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Category: space – Page 3

Earth’s magnetic field creates a previously undetected pocket of protection from radiation on the moon

High-energy particles called galactic cosmic rays (GCRs) bombard unprotected objects in space, often causing damage. Earth, however, is protected by its magnetic field, which creates a protective shell around the planet that can deflect dangerous charged particles, like GCRs.

The moon is known to pass through the tail-like part of Earth’s magnetosphere, but a new study, published in Science Advances, suggests the moon might experience additional protection at another point in its orbit. Although this pocket of protection exists when the moon is outside of the magnetosphere, researchers believe the effects are still due to Earth’s magnetic field.

An anomalous dip in particle counts When the research team analyzed data taken from the Lunar Lander Neutron and Dosimetry (LND), onboard China’s Chang’E-4 lander, they were surprised to find that the LND experienced a 20% dip in GCR particles hitting detectors while the lander was on the moon’s far side. This occurred at a specific time during the lunar “morning” and only for about 2 days each lunar cycle. Since the LND took data over 31 cycles, the team could see that this was not just a one-off occurrence. This was unexpected because it was previously assumed that GCRs are evenly distributed in the space between Earth and the moon, outside Earth’s magnetosphere.

Subaru telescope captures comet 3I/ATLAS composition change

The Subaru Telescope observed the interstellar comet 3I/ATLAS on January 7, 2026, after it made its closest approach to the sun. By observing colors in the coma around the comet, astronomers could estimate the ratio of carbon dioxide to water. This ratio is much lower than that inferred from earlier observations by space telescopes. These findings suggest that the chemistry of the coma is evolving over time and offers clues to the structure of comet 3I/ATLAS. The work appears in The Astronomical Journal.

Comet 3I/ATLAS (C/2025 N1) has garnered much attention as a comet which originated outside of the solar system. A research group led by Yoshiharu Shinnaka of the Koyama Space Science Institute, Kyoto Sangyo University, used the Subaru Telescope to observe comet 3I/ATLAS after perihelion, the comet’s closest approach to the sun. The team applied analytical methods and expertise accumulated through investigations of solar system comets to the data.

From this analysis, the team was able to estimate the ratio of carbon dioxide (CO2) to water (H2O) in the coma, the cloud of gas around the nucleus of the comet. Because the gas in the coma comes from the nucleus, the coma composition provides hints to the composition of the nucleus.

Next-generation atomic clock successfully tested at sea

Adelaide University researchers have successfully tested a new type of portable atomic clock at sea for the first time, using technology that could help power the next generation of navigation, communications and scientific systems. The research team, from the Institute for Photonics and Advanced Sensing (IPAS), developed the highly precise device and trialed it aboard a vessel provided by the Royal Australian Navy in July 2024. They have reported their findings in a new paper published in the journal Optica.

Atomic clocks are the world’s most accurate timekeepers and are essential for technologies such as GPS navigation, telecommunications networks and radio astronomy. However, most high-performance atomic clocks operate in carefully controlled laboratory environments and are not designed to be easily transported or used in challenging real-world conditions. The newly developed device changes that.

Photonics researchers created a portable optical atomic clock that uses laser-cooled atoms of the element ytterbium to keep time with extreme precision. By cooling the atoms with lasers and measuring a very specific atomic transition, the clock can track time far more accurately than conventional systems.

Copper blasted into a million-degree plasma strips away 22 electrons in a flash before atoms recover

When laser flashes hit matter, electrons are knocked off their orbits around the atomic nuclei. This can generate extremely hot plasmas composed of charged particles—ions and electrons. Researchers at HZDR have now observed this ionization process in more detail than ever before. To do so, they combined two state-of-the-art lasers: the X-ray free-electron laser and the high-intensity optical laser ReLaX at the HED-HiBEF experiment station at the European XFEL in Schenefeld, near Hamburg. Their findings, published in Nature Communications, deliver fundamental insights into the interaction of high-energy lasers and matter under extreme conditions.

Ionization takes place extremely quickly—in picoseconds, within a few trillionths of seconds. In order to monitor this process in detail, laser pulses must be significantly shorter. “These are exactly the conditions provided by the two lasers that have pulse durations of just 25 and 30 femtoseconds—that is, trillionths of a second,” explains Dr. Lingen Huang, head of experimentation in HZDR’s Division of High-Energy Density.

Initially, an extremely intense flash of light strikes a delicate copper wire that is only about one-seventh the thickness of a human hair. The pulse intensity is approximately 250 trillion megawatts per square centimeter—concentrated on a tiny surface for an extremely short time. Values like this are otherwise achieved only under exceptional conditions, such as in extreme astrophysical environments like the immediate vicinity of neutron stars or during gamma-ray bursts.

EarthSpace 2026

Register now for 2026! A discussion of Earth and space on Earth Day, with Frank White, me, and other great guests!

EarthSpace 2026 brings together leaders, thinkers, and builders to explore one core idea: the future of Earth and the future of space are not separate conversations.

From climate solutions to space infrastructure, from policy to culture, the choices we make today will define how humanity lives on this planet—and beyond it.

This is not a passive webinar. It’s a focused, high-signal conversation with people actively shaping the frontier.

Space 18th SDG — A Side Event at COPUOS Legal SubCommittee — 16 April 2026

Space has become critical infrastructure for climate monitoring, disaster risk reduction, connectivity, navigation, education, and long-term planetary resilience. Even more important, space is an open horizon for new industrial development and settlement, starting with Earth orbit, the geo-lunar system, and the near-Earth asteroids. The Space 18th SDG initiative proposes a non-regulatory, enabling framework that strengthens the existing 17 SDGs by recognizing outer space as both an enabler of sustainable development and an environment requiring stewardship.
THE PANEL:
Prof. Sergio Marchisio, Space Law Expert, La Sapienza University, Rome, Italy.
Ms. Fikiswa Majola, Deputy Director Space Systems, Department of Science and Technology (DST) South Africa.
Prof. Guoyu Wang — Space Law Center, China National Space Administration.
Dr. Claire Nelson, The Future Forum, Giamaica.
Adriano V. Autino, SRI CEO & Founder.
Maria Antonietta Perino, Thales Alenia Space, Italy.
Stefano Antonetti, D-ORBIT SpA, Strategy Director, Italy.
Antonio Stark, iSpace, Japan.
MODERATES:
Dr. Gülin Dede, SRI Director of Relations, Chair of the Space 18th SDG Coalition.

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