ch
Feedback
Daily Science to all

Daily Science to all

前往频道在 Telegram

5 newZ per day

显示更多

📈 Telegram 频道 Daily Science to all 的分析概览

频道 Daily Science to all (@sciencetoall) 英语 语言赛道中的 是活跃参与者。目前社区聚集了 11 107 名订阅者,在 技术与应用 类别中位列第 11 135,并在 中国 地区排名第 18 307

📊 受众指标与增长动态

невідомо 创建以来,项目保持高速增长,吸引了 11 107 名订阅者。

根据 30 六月, 2026 的最新数据,频道保持稳定运转。过去 30 天订阅人数变化为 -41,过去 24 小时变化为 -4,整体触达仍然可观。

  • 认证状态: 未认证
  • 互动率 (ER): 平均受众互动率为 4.13%。内容发布后 24 小时内通常能获得 1.71% 的反应,占订阅者总量。
  • 帖子覆盖: 每篇帖子平均可获得 459 次浏览,首日通常累积 190 次浏览。
  • 互动与反馈: 受众积极参与,单帖平均反应数为 0
  • 主题关注点: 内容集中在 scientist, researcher, discovery, matter, plasma 等核心主题上。

📝 描述与内容策略

作者将该频道定位为表达主观观点的平台:
5 newZ per day

凭借高频更新(最新数据采集于 01 七月, 2026),频道始终保持新鲜度与高覆盖。分析显示受众积极互动,使其成为 技术与应用 类别中的关键影响点。

11 107
订阅者
-424 小时
-67
-4130
吸引订阅者
七月 '26
七月 '260
在0个频道中
六月 '26
+56
在0个频道中
Get PRO
五月 '26
+73
在0个频道中
Get PRO
四月 '26
+35
在0个频道中
Get PRO
三月 '26
+15
在0个频道中
Get PRO
二月 '26
+24
在0个频道中
Get PRO
一月 '26
+41
在0个频道中
Get PRO
十二月 '25
+53
在0个频道中
Get PRO
十一月 '25
+30
在0个频道中
Get PRO
十月 '25
+24
在7个频道中
Get PRO
九月 '25
+40
在1个频道中
Get PRO
八月 '25
+19
在0个频道中
Get PRO
七月 '25
+20
在2个频道中
Get PRO
六月 '25
+47
在0个频道中
Get PRO
五月 '25
+45
在1个频道中
Get PRO
四月 '25
+82
在0个频道中
Get PRO
三月 '25
+63
在0个频道中
Get PRO
二月 '25
+47
在0个频道中
Get PRO
一月 '25
+72
在0个频道中
Get PRO
十二月 '24
+99
在0个频道中
Get PRO
十一月 '24
+237
在1个频道中
Get PRO
十月 '24
+191
在0个频道中
Get PRO
九月 '24
+188
在0个频道中
Get PRO
八月 '24
+208
在2个频道中
Get PRO
七月 '24
+96
在0个频道中
Get PRO
六月 '24
+193
在3个频道中
Get PRO
五月 '24
+199
在4个频道中
Get PRO
四月 '24
+207
在0个频道中
Get PRO
三月 '24
+235
在1个频道中
Get PRO
二月 '24
+295
在5个频道中
Get PRO
一月 '24
+242
在1个频道中
Get PRO
十二月 '23
+225
在1个频道中
Get PRO
十一月 '23
+119
在0个频道中
Get PRO
十月 '23
+127
在3个频道中
Get PRO
九月 '23
+140
在0个频道中
Get PRO
八月 '23
+186
在0个频道中
Get PRO
七月 '23
+182
在0个频道中
Get PRO
六月 '23
+183
在0个频道中
Get PRO
五月 '23
+194
在0个频道中
Get PRO
四月 '23
+114
在0个频道中
Get PRO
三月 '23
+133
在0个频道中
Get PRO
二月 '23
+108
在0个频道中
Get PRO
一月 '23
+165
在0个频道中
Get PRO
十二月 '22
+197
在0个频道中
Get PRO
十一月 '22
+158
在0个频道中
Get PRO
十月 '22
+150
在0个频道中
Get PRO
九月 '22
+253
在0个频道中
Get PRO
八月 '22
+156
在0个频道中
Get PRO
七月 '22
+350
在0个频道中
Get PRO
六月 '22
+275
在0个频道中
Get PRO
五月 '22
+302
在0个频道中
Get PRO
四月 '22
+195
在0个频道中
Get PRO
三月 '22
+202
在0个频道中
Get PRO
二月 '22
+160
在0个频道中
Get PRO
一月 '22
+234
在0个频道中
Get PRO
十二月 '21
+140
在0个频道中
Get PRO
十一月 '21
+162
在0个频道中
Get PRO
十月 '21
+271
在0个频道中
Get PRO
九月 '21
+339
在0个频道中
Get PRO
八月 '21
+444
在0个频道中
Get PRO
七月 '21
+276
在0个频道中
Get PRO
六月 '21
+332
在0个频道中
Get PRO
五月 '21
+410
在0个频道中
Get PRO
四月 '21
+349
在0个频道中
Get PRO
三月 '21
+427
在0个频道中
Get PRO
二月 '21
+341
在0个频道中
Get PRO
一月 '21
+531
在0个频道中
Get PRO
十二月 '20
+11 125
在0个频道中
日期
订阅者增长
提及
频道
01 七月0
频道帖子
🌞 The Sun Is Waking Up Fast — A Major X-Class Solar Flare Could Happen at Any Moment Solar activity has accelerated dramatically over the past 48 hours, and space weather scientists are watching closely. The number of solar flares has surged from 5 per day two days ago, to 8 yesterday, and 17 within the last 24 hours. This morning, the Sun produced its first M-class flares of the current activity spike — leaving only the most powerful category, X-class, yet to appear. What’s making scientists especially cautious is the location of the Sun’s largest active region of 2026. It is currently facing almost directly toward Earth. Surprisingly, despite its enormous size, it has not yet produced a single X-class flare. Earlier this year, another large sunspot group generated five X-class flares, including the year’s strongest event, X8.1. That makes the current quietness look more like the calm before the storm than a sign of stability. Space-based observations reveal an even more intriguing picture. Two giant sunspot groups that appear separate on the solar surface are actually connected high above it in the corona, forming a single, highly complex magnetic system. These intertwined magnetic fields continuously exchange energy. On one hand, this can relieve local magnetic stress. On the other, it effectively creates one enormous energy reservoir capable of producing an exceptionally powerful eruption. Predicting exactly when that energy will be released remains one of the biggest challenges in solar physics. Most of the Sun’s magnetic field lies hidden beneath the visible surface, beyond direct observation, making even the most sophisticated computer models unreliable for systems this complex. For now, an X-class solar flare could occur at virtually any time. If accompanied by a coronal mass ejection directed toward Earth, it could trigger strong geomagnetic storms, spectacular auroras at unusually low latitudes, and temporary disruptions to satellites, radio communications, and navigation systems. 🔭 The Sun is reminding us that even after centuries of observation, our nearest star can still surprise us. #Science #Astronomy #Sun #SolarFlare #SpaceWeather #SolarStorm #Heliophysics

