This study introduces a custom-designed NV quantum sensing based microscopy for high-sensitivity microscopic magnetic imaging (MMI) of individual Chang'e-5 lunar regolith grains, achieving the first direct observation of surface magnetic field distributions at the single-particle scale. Overcoming the limitations of traditional orbital magnetometry (kilometer-scale) and macroscopic bulk rock-magnetic measurements (e.g., VSM), our approach realizes the separation and identification of magnetic signals at the micro- to nanoscale. Results indicate that native irons in basalt clasts exhibits weak and directionally uniform magnetism, suggesting it records the lunar paleomagnetic field during magma cooling; in contrast, carriers such as nanophase iron and Fe-Ni alloys in breccia grains, as well as crack-associated magnetic “stripe” features, display distinct magnetic signals reflecting the influence of multiple geological processes, including meteorite impacts and space weathering. Overall, this study advances lunar magnetic detection to the single-particle microscopic level, providing direct evidence for understanding the origin of lunar magnetic anomalies and the magnetic field evolution history, offering a new microscopic perspective for lunar and planetary science.

This study presents a metamaterial-inspired design to develop negative Poisson's ratio (NPR) structural electrodes using a directional freezing 3D printing-assisted strategy. This approach incorporates both macroscopic NPR structures and microscopic directional porous structures, which enhances ion transport, improves compressibility and provides impact resistance, effectively preventing package bulges during compression. Consequently, the electrodes demonstrate a high 50% compressible deformation and recover their original state even after 50 cycles of 25% compression. The 3D-printed lithium iron phosphate cathodes deliver a high average specific capacity of 153 mAh/g over 100 cycles and exhibit outstanding rate capability. Furthermore, the assembled full cell maintains both excellent compressibility and impact-buffered resistance, highlighting its potential applications. This innovative design of NPR metamaterial-structured electrodes provides a universal platform for developing the next generation of impact-buffered, compressible structural batteries.

Scientists have solved a 66 million year old mystery about why the earth cooled after the age of the dinosaurs.

A new device, designed by researchers at the University of Colorado Boulder and University of Colorado Anschutz, jiggles red blood cells until they break apart—revealing valuable information about their quality. 

Researchers have reported new experimental results addressing the origin of rare proton-rich isotopes heavier than iron, called p-nuclei. Led by Artemis Tsantiri, then-graduate student at the Facility for Rare Isotope Beams (FRIB) and current postdoctoral fellow at the University of Regina in Canada, the study presents the first rare isotope beam measurement of proton capture on arsenic-73 to produce selenium-74, providing new constraints on how the lightest p-nucleus is formed and destroyed in the cosmos. The team published its results in Physical Review Letters (“Constraining the Synthesis of the Lightest 𝑝 Nucleus ⁷⁴Se”).

Rye pollen slows tumor growth in animal models of cancer. Chemists determined the 3D structure of the bioactive molecules in rye pollen. With new blueprint, researchers could develop strategies for cancer treatment.

After more than 25 years of experience in condensed matter physics, as a student, researcher and in high-ranking executive roles at neutron scattering sources around the globe, Jon Taylor brings a wealth of experience and accomplishments to his new position as Associate Laboratory Director for the Neutron Sciences Directorate (NScD) at the Department of Energy’s Oak Ridge National Laboratory.