“The result is more than the creation of a new quantum state. It is a demonstration of a new method for engineering interactions that were previously out of reach,” said Dr. Oana Băzăvan, lead author from the Department of Physics, University of Oxford.
“The fourth-order quadsqueezing interaction was generated more than 100 times faster than expected using conventional approaches. This makes effects that were previously out of reach accessible in practice,” Băzăvan added.
Physicists have long used a trick called “squeezing” to sharpen the fuzzy measurements of the subatomic world. It is why gravitational-wave detectors, like LIGO, can hear black holes colliding across the universe. But for all its utility, ordinary squeezing is a relatively simple, second-order effect.
An experiment with a carbon material in a magnetic field has revealed a novel way for electrons to move, which doesn’t fully belong in two or three spatial dimensions
WASHINGTON — The Defense Advanced Research Projects Agency has awarded contracts to three companies to study concepts for a lunar mission to search for water ice in very low orbits.
DARPA announced last year the Lunar Assay via Small Satellite Orbiter (LASSO) program. LASSO would demonstrate the ability to operate in a very low orbit around the moon while searching for locations on the moon that contain water ice at concentrations greater than 5%.
The mission, the agency stated, would test “sustained and advanced maneuverability” needed to maintain that low orbit, with applications elsewhere in cislunar space. The scientific data from the mission would support both NASA and commercial efforts to use lunar resources.
L-arginine helps protein droplets stay stable and prevents fibril formation linked to Alzheimer’s. This process occurs at droplet surfaces, offering a potential therapeutic target.
New research reveals that high glucose levels drive stem cells to multiply, while low levels signal them to mature into myelin-producing cells, a discovery that could lead to new metabolic strategies for treating white matter injuries and MS.
As we go through life, our brains run different processing modes. Some – the attention and sensory systems – result in very similar experiences of the world: what colour the sky is, how warm the day feels.
But there is another, deeper side to the brain which weaves together your memories, goals, beliefs and emotions into a continuous sense of self. This allows you to experience the world not as it is, but as it matters to you personally.
This unique inner world is supported by the brain’s default mode network (DMN). This links together several areas including in the prefrontal cortex (at the very front of the brain) and the parietal lobe (at the back).
Physicists have long assumed that the universe is uniform at very large scales, but evidence is emerging this is wrong and suggests a way to resolve some of the biggest cosmological mysteries
That framing goes too far. Physics doesn’t prove that God is “impossible”—it deals with testable models of the natural world, not metaphysical conclusions. If you present it as a logical or scientific analysis of physical claims, it will sound stronger and more credible. Here’s a refined, high-impact description in the same style—without overclaiming:
Does modern physics leave any room for God? In this video, we examine that question through the analytical lens of Richard Feynman — not as a matter of belief, but as a question about how the universe actually behaves when studied with precision. Physics does not argue against God. It does something more demanding: it builds a complete, self-consistent description of reality based entirely on measurable laws — and asks whether external intervention is required anywhere within that structure. Over four centuries, those laws have expanded to describe everything from subatomic particles to cosmic evolution — without a single confirmed exception. So where, if anywhere, does a non-physical agent fit?
In this video, we walk through the physical framework that raises this question: The conservation laws that govern every interaction. The causal structure of spacetime and what it permits. Thermodynamic limits on energy, order, and change. The constraints of information in a physical universe. And the boundary between scientific knowledge and unfalsifiable claims.
This is not a debate about belief. It’s an examination of structure. Because when physics describes the universe with increasing completeness, it doesn’t explicitly disprove metaphysical ideas — but it does redefine what counts as an explanation. And that shift has consequences.
⚡ Why This Matters: Understanding what science can and cannot say is just as important as understanding what it discovers.
📌 Watch till the end — the conclusion isn’t what most people expect.