2
🌋 Yellowstone May Not Be Powered by a Deep Mantle Plume After All Yellowstone is one of Earth’s most famous supervolcanoes — and for decades, many geologists explained it with a familiar image: a deep mantle plume, a vertical column of hot rock rising from near Earth’s core, similar to the plume that built Hawaii. A new study in Science suggests a very different mechanism. Researchers built a high-resolution 3D geodynamic model of western North America and found that Yellowstone’s magma may be supplied not by a deep plume, but by the shallow asthenosphere — the hot, slowly flowing layer of mantle just beneath the rigid lithosphere. The driver is what the authors call an eastward “mantle wind”: a broad horizontal flow of hot rock moving beneath North America at geologic speeds. This flow appears to be linked to the ancient Farallon Plate, which began sliding beneath North America tens of millions of years ago. Remnants of that plate still sit deep under the continent. As they continue to sink, they help generate a large-scale mantle flow that pushes hot asthenospheric material toward Yellowstone. Then comes the key part: as this buoyant material is forced beneath the thick continental lithosphere, the stretching and pressure changes trigger decompression melting — producing magma without requiring a deep plume rising from the core-mantle boundary. The model also helps explain Yellowstone’s unusual underground plumbing. Competing tectonic forces appear to tear the lithosphere beneath the region, creating a southwest-dipping channel. This channel acts like a pathway for magma to rise, spread and evolve into a vast “magma mush” system rather than a simple, long-lived liquid magma chamber. Why it matters: supereruptions can eject more than 1,000 cubic kilometers of material, blanket huge regions in ash and affect climate for years. Understanding what actually sustains systems like Yellowstone is crucial for long-term volcanic hazard models. The big takeaway: Yellowstone may be less like a blowtorch from Earth’s deep interior — and more like a tectonic wound kept active by the slow, hidden motion of an ancient plate. Source: https://www.science.org/doi/10.1126/science.ady2027 Readable summary: https://www.sciencedaily.com/releases/2026/06/260622014317.htm #Yellowstone #Supervolcano #Geology #EarthScience #Science
314
3
🪐 Astronomers Found Two Giant Planets Less Dense Than Cotton Candy Astronomers have confirmed the existence of two of the puffiest planets ever discovered — gas giants roughly the size of Jupiter, but with densities so low they are less dense than cotton candy. The pair, named TOI-791 b and TOI-791 c, orbit an F7-type star about 1,110 light-years from Earth in the southern constellation Volans. Their numbers are almost hard to believe: TOI-791 b has an average density of just 0.038 g/cm³, while TOI-791 c comes in at 0.047 g/cm³. For comparison, Jupiter’s average density is about 1.33 g/cm³. Cotton candy is roughly 0.05 g/cm³. Earth is around 5.5 g/cm³. That makes these planets not just “fluffy” by astronomical standards — they are among the lowest-density giant planets ever detected. The discovery, published in Monthly Notices of the Royal Astronomical Society, is especially valuable because the two planets appear to be locked in a rare 5:3 orbital resonance: for every five orbits of the inner planet, the outer one completes almost exactly three. This gravitational interaction slightly shifts the timing of their transits across the star, allowing astronomers to estimate their masses. 🔹 The planets were first spotted by volunteers in the Planet Hunters TESS citizen-science project 🔹 Confirmation required eight years of observations 🔹 Data from the ASTEP telescope at Antarctica’s Concordia Station were crucial 🔹 Each transit lasts more than 11 hours — unusually long for ground-based observations 🔹 Only a handful of systems are known to contain multiple super-puff planets The leading idea is that these worlds may have relatively small cores surrounded by enormous hydrogen- and helium-rich atmospheres. But exactly how such diffuse planets form — and how they keep their atmospheres for so long — remains an open question. Important caveat: these measurements come from transits and orbital timing effects, not from direct imaging. The densities are robust within the current model, but the planets’ true atmospheric composition will require follow-up observations — potentially with the James Webb Space Telescope. Super-puff planets are strange because they sit at the edge of what our planet-formation models can comfortably explain. If a giant planet can be less dense than cotton candy and still hold itself together, what else is out there that our theories have not yet learned to expect? 📄 Source: https://academic.oup.com/mnras/article-lookup/doi/10.1093/mnras/stag864 #exoplanets #astronomy #space #TESS #superpuffs
348
4
🪐 A Wobbling “Peanut” Asteroid May Still Carry Traces of Ancient Water NASA’s Lucy mission has revealed one of the strangest small worlds ever seen up close: asteroid Donaldjohanson — a young, peanut-shaped rock in the main asteroid belt that tumbles through space and still preserves chemical hints of liquid water from its distant past. Lucy flew past Donaldjohanson on April 20, 2025, at about 30,000 mph, coming within just 650 miles of the asteroid. The encounter was meant partly as a rehearsal before Lucy reaches Jupiter’s Trojan asteroids in 2027. Instead, it became a science story of its own. Donaldjohanson does not rotate like a simple spinning rock. Data from Lucy show that it tumbles end-over-end once every 10.5 Earth days, while also wobbling around its long axis every 26.5 days — more like an unstable top than a normal asteroid. Its shape is just as unusual. Donaldjohanson is a contact binary: two lobes joined by a narrow neck, giving it a cosmic peanut-like form. Scientists think it formed about 155 million years ago, when fragments from a violent collision gently came back together under their own gravity. Since then, sunlight has been slowly reshaping it. Through the YORP effect — a tiny torque caused when sun-warmed surfaces radiate heat back into space — Donaldjohanson’s spin appears to have slowed by at least a factor of 10 over the last 20–60 million years. As the rotation changed, loose material likely slid down its slopes, softening craters and reshaping the surface. But the most intriguing clue came from Lucy’s infrared data: iron-rich clay minerals on the surface. These minerals form in the presence of liquid water, meaning Donaldjohanson’s parent body once experienced aqueous alteration. But unlike Bennu and Ryugu, which contain magnesium-rich clays suggesting longer exposure to water, Donaldjohanson’s chemistry points to a much shorter episode. 