a masterpiece. But that doesn’t mean another track should be pushed down or replaced. It’s about giving space to both songs without removing anything at all.show more

V Philippines 🇵🇭 ʟᴀʏᴏ(ꪜ)ᴇʀ¹⁰⁰
50,816 просмотров • 3 месяцев назад
Math says the Big Bang made matter and antimatter... in equal halves. They should have erased each other into light, leaving no one to see it. And yet, you exist, because nature miscounted by one part in a billion. Math says nothing forbids a particle from outrunning light. The equations hand it an imaginary mass and let it through. And yet, in a century of looking, not one has ever shown up. Math says you can have a north without a south. Break a magnet, isolate the pole. And yet break it a trillion times, you get a trillion little magnets, each with both ends intact. The universe reads the math and decides what it’s willing to be.show more

Kekius Maximus
13,362 просмотров • 25 дней назад
Taylor Approximation ✍️ It shows a mathematical "best guess"... evolving to match a complex 3D shape by adding layers of detail one step at a time. The purple surface is the original goal, while the red grid represents a polynomial approximation anchored at the center point. At first, the red surface can only mimic the very middle of the shape. As the calculation adds more terms, visualized by the red grid rippling and shifting, the approximation "learns" how to curve and bend to match the target more accurately. This is a visual demonstration of how math can break down a detailed, wavy landscape into simpler instructions. When these instructions are stacked together, they recreate the entire surface with incredible precision. Video: mathwithmuzaashow more

ScieVision
11,384 просмотров • 4 месяцев назад
🚨QUANTUM🚨: A brand new quantum state just appeared that... links two fields we thought were separate 🧨 Scientists at Rice University have discovered a new quantum state of matter that connects quantum criticality — where electrons fluctuate between different phases — with electronic topology, which describes organized wave-like behavior of electrons. This hybrid state could open new paths for advanced computing, sensing, and materials. Source: Rice University news release on a study published in Nature Physics (January 2026). Uniphics explains this emergence directly through spin-wave dynamics in the ξM-field. Each Gyrotron is a stable 3D gyroscope formed by three orthogonal spin quanta — every quantum a tempest of whirling energy spinning clockwise or counterclockwise in its own plane. When local energy density and spin bias allow mixed configurations (similar to the musktron and maleytron patterns), the resulting spin-wave interference naturally produces both critical fluctuations and topological order at the same time. Negentropy favors these hybrid states because they represent lower-energy, organized patterns within the field. No new particles or exotic couplings are needed; the same principles that govern particle formation, the weak and strong forces through spin alignments, and the low-acceleration gravitational surge also allow these combined quantum behaviors in real materials when conditions permit. This turns the “unexpected new quantum state” into a predicted outcome of spin-wave physics once the three pillars are allowed to select stable hybrid configurations. How might recognizing that hybrid quantum states arise from mixed spin-wave interference change the way we search for new materials or design future quantum technologies? A Theory of Everything should be able to answer everything. Uniphics Explained Simply PDF: Chapters 1–10 free: Grokipedia #Uniphics #QuantumStates #SpinWaves #Topology #QuantumCriticality Grok xAIshow more

Paul Maley
22,669 просмотров • 1 месяц назад
🚨 BREAKING: This is what happens when particles collide... at near light speed. Inside CERN, protons smash together… and for a fraction of a second something invisible appears. Then vanishes. Read that again. We don’t see the Higgs boson directly. We see the pattern it leaves behind. Energy explodes outward. Particles scatter in every direction. And hidden in that chaos structure reveals itself. This is how we found the particle that gives mass to everything. In my view Particles aren’t things They’re events in a field What we call “mass” is a stable interaction with structure So this isn’t just a collision… It’s reality briefly exposing how it builds itself. The real question is If particles only exist as interactions… what is the structure they emerge from? Follow me I break down how structure shapes reality.show more

TheNewPhysics
12,681 просмотров • 3 месяцев назад
This is the "stone-pelting" wing of UP Police trying... to stop loaded trucks as it pass through a toll barrier in Sonbhadra district of Uttar Pradesh.show more

