Briefing

Arctic peatlands are expanding with rising temperatures, storing more carbon at least for now. But future warming could reverse this benefit, releasing massive emissions.

Even after 20 million years of evolutionary separation, two tiny worm species show astonishingly similar patterns in how they turn genes on and off. Scientists mapped every cell s activity during development and found that genes essential to basic functions like muscles and digestion remained largely unchanged. Meanwhile, genes linked to sensing the environment or brain-like functions showed more variation. This high-resolution comparison of every cell between species may help unlock mysteries of how life evolves and adapts without always changing how it looks.

Researchers at Colorado State University have developed a new photoredox catalysis system that uses visible light mimicking photosynthesis to drive energy-intensive chemical reactions at room temperature. This groundbreaking process could significantly reduce the energy required in chemical manufacturing, especially in industries reliant on fossil fuels.

In a twist on conventional wisdom, researchers have discovered that in ocean-like fluids with changing density, tiny porous particles can sink faster than larger ones, thanks to how they absorb salt. Using clever lab experiments with 3D-printed agar shapes in a stratified water column, scientists demonstrated that porosity and particle shape are major factors in determining sinking speed. This finding could revolutionize how we understand carbon cycling, microplastic behavior, and even strategies for ocean-based carbon capture.

Beneath the forest floor lies an overlooked secret: many plants grow a second set of roots far deeper than expected sometimes over three feet down tapping into hidden nutrient stores and potentially locking away carbon. A new study using deep-soil data from NEON reveals that these “bimodal” rooting systems are more common than previously believed and may play a powerful role in stabilizing ecosystems and fighting climate change.

USC researchers have uncovered a hidden driver behind the early and severe onset of Alzheimer’s in people with Down syndrome: iron overload in the brain. Their study revealed that individuals with both conditions had twice the iron levels and far more oxidative damage than others. The culprit appears to be ferroptosis, an iron-triggered cell death mechanism, which is especially damaging in sensitive brain regions.

Researchers at ETH Zurich have developed an astonishing new material: a printable gel that’s alive. Infused with ancient cyanobacteria, this “photosynthetic living material” not only grows but also removes CO₂ from the air, twice over. The bacteria use sunlight to produce biomass and simultaneously trigger mineral formation, which locks carbon away in a stable form. Engineered hydrogels provide an ideal habitat for these microbes, allowing them to thrive for over a year. Even more captivating, this material has already made its way into architecture, with living installations showcased in Venice and Milan that merge design, sustainability, and living science.

The Pleiades, a crescent moon and Venus  —  what more could an astrophotographer want?

Cold sore-causing HSV-1 doesn’t just hijack cells it reconfigures the entire architecture of our DNA to aid its invasion. Researchers discovered that it actively reshapes the 3D structure of the human genome within hours of infection, using host enzymes like topoisomerase I to gain access to crucial genetic machinery. Stunningly, blocking this single enzyme shuts the virus down completely.

Scientists at UBC have devised a chip-based device that acts as a “universal translator” for quantum computers, converting delicate microwave signals to optical ones and back with minimal loss and noise. This innovation preserves crucial quantum entanglement and works both ways, making it a potential backbone for a future quantum internet. By exploiting engineered flaws in silicon and using superconducting components, the device achieves near-perfect signal translation with extremely low power use and it all fits on a chip. If realized, this could transform secure communication, navigation, and even drug discovery.