🔹 Donaldjohanson is a bilobed “contact binary” asteroid 🔹 It tumbles on two axes, with rotation periods of 10.5 and 26.5 days 🔹 Its current body likely formed around 155 million years ago 🔹 Sunlight gradually slowed its spin through the YORP effect 🔹 Iron-rich clays suggest liquid water was present — but only briefly 🔹 The flyby was also a successful rehearsal for Lucy’s Trojan asteroid encounters, beginning with Eurybates in August 2027 Important caveat: this was a fast flyby, not an orbital mission or a sample return. Lucy measured the surface remotely; the asteroid’s interior remains unknown. Still, Donaldjohanson matters because it gives scientists a rare comparison point. Bennu and Ryugu are near-Earth asteroids with long migration histories. Donaldjohanson is a much younger main-belt object that stayed closer to its birthplace. Its strange shape, unstable spin, and brief water history offer a fresh clue to how small bodies evolved — and how water-rich material may have moved through the early Solar System. 📄 Sources: https://www.science.org/doi/10.1126/science.aec0503 #NASA #LucyMission #Asteroid #PlanetaryScience #SolarSystem
364
5
🐝 What If Queen Bees Aren’t Made by Royal Jelly Alone? For decades, the textbook story sounded simple: feed an ordinary honeybee larva royal jelly, and it becomes a queen. A new study in Nature suggests the real story is far more sophisticated. Researchers found that future queens are not just fed differently — they are raised inside specially engineered “royal cribs”: peanut-shaped queen cells built from unusual wax, kept warmer and more humid, and maintained by dedicated young worker bees. These queen cells are not passive containers. Their wax is physically and chemically distinct from ordinary worker-cell wax: softer, less dense, more flexible, and better at holding heat and moisture. In other words, the nursery itself helps shape development. The key experiment was simple but powerful. Scientists raised queen-destined larvae with the same royal jelly, but changed the wax environment. Larvae exposed to ordinary worker-cell wax were more likely to die and developed into smaller, weaker queens. So royal jelly matters — but it is not the whole mechanism. 🔹 Queen development depends on diet + architecture + microclimate 🔹 Queen-cell wax is chemically and physically different from ordinary comb wax 🔹 Young “queen cell builders” appear specially adapted to construct and maintain these royal nurseries 🔹 Extra warmth may help queens mature faster: about 16 days vs about 21 days for workers 🔹 Similar patterns were found in western and eastern honeybees, suggesting deep evolutionary roots Important caveat: this study focused on honeybees, not all social insects. And scientists still need to identify exactly which physical or chemical features of the wax are doing the biological work. Still, the implication is fascinating: development is not shaped by genes and nutrition alone. Built environments — even tiny wax chambers — can influence what an organism becomes. If a wax cradle can help decide the fate of a future queen, what other biological outcomes are being shaped by structures we barely notice? 📄 Source: https://www.nature.com/articles/s41586-026-10534-3 #Science #Biology #Bees #Nature #Entomology
349
6
🪐 A Rare Meteorite May Preserve Evidence of a Lost World from the Dawn of the Solar System Scientists at the University of Colorado Boulder have uncovered what may be the strongest evidence yet for a vanished protoplanet — a planetary embryo that once orbited the young Sun more than 4.5 billion years ago before being destroyed in a catastrophic collision. The clue comes from an unusual meteorite known as Northwest Africa (NWA) 12774, discovered in the Sahara Desert. It belongs to the angrites, one of the rarest meteorite groups ever found. Out of more than 80,000 known meteorites, only a few dozen are classified as angrites. These rocks formed during the earliest stages of solar system history, just a few million years after the Sun was born. What makes NWA 12774 remarkable is its mineral chemistry. Researchers found clinopyroxene crystals enriched in aluminum — a signature that indicates formation under enormous pressure. Their calculations suggest pressures exceeding 17.5 kilobars, more than 17 times greater than the pressure at the bottom of the Mariana Trench. Such conditions could not have existed inside a small asteroid. The results imply that the meteorite’s parent body had a radius of at least 1,000 km. Because the crystals preserve delicate structures that would likely not survive deep burial, the original world may have been much larger — potentially approaching the size of the Moon and perhaps even Mars. 🔹 Evidence points to a planetary embryo at least 1,000 km in radius 🔹 Formation pressures exceeded 17.5 kilobars 🔹 Its composition differs significantly from Earth and Mars 🔹 It may represent a previously unknown pathway of planetary evolution 🔹 Fragments of similar lost worlds could still be hiding in meteorite collections The study suggests that the early solar system was far more diverse than previously thought. Many planetary embryos likely formed, collided, merged, or were destroyed before the planets we know today emerged. How many lost worlds helped build the solar system we live in? 📄 Original paper (Earth and Planetary Science Letters) · ScienceDaily #astronomy #space #meteorite #planetaryscience #solarsystem
447
7