Piyush Rai
425,128 просмотров • 10 месяцев назад
one more thing this wasn’t incheon airport and all... fans were kept behind barriers until they passed passport control. they weren’t allowed outside the barrier as you can see in the video WHICH IS GOOD enha was able to walk freely there’s no other side to it.show more

🦊♡🐰ྀི | fan acc
36,817 просмотров • 3 месяцев назад
🚨 PARKER SOLAR PROBE JUST FOUND HIGH-ENERGY PARTICLES NEAR... THE SUN THAT NO MODEL PREDICTED AND WE DON’T KNOW HOW THEY GOT SO ENERGETIC. During its close passes through the solar corona, NASA’s Parker Solar Probe detected protons accelerated to energies around 400 keV roughly 1,000 times higher than current models of magnetic reconnection at the heliospheric current sheet could explain. The particles appear to be trapped and energized inside magnetic islands that form and merge during reconnection events at the current sheet (the vast surface where the Sun’s magnetic field flips polarity). This mechanism was not expected to produce such high energies so close to the Sun. Why this matters: • It reveals a previously unknown or underestimated source of energetic particles right in the solar corona • Existing models of solar energetic particles have focused mainly on shocks from coronal mass ejections — this suggests reconnection can also be a powerful accelerator • The same process may be contributing more to coronal heating than previously calculated • It has implications for space weather forecasting, since these particles can affect spacecraft and astronauts The deeper implication: Parker is showing us that the physics of the near-Sun environment is more energetic and complex than our models assumed. Magnetic reconnection long known as an important process appears capable of accelerating particles to surprisingly high energies through the merging of magnetic islands. This doesn’t just tweak our understanding of the Sun; it may force revisions in how we model particle acceleration across many astrophysical environments. We’re still in the early stages of understanding what Parker is revealing, but it’s already clear that the corona is more violent and dynamic than we thought. How do you think this discovery might change our models of space weather or solar physics in the coming years? Follow for more updates from Parker Solar Probe and the evolving picture of our Sun.show more

TheNewPhysics
16,192 просмотров • 19 дней назад
🚨 PHYSICISTS JUST CONFIRMED “NEGATIVE TIME” IS REAL IN... A MIND-BENDING QUANTUM EXPERIMENT. Light can exit a cloud of atoms before it even enters. In a new experiment, researchers fired photons through a dense cloud of ultra-cold atoms and measured something that shouldn’t be possible in classical physics. Some photons appeared to spend a negative amount of time inside the cloud effectively leaving before they had fully arrived. Why this matters: • This isn’t time travel it’s a quantum effect involving how light interacts with matter at the deepest level • It comes from “weak measurements” that let scientists observe the system without fully disturbing it • The atoms themselves “report” spending negative time in an excited state • It challenges our everyday intuition about cause and effect in quantum systems The deeper implication is enormous: We are seeing the strange, non-intuitive nature of quantum mechanics play out in real experiments. Time at the quantum scale doesn’t always behave like the arrow we experience in daily life. Effects can appear to precede causes in measurable ways without breaking relativity or causality. This is one of the clearest experimental windows yet into how reality works at its most fundamental level. What do you think does “negative time” change how you see reality, or is it just another quantum quirk we’ll eventually get used to? Follow for more frontier physics and reality-bending discoveries.show more

TheNewPhysics
22,256 просмотров • 1 месяц назад
🚨 BREAKING NEWS 🚨 SCIENTISTS JUST TELEPORTED QUANTUM INFORMATION... THROUGH THE EXISTING INTERNET. Not in a lab vacuum. Not through a special quantum-only cable. They did it through real internet fiber while normal internet traffic (400 Gbps) was still flowing. Researchers at Northwestern University successfully transmitted a quantum state of light across 30 km of active fiber optic cable, proving quantum signals can coexist with the classical internet we already use. Why this matters: Today’s internet moves classical bits. A quantum internet could enable virtually unhackable communication, distributed quantum computing, and ultra-secure networks. Quantum information cannot be copied without disturbing it a built-in security feature. The deeper implication: The internet may evolve from moving classical information into moving quantum states themselves. At that point, the line between communication and computation begins to disappear. We may be watching the early construction of an entirely new layer of civilization. Follow for more frontier physics and future technology.show more

TheNewPhysics
28,665 просмотров • 1 месяц назад