Researchers from the University of Nebraska–Lincoln and Texas A&M University have developed a groundbreaking method to create durable construction materials on Mars using just local resources—Martian soil, sunlight, air, and water. This technique could eliminate the massive cost and logistical headache of transporting building supplies across 140 million miles of space.

Published in the Journal of Manufacturing Science and Engineering, the study outlines how scientists engineered a “synthetic community” of cyanobacteria and filamentous fungi—organisms that, when combined, can transform Mars’ dusty, barren soil into solid, rock-like structures. This duo acts similarly to lichens on Earth, which are cooperative lifeforms made of fungi and algae or bacteria.

To think about an artificial limb is to think about a person—an individual who moved, reached, worked, and lived with that device as part of their body. Prosthetic limbs are not just mechanical objects; they are tools of motion and touch, designed to connect people to their world.

Yet, when prostheses from the past are studied in museums or archives, the human connection often feels distant. Their users are long gone. The devices are typically damaged, worn down by centuries of time and exposure. They sit motionless on display or tucked away in storage—silent