🤖 NVIDIA Cosmos 3: AI Is Leaving the Screen and Entering the Physical World NVIDIA has unveiled Cosmos 3, the world’s first fully open “omnimodel” for Physical AI — a new generation of AI designed not only to understand information, but also to perceive, predict, simulate, and act in the real world. Unlike traditional AI systems that specialize in a single modality, Cosmos 3 combines visual reasoning, world simulation, and action generation within a unified architecture. The goal is straightforward: build AI that can operate in physical environments rather than merely talk about them. Potential applications include robotics, autonomous vehicles, manufacturing, industrial automation, and medical simulation. By releasing the model openly, NVIDIA hopes to accelerate development across the entire Physical AI ecosystem. Nikolas Bush Take The significance of Cosmos 3 is not the model itself — it’s what it represents. For the past few years, the AI race has focused on making language models larger and more capable. NVIDIA is betting that the next battleground will be Physical AI: systems that can see, understand, predict, and act in the real world. If this shift succeeds, the winners of the next decade may not be the companies with the smartest chatbots, but those building the best robots, autonomous machines, industrial agents, and digital-physical ecosystems. The most important question is no longer: “Can AI think?” It’s becoming: “Can AI reliably interact with reality?” That is a far more difficult challenge — and a far larger market. 📎 AIapps June 2026 roundup · SingularityMoments Top 10 #AI #NVIDIA #PhysicalAI #Robotics #EmbodiedAI #ArtificialIntelligence #science
433
8
🌌 Einstein’s “Biggest Blunder” May Have a New Explanation — Hidden in the Shape of Space-Time One of the deepest problems in modern physics is the cosmological constant — the tiny number linked to the accelerating expansion of the universe. The mystery is brutal: quantum theory suggests empty space should contain an enormous amount of vacuum energy. If that were true, the universe should have expanded so violently that galaxies, stars, and life could never form. But in reality, the cosmological constant is incredibly small. Now, physicists at Brown University propose a possible explanation: the value may be protected by the topology of space-time itself. Their idea connects quantum gravity with the quantum Hall effect — a Nobel Prize-winning phenomenon where electrical conductance becomes locked into precise, stable values because of topology: the underlying “shape” of the system. The researchers argue that space-time may work in a similar way. In their model, the cosmological constant becomes tied to a topological parameter, meaning quantum fluctuations that should make it explode are effectively neutralized. In simple terms: the universe’s expansion may not be delicately fine-tuned by chance — it may be stabilized by the mathematical structure of space-time. Important caveat: this is still a theoretical proposal, not an experimental discovery. Whether space-time really has this kind of topological protection remains an open question. But if the idea is right, it could offer a rare bridge between quantum gravity and experimentally tested condensed-matter physics — and may explain why our universe is stable enough to contain galaxies, stars, and us. Could the reason we exist be written into the geometry of the universe itself? Source: Brown University / Physical Review Letters https://www.brown.edu/news/2026-04-20/cosmological-constant-problem #Physics #Cosmology #QuantumGravity #DarkEnergy #Einstein
432
9
🧠 What If Alzheimer’s Starts Inside Brain Cells — Before the Plaques Take Over? For decades, Alzheimer’s disease has been strongly associated with amyloid beta plaques — sticky protein deposits that build up between neurons. This idea shaped an entire generation of drug development. But clearing plaques has not been enough to stop or reverse the disease, which suggests the real story may begin earlier and deeper inside the cell. A new study from the University of California, Riverside, published in PNAS Nexus, proposes a different mechanism: amyloid beta may disrupt neurons by hijacking the same internal “tracks” normally used by tau, another key brain protein. Inside neurons, microtubules act like tiny railways, helping move vital cargo through long and fragile nerve-cell branches. Tau normally stabilizes these tracks. But the researchers found that amyloid beta can bind to microtubules with roughly similar strength — meaning that, if it accumulates inside neurons, it may compete with tau and push it away from its normal job. That could trigger a dangerous cascade: microtubules become unstable, cellular transport starts to fail, and displaced tau begins to misbehave — clumping, becoming chemically modified, and moving into parts of the neuron where it does not belong. In this model, plaques outside cells may not be the original weapon. They may be a visible downstream sign of a much earlier intracellular failure. Why this matters: 🔹 Amyloid beta and tau appear to compete for overlapping binding sites on microtubules 🔹 The damage may begin inside neurons, before external plaques dominate the picture 🔹 Aging-related decline in autophagy — the cell’s recycling system — could allow amyloid beta to build up internally 🔹 The model may help explain why plaque-clearing drugs have shown limited clinical impact 🔹 It points toward new strategies: protecting microtubules, supporting tau function, or improving intracellular protein cleanup Important caveat: this is not a clinical trial and not proof that this mechanism causes Alzheimer’s in humans. It is a proposed model based on laboratory experiments — but an interesting one, because it connects two major Alzheimer’s hallmarks, amyloid beta and tau, through the same cellular structure. More than 57 million people worldwide live with dementia, and Alzheimer’s disease accounts for the majority of cases. If this microtubule-competition model holds up, it could shift part of the field from simply removing plaques to protecting the neuron’s internal transport system before it breaks. Maybe the real crime scene was never just between brain cells. Maybe it was inside them all along. Source: https://doi.org/10.1093/pnasnexus/pgag034 #Alzheimers #Neuroscience #BrainHealth #Dementia #PNASNexus #science
434
10
