The researchers discovered the multiple superconducting states in atomically thin exfoliations of graphite, known as graphene. Specifically, graphene is a single-atom-thin sheet of carbon atoms arranged precisely in a microscopic lattice. The team made its discoveries in samples of rhombohedral graphene, which is a natural structure within graphite consisting of a stack of four or five graphene layers.
Interestingly, the researchers found that several of the new superconducting states in rhombohedral graphene are able to persist in the presence of a magnetic field, which normally kills superconductivity.
And in a further surprise, these superconducting states even get stronger when exposed to a magnetic field.
A new study has revealed an unexpected link between solar storms and the flux of high-energy cosmic rays arriving at Earth. The findings, made using one of the world’s largest cosmic ray detectors, could open up a new way to probe the magnetic structures inside solar storms—and potentially improve our ability to forecast their effects on Earth. The research has been published in Physical Review Letters.
Earth’s magnetic field is constantly being bombarded by energetic charged particles, originating from two very different sources. While some of these particles are cosmic rays, which come toward Earth from all directions across the galaxy, the rest originate from solar storms: violent outbursts from the sun that hurl vast clouds of magnetized plasma into space.
So far, the effects of these two phenomena have often been treated as independent. Although scientists have long known that solar storms can reduce the number of lower-energy cosmic rays reaching Earth by trapping them in the storm’s twisted magnetic fields, higher-energy cosmic rays were thought to be too energetic to be affected. At these energies, the particles were expected to punch straight through the magnetic structures without being deflected.
Researchers have shown that an unusual class of quantum states known as “fractional Fermi seas” can be deliberately created, according to a new study published in Physical Review Letters. The work was carried out by the Nägerl group together with theoretical physicist Alvise Bastianello of CNRS and Université Paris-Dauphine.
The study demonstrates how a new critical phase of matter can emerge when quantum particles are pushed far from their normal equilibrium conditions. Using ultracold cesium atoms confined to one dimension, the researchers repeatedly altered how strongly the particles interacted with one another. The resulting state goes beyond the behavior predicted by the well-known Tomonaga-Luttinger liquid theory, a cornerstone for understanding one-dimensional quantum systems.
This publication provides the theoretical framework for recent experimental research conducted in the group of Hans-Christoph Nägerl at the Department of Experimental Physics.
From cosmic rays to solar storms, space travel is a radiation gauntlet… but water may be the simplest, smartest solution. Discover how future starships might turn their life-support systems into life-saving armor.
Get Nebula using my link for 50% off an annual subscription: https://go.nebula.tv/isaacarthur. Watch my exclusive video Nearby Supernovae: https://nebula.tv/videos/isaacarthur–… out Gods & Monsters: https://nebula.tv/curiousarchive/gods… 🛒 SFIA Merchandise: https://isaac-arthur-shop.fourthwall… 🌐 Visit our Website: http://www.isaacarthur.net ❤️ Support us on Patreon: / isaacarthur ⭐ Support us on Subscribestar: https://www.subscribestar.com/isaac-a… 👥 Facebook Group: / 1,583,992,725,237,264 📣 Reddit Community: / isaacarthur 🐦 Follow on Twitter / X: / isaac_a_arthur 💬 SFIA Discord Server: / discord Credits: Fishbowl Starships Water As Shielding Episode 721; June 1, 2025; Nebula Exclusive Written, Produced, & Narrated by: Isaac Arthur Graphics: Bryan Versteeg, Jeremy Jozwik, Udo Schroeter Select imagery/video supplied by Getty Images Music Courtesy of Epidemic Sound http://epidemicsound.com/creator Taras Harkavyi, “Alpha and…” Chris Zabriskie, “Unfoldment, Revealment”, “A New Day in a New Sector” “Oxygen Garden”, “Wonder Cycle” Stellardrone, “Red Giant”, “Billions and Billions” Chapters: 0:00 Intro 1:45 The Threat — Radiation In Space 2:36 Galactic Cosmic Rays (GCRs) 3:44 Solar Particle Events (SPEs) 4:16 Van Allen Belt Radiation 5:19 Radiation’s Impact on Humans and Equipment 8:18 Radiation Shielding Basics 9:18 Water as a Radiation Shield 11:19 Effectiveness of Water 15:42 Difficulties Using Water 17:29 Beyond Water: Alternative Radiation Shielding Methods 17:59 Metallic Shielding 18:58 Regolith & Asteroid-Based Shielding 20:27 Hydrogen-Rich Polymers 21:22 Graphene, CNTs, and BNNTs 23:54 Active Shielding: Magnetic & Plasma Barriers 24:49 Fusion Fuel Shielding 25:27 Hybrid Shielding Approaches 28:16 God & Monsters 29:26 The Future of Radiation Shielding 30:00 Smart & Self-Healing Shielding 31:29 Artificial Magnetospheres 33:22 Biological Adaptation 35:35 Radiation-Resistant AI & Robotics 37:45 The Future of Space Radiation Protection 38:55 The Future of Water-Based Shielding. Check out Gods \& Monsters: https://nebula.tv/curiousarchive/gods…
🛒 SFIA Merchandise: https://isaac-arthur-shop.fourthwall… 🌐 Visit our Website: http://www.isaacarthur.net. ❤️ Support us on Patreon: / isaacarthur. ⭐ Support us on Subscribestar: https://www.subscribestar.com/isaac-a… 👥 Facebook Group: / 1583992725237264 📣 Reddit Community: / isaacarthur. 🐦 Follow on Twitter / X: / isaac_a_arthur. 💬 SFIA Discord Server: / discord. Credits: Fishbowl Starships Water As Shielding. Episode 721; June 1, 2025; Nebula Exclusive. Written, Produced, \& Narrated by: Isaac Arthur. Graphics: Bryan Versteeg, Jeremy Jozwik, Udo Schroeter. Select imagery/video supplied by Getty Images. Music Courtesy of Epidemic Sound http://epidemicsound.com/creator. Taras Harkavyi, \
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One of the most popular ideas in physics right now is something named “ER = EPR.” This theory has it that entangled particles are actually linked by tiny, tiny wormholes. Recently, a group of physicists tested the idea – let’s take a look at their findings.