🧬 Scientists May Have Reactivated a Dormant Regeneration Program in Mammals For a long time, scientists believed that mammals simply lost the ability to regenerate complex body parts during evolution. Salamanders can regrow entire limbs. Mammals usually heal injuries with scar tissue. But researchers at Texas A&M University have now demonstrated that this regenerative potential may still exist — just in a dormant state. In a new study published in Nature Communications, the team led by Dr. Ken Muneoka used a two-step treatment that redirected healing away from scar formation and toward actual tissue regeneration. In animal models, amputated digits regrew key structures including bone, tendons, ligaments, and joint tissues — components that mammals normally cannot rebuild once lost. The approach relies on two growth factors applied in sequence: • FGF2 (fibroblast growth factor 2) first stimulates the formation of a blastema — a specialized cluster of regenerative cells normally seen in animals such as salamanders. • Several days later, BMP2 (bone morphogenetic protein 2) provides instructions that guide those cells to rebuild specific tissues. Key findings: 🔹 Regeneration occurred without transplanting stem cells — the body’s own cells were reprogrammed locally 🔹 Bone, tendon, ligament, and joint structures regenerated after amputation 🔹 Cells could be instructed to form tissues in locations where they would not normally develop 🔹 BMP2 is already FDA-approved for certain medical applications, while FGF2 has undergone extensive clinical investigation 🔹 The regenerated structures were not perfect replicas, but major functional components were restored Important caveat: these results come from animal studies, not human clinical trials. Whether the same strategy can trigger comparable regeneration in humans remains unknown. Still, the work suggests that mammalian regeneration may not have disappeared during evolution. Instead, the underlying biological program may still be present — but normally remains switched off. If that turns out to be true, future regenerative therapies may focus less on adding new cells and more on activating capabilities our bodies already possess. 📄 Original paper (Nature Communications) · ScienceDaily #RegenerativeMedicine #Biotech #TissueEngineering #NatureCommunications #FutureOfMedicine #science
395
11
🧠 A Copper-Based Compound May Help the Brain Clear Alzheimer’s Proteins — by Repairing Its “Waste Pumps” Most Alzheimer’s drug research has focused on attacking amyloid plaques directly. A new study from Monash University suggests a different route: what if the brain’s waste-clearance system could be repaired instead? The compound is called Cu(ATSM) — a copper-delivering molecule already studied in human safety trials for Parkinson’s disease and ALS. In a mouse model of Alzheimer’s, researchers found that Cu(ATSM) restored levels of P-glycoprotein, or P-gp — a transporter at the blood-brain barrier that helps move amyloid-beta out of the brain. Think of P-gp as part of the brain’s drainage system. When these pumps weaken, toxic proteins can accumulate. When the researchers boosted them with Cu(ATSM), the results were striking: • 42% reduction in toxic amyloid-beta over 56 days • nearly 44% improvement in spatial learning • 24.1% increase in P-gp clearance pumps at the blood-brain barrier • evidence that repairing the blood-brain barrier may help lower amyloid burden and improve cognition The important caveat: this was not a human Alzheimer’s trial. The results come from APP/PS1 mice — a widely used model of the disease — so the next question is whether the same mechanism works in people. Still, the idea is powerful. Instead of only trying to destroy plaques after they form, future therapies might also help the brain restore its own clearance infrastructure. If Alzheimer’s is partly a “drainage failure,” could repairing the brain’s plumbing become one of the next big strategies in neurodegeneration? 📄 Source: https://doi.org/10.1021/acschemneuro.6c00252 #Alzheimers #Neuroscience #DrugDiscovery #BloodBrainBarrier #CopperTherapy #science
387
12
🐱 Oxford Physicists Just Made Schrödinger’s Cat Even Weirder Schrödinger’s cat was never really about a cat. It was a way to show how strange quantum mechanics becomes when one object is treated as being in two states at once. Now physicists at the University of Oxford have created a new family of “cat-like” quantum states — but with an extra twist: the two parts of the superposition are not ordinary, classical-looking wave packets. They are already deeply quantum objects. In standard lab versions of Schrödinger-cat states, researchers usually combine coherent states — the closest thing quantum physics has to classical motion. The Oxford team went further. Using a single trapped strontium-88 ion, they built superpositions from squeezed, trisqueezed and quadsqueezed motional states: exotic states where quantum uncertainty is reshaped in unusual ways. The setup is elegant. The ion’s internal electronic state acts like a qubit, while its motion behaves like a quantum harmonic oscillator — a system that can occupy many energy levels. By entangling these two parts and then performing a mid-circuit measurement, the team could “sculpt” the ion’s motion into highly programmable quantum superpositions. Why is this interesting? • The states are built from nonclassical components, not just classical-like wave packets • Their size, orientation and separation can be tuned experimentally • Wigner-function measurements showed interference and negativity — signatures of genuinely quantum behavior • Some states displayed striking geometric patterns, including sixfold symmetry in a trisqueezed example • At the same average energy, these states can be more “quantum-resourceful” than standard cat states or Fock states This matters because future quantum computers may not rely only on simple qubits. Quantum oscillators can store information across many energy levels, opening a richer route toward bosonic quantum error correction — where information is encoded in oscillator states rather than many separate physical qubits. It is still early-stage physics, not a ready-made quantum computer. But it gives researchers a new way to build, control and study quantum states that sit far beyond everyday intuition. And it brings us back to the original question Schrödinger wanted to provoke: Where does the quantum world end — and the classical world begin? Source: https://doi.org/10.1103/k1xk-yt42 #QuantumPhysics #SchrodingersCat #QuantumComputing #Physics #Oxfordx #science
405
13
⚡ Google TurboQuant Cracks the AI Memory Wall — And It's Not About Bigger Models At ICLR 2026, Google Research introduced TurboQuant, a new two-stage compression method that can reduce transformer KV cache memory usage by 40–60% without retraining and with minimal impact on model quality. The KV cache — which stores information about every token processed during a conversation or document — has become one of the biggest bottlenecks in modern LLM inference. As context windows expanded from thousands to millions of tokens, KV caches often began consuming more GPU memory than the model weights themselves. TurboQuant tackles this problem directly. The first stage, called PolarQuant, rotates cached vectors into a representation that is more friendly to quantization. The second stage uses a quantized Johnson–Lindenstrauss projection to compress the remaining error signal into just one bit per dimension. Together, these techniques reduce KV cache storage requirements to roughly 3–4 bits per element. The implications are significant. Lower memory consumption means more concurrent users per GPU, larger context windows, and lower inference costs without changing the underlying model. In a world where AI infrastructure spending is growing at an unprecedented pace, improvements in efficiency can be just as valuable as improvements in model capability. Nikolas Bush Take 1. The industry is entering an efficiency era. For the last several years, the default answer to better AI has been bigger models, larger datasets, and more compute. TurboQuant is part of a growing trend suggesting that algorithmic efficiency may deliver some of the largest gains going forward. A 50% reduction in memory requirements achieved through mathematics rather than billion-dollar infrastructure investments changes the economics of AI deployment. 2. Infrastructure is becoming the real battleground. Model quality is increasingly converging among frontier AI labs. The next competitive advantage may come from serving those models faster, cheaper, and at larger scale. Techniques such as TurboQuant directly target one of the most expensive components of large-scale inference: memory. In that sense, this is not merely a research paper — it's an infrastructure play. 3. The most important signal is reproducibility. Breakthroughs matter only if the broader ecosystem can adopt them. If TurboQuant proves effective across different model architectures and hardware environments, it could evolve into a standard optimization layer for inference stacks, much like FlashAttention became a standard component of modern training and inference pipelines. Caveats The reported 40–60% memory reduction comes from benchmarked experiments and may vary depending on model architecture, context length, and hardware configuration. Some social media claims of extreme compression ratios refer to edge-case theoretical scenarios rather than typical production deployments. And importantly, TurboQuant addresses inference efficiency — not the still-unsolved challenge of reducing training costs. What Comes Next? If efficiency-focused innovations continue delivering meaningful gains, 2026 may be remembered as the year the AI industry began shifting its attention from model size to resource efficiency. The next major breakthroughs may come not from adding more parameters, but from using existing compute far more intelligently. 📎 Google Research blog · Lanceum analysis · Weekly AI roundup #TurboQuant #ICLR2026 #AIInfrastructure #LLMInference #EfficiencyOverScale #science
463
14
🚨 The U.S. Government Just Forced Anthropic to Switch Off Fable 5 and Mythos 5 This may be the first real “game over” moment for the old AI deployment model. On June 11, 2026, Anthropic received a U.S. government export-control directive citing national security authorities. The order required the company to suspend access to Claude Fable 5 and Claude Mythos 5 for any foreign national — not only outside the United States, but also inside the country. That includes foreign-national employees of Anthropic itself. To comply, Anthropic says it had to disable Fable 5 and Mythos 5 for all customers globally. Other Claude models remain available. For now. The reason appears to be a claimed jailbreak method for Fable 5. Anthropic reviewed the demonstration and argues that the method only identifies a small number of previously known, simple vulnerabilities — the kind of tasks already possible with other public frontier models. According to the company, it did not receive a single example of a jailbreak producing a genuinely harmful result. And this is where the conflict becomes much bigger than Anthropic. The real issue is the standard of proof. If asking a model to read a codebase and identify bugs is enough to trigger a national-security shutdown, then almost every next-generation frontier model becomes politically vulnerable by default. Future models will not get weaker. They will get stronger. So the regulatory question is no longer theoretical. Who gets access? Who counts as trusted? And which jurisdiction gets to decide? This is a tectonic shift in AI regulation. Until now, governments mostly relied on voluntary commitments, safety frameworks, evaluations and post-release pressure. Now we have something much more direct: a forced shutdown of a commercial frontier model after deployment. If this precedent holds, any advanced AI release can be stopped by a government letter. And the location of frontier AI development may become less about talent, compute or product — and more about citizenship, export law and political risk. There is also a very awkward human side to this. If access to leading AI systems starts being restricted by nationality or “U.S. person” status, the blast radius could reach some of the most important people in AI: • Andrej Karpathy — recently joined Anthropic; publicly described as Slovak-Canadian • Demis Hassabis — British co-founder and CEO of Google DeepMind • Geoffrey Hinton — British-Canadian pioneer of deep learning • Yoshua Bengio — Canadian AI researcher and safety advocate • Ilya Sutskever — publicly described as Israeli-Canadian; co-founder of Safe Superintelligence • Mustafa Suleyman — British CEO of Microsoft AI • Aidan Gomez — British-Canadian co-founder and CEO of Cohere The point is not that all of them are immediately blocked from anything. The point is that a citizenship-based access regime for frontier AI would create absurd edge cases almost instantly. The U.S. could end up restricting the very people who built the field. So no, this probably does not mean AI progress is over. But it may mean the era of “just ship the model globally” is over. Order a truckload of popcorn. China is definitely watching. #Anthropic #Fable5 #Mythos5 #AIRegulation #ExportControl #FrontierAI #AISafety #science
521
15