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The #1 most-wanted particle in physics is the graviton, a quantum of gravity. If physicists were to prove that gravitons exist, they would unambiguously prove that Einstein’s theory is ultimately wrong and must be replaced by a more complete theory that gives quantum properties to space and time. In a recent paper, a physicist came up with an ingenious experiment that could prove that gravitons do exist. Let’s take a look.
A solar storm hitting Earth appears to have reduced the amount of incoming high-energy cosmic rays, suggesting a new way of measuring solar activity.
Solar activity has a well-known impact on the flux of low-energy cosmic rays that strike Earth. Now researchers have detected a solar-storm-induced change in the flux of higher-energy cosmic rays [1]. Using data from a large detector array in China, the team measured a decrease—over several hours—in cosmic-ray showers coming from a particular direction in the sky. The timing of this anisotropy suggests that cosmic rays heading into the outward-moving storm were preferentially scattered by the storm’s magnetic fields. The results could lead to a new way to study the magnetic structures in solar storms.
The solar wind—the spray of charged particles continually emitted by the Sun—partially shields Earth and other planets from cosmic rays that stream into the Solar System from all directions. The wind contains magnetic fields that help deflect the high-energy protons and other particles that make up the cosmic rays. In 2024, when the wind was at the peak in its 11-year cycle, the flux of cosmic rays was down by about 0.5% compared to the average.
Controlling and trapping molecules, units of a substance consisting of two or more chemically bound atoms, with laser light is significantly more challenging than trapping individual atoms. This is because molecules exhibit more complex vibrational and rotational dynamics that make them more difficult to cool and trap.
In a paper published in Physical Review Letters, researchers at Columbia University and Indiana University Bloomington reported the effective cooling and trapping of calcium monohydride (CaH), a molecule consisting of a calcium atom and a hydrogen atom bound together.
Transistors, small semiconductor-based switches that control the flow of electricity, are central components of all electronic devices, from computers to smartphones, wearables, sensors and smart appliances. Over the past decades, electronics engineers have been continuously working to boost the speed and performance of transistors while also reducing their size.
A promising approach for miniaturizing transistors entails the use of two-dimensional (2D) semiconductors, materials that are only one or a few atoms thick. Despite their potential, most high-performing 2D transistors have so far been demonstrated using relatively wide channels, and it has remained unclear whether their performance can be preserved when the channels are made much narrower.
Researchers at Stanford University recently developed new compact transistors based on narrow strips of monolayer 2D semiconducting materials known as nanoribbons. These transistors, introduced in a paper published in Nature Nanotechnology, were found to perform remarkably well despite their small size, outperforming previously developed nanoribbon transistors based on the same 2D materials.
Scientists at the Max Planck Institute for the Science of Light (MPL) have developed a technique for interrogating molecules on surfaces with spectroscopic precision, thereby reaching the ultimate quantum limit for the first time. With their findings, published in Science, the researchers open new opportunities for the study of molecule-surface interactions and molecular quantum technologies.
Many optical quantum technologies rely on nanoscale objects, such as atoms or molecules, that interact strongly with light. These quantum emitters are used for generating single photons, storing quantum information and entanglement distribution, processes that find application in quantum communication and computation.
To investigate these emitters individually, researchers need to keep them in one place for a long time. This is usually achieved by either trapping them in a vacuum or placing them inside a bulk material. Quantum emitters located on a surface would create new opportunities to manipulate their functionalities by “touching them,” for example, with an atomically sharp tip, as is used in scanning tunneling microscopy (STM) and atomic force microscopy (AFM).