🧪 Could Tiny Mineral Particles Have Helped Spark Life on Earth? One of science's biggest unanswered questions is how life emerged from nonliving matter. A new hypothesis suggests that the answer may lie in something surprisingly small: mineral nanoparticles. Prof. Yongdong Jin of Shenzhen University has proposed the "Nanozyme Hypothesis" — the idea that naturally occurring mineral nanoparticles may have acted as primitive catalysts on the early Earth, helping transform simple chemicals into increasingly complex organic molecules. Billions of years ago, our planet was a vast chemical laboratory. Around volcanoes, hydrothermal vents, and hot springs, intense heat and pressure produced nanoparticles made of metals, metal oxides, and sulfides. According to the hypothesis, these particles behaved like enzyme-like catalysts, accelerating reactions that otherwise would have occurred far too slowly. Jin describes this process as a form of "inorganic photosynthesis" — chemistry powered by minerals long before biological cells existed. What makes the idea particularly interesting is that it may help bridge several competing origin-of-life models. Rather than choosing between an RNA world, metabolism-first, or lipid-first scenario, nanozymes could have provided the chemical platform that enabled all of them to emerge. The proposed functions of nanozymes include: • Catalyzing key chemical reactions • Concentrating molecules on their surfaces • Protecting fragile compounds from UV radiation • Using light to promote specific reactions • Converting environmental energy into chemically useful forms Remarkably, mineral nanoparticles are still abundant on Earth today, and many are known to exhibit enzyme-like behavior. The paper also highlights gold nanoparticles as particularly efficient catalysts under certain prebiotic conditions. If future experiments support this hypothesis, it could reshape the search for life beyond Earth. Worlds with volcanic activity, liquid water, and the right mineral chemistry might possess the same ingredients that once helped kick-start biology here. Was life an extraordinarily rare accident — or a natural consequence of chemistry under the right conditions? 📄 Original paper (Research, Dec 2025) · ScienceDaily summary #OriginOfLife #Nanozymes #Abiogenesis #Astrobiology #EarthScience #science
547
16
🗂 The @science archive now lives on the web Every post from this channel — searchable, filtered, and mapped on an interactive timeline. One page, no apps, no logins. Thanks to AI and just 1 prompt.. crazy! 🔹 356 posts and counting — the full archive since 2024, auto-synced with the channel several times a day 🔹 Five frontiers: AI, Space, Biotech, Physics and FutureTech — filter by category or search any keyword across titles and summaries 🔹 An interactive timeline of scientific breakthroughs from 2012 to 2025 — from AlexNet to room-temperature superconductor claims, hover any dot for the story 🔹 Every card links straight back to the original post here on Telegram 🔹 Built lightweight: a single page that loads in under a second, works on any phone The archive grows automatically as new posts appear on the channel. 🔗 http://144.172.108.222/science/
527
17
✨ Pterosaurs Shimmered in Iridescent Greens and Magentas — 120-Million-Year-Old Fossil Rewrites the Look of Earth's First Flying Vertebrates For decades, paleoartists have imagined pterosaurs in vivid, colorful hues. Now, a stunning new fossil analysis suggests that at least one species really did shimmer with shifting iridescent colors, much like modern starlings and pigeons. The discovery comes from a specimen of Sinopterus dongi, unearthed in northeastern China. Scanning electron microscopy revealed layered arrays of melanosomes within the creature's pycnofibers — structures that closely resemble those producing iridescence in modern bird feathers. Computer simulations predict deep greens and magentas that shifted with viewing angle. The diversity and organization of melanosomes matches patterns seen only in warm-blooded birds and mammals, suggesting elevated metabolisms and sophisticated thermoregulation — traits long debated among paleontologists. The finding also hints that iridescent displays may have played a role in courtship rituals. "This is one of the most intriguing and surprising fossil discoveries of the past few years." — Dr. Steve Brusatte, University of Edinburgh 📄 Original paper (bioRxiv) · Science News summary #paleontology #pterosaurs #fossil #evolution #iridescence #science
533
18
🤖 A 100-billion-parameter AI model was just trained across random GPUs scattered around the globe — not in a billion-dollar datacenter. And it worked. Macrocosmos, building on the Bittensor network, has demonstrated Orion-100B: a 100B-parameter language model trained across geographically distributed Nvidia A100 GPUs. Their system, called IOTA, splits the model itself across many machines using 16 pipeline-parallel stages — unlike earlier decentralized approaches that often required each participant to host the full model. The result: more than 30% model FLOP utilization and roughly 65% of the efficiency of a comparable datacenter setup. The technical challenge was serious. Macrocosmos had to reduce massive inter-GPU traffic, handle unstable nodes, work with heterogeneous hardware, and keep the training process alive across a decentralized network. Their ResBM activation compression technique reportedly reduced traffic from around 150MB to 2.2MB per stage. The team says it ran more than 700 experiments before scaling from a 1.5B test model to 100B in about a month. Nikolas Bush’s Take: This story matters far beyond the technical achievement. First, if this approach scales, it could change the economics of AI training. A 100B-parameter model trained on geographically distributed A100 GPUs at roughly 65% of comparable datacenter efficiency is not yet a replacement for hyperscaler infrastructure — but it is a serious signal. It suggests that large-scale AI training may not always require a single billion-dollar GPU cluster. Second, the Bittensor layer is important. This is not just a distributed computing experiment; it is an incentive system. GPU owners can be rewarded for contributing compute, which creates the foundation for a market around idle hardware. In simple terms, this could become something like “Airbnb for AI training”: monetizing unused GPU capacity the way Airbnb monetized unused rooms. Third, the uncomfortable part: decentralized AI training has often been dismissed by the mainstream AI community as impractical. Orion-100B does not prove that decentralized training will beat datacenters tomorrow. But it does prove that the idea deserves to be taken much more seriously. The next phase — permissionless participation from consumer hardware — will be the real test. If that works, the AI infrastructure map could become much more distributed than many people expected. Original report: https://macrocosmosai.substack.com/p/orion-100b-distributed-pretraining Summary: https://www.tao.media/macrocosmos-unveils-orion-100b-a-100b-parameter-distributed-ai-training-run/ #AI #DecentralizedAI #Bittensor #LLM #DeepLearning @science
573
19
🧬 "Undruggable" No More: New Pill Nearly Doubles Survival in Advanced Pancreatic Cancer For decades, pancreatic cancer has been one of medicine's most hopeless diagnoses. More than 90% of cases are driven by mutations in a gene called KRAS — a protein scientists long labeled "undruggable" because its surface is so unnaturally smooth that no drug could latch onto it. That era just ended. A new oral drug called daraxonrasib takes a brilliantly indirect approach: instead of trying to bind KRAS directly, it grabs onto a helper molecule called cyclophilin A inside the cell. That drug-protein complex then clamps onto active KRAS and physically shuts it down, silencing the "grow forever" signal at its source. The approach is so novel that it targets multiple mutant forms of RAS at once, making resistance much harder for the cancer to develop. In a Phase 3 trial of 500 patients with metastatic pancreatic cancer who had already been through prior treatment, the results were striking. Patients on daraxonrasib lived a median of 13.2 months compared to just 6.7 months on standard chemotherapy — nearly double. The drug reduced the overall risk of death by 60%. Results were presented by Revolution Medicines and published in the New England Journal of Medicine. Side effects are real — a prominent skin rash affected 86% of patients, along with mouth sores, diarrhea, and nausea — but patients on daraxonrasib were far less likely to abandon treatment than those on chemo, and reported better quality of life with less pain. — Median overall survival: 13.2 months (daraxonrasib) vs 6.7 months (chemotherapy) — 60% reduction in risk of death — Once-daily pill — no infusions, no hospital visits — Works against multiple RAS mutations simultaneously, limiting resistance — Lower treatment discontinuation rate and improved quality of life vs chemo "For decades, successfully targeting the central mechanism that causes the vast majority of pancreatic cancers was considered impossible. That narrative is rapidly changing." — Dr. Christopher Lieu, Professor of Medical Oncology, University of Colorado Why it matters: Pancreatic cancer kills 97% of patients with metastatic disease within five years. Chemotherapy has been our only real tool — a blunt instrument with brutal side effects. Daraxonrasib is the first therapy to go after the genetic engine of the disease itself. If approved, it would be the most significant advance in pancreatic cancer treatment in a generation, and the platform — hijacking cyclophilin A to reach "undruggable" targets — could open doors for dozens of other cancers driven by RAS mutations. 📄 NEJM: https://www.nejm.org/doi/full/10.1056/NEJMoa2605555 📖 ScienceDaily: https://www.sciencedaily.com/releases/2026/06/260604044247.htm 📖 The Conversation: https://theconversation.com/breakthrough-drug-nearly-doubles-survival-with-advanced-pancreatic-cancer-an-oncologist-explains-how-daraxonrasib-overcame-an-undruggable-disease-283647 #PancreaticCancer #KRAS #CancerResearch #MedicalBreakthrough #science
608
20
🧬 Cancer Cells' Favorite Escape Trick Backfires — And Scientists Just Discovered How to Exploit It For decades, immunologists have operated under a simple assumption: cancer cells evade the immune system by shutting down a protein called MHC class I, which acts as a "wanted poster" for killer T cells. Without this signal, CD8+ killer T cells become blind to the tumor, allowing it to grow unchecked. But a groundbreaking study published in Nature Immunology has now flipped that assumption on its head. Researchers at Baylor College of Medicine and the University of Michigan discovered that when cancer cells silence MHC I to hide from killer T cells, they inadvertently expose themselves to a completely different immune attack. Instead of becoming invisible, the tumor cells become hyper-visible to CD4+ "helper" T cells — immune cells long thought to play only a supporting role. These helper T cells then trigger ferroptosis, a violent form of cell death driven by iron-catalyzed oxidative stress that essentially rusts the cancer cell from the inside out. The team, led by Dr. Pavan Reddy at the Dan L Duncan Comprehensive Cancer Center, validated this mechanism across mouse models, human tumor samples, and large clinical datasets from patients who had received checkpoint inhibitor therapies. The results held not only for cancer but also for graft-versus-host disease — a dangerous complication of bone marrow transplants — suggesting the finding rewires our fundamental understanding of T cell biology. — Cancer cells reduce MHC I to hide from CD8+ killer T cells — This loss makes them unexpectedly vulnerable to CD4+ helper T cells — CD4+ cells kill via ferroptosis — iron-driven oxidative destruction — The same mechanism operates in transplant complications — Clinical patient data confirms relevance to real-world outcomes "Our work, if further validated, will have implications for T cell-mediated immune responses beyond cancer and transplant immunology," said Reddy. "This may allow for the development of novel strategies that target MHC class I and CD4+ T cells." Why it matters: Many aggressive tumors become resistant to immunotherapy precisely because they drop MHC I expression. Until now, this was seen as a dead end. The new discovery suggests these "escaped" tumors may actually be the most vulnerable — if we can learn to weaponize CD4+ T cells against them. It opens a new front in cancer immunotherapy, especially for patients who have stopped responding to existing treatments. 📄 Original paper (Nature Immunology): https://doi.org/10.1038/s41590-026-02480-z 📖 Readable summary (ScienceDaily): https://www.sciencedaily.com/releases/2026/06/260603023911.htm #Immunology #CancerResearch #Immunotherapy #Science #Breakthrough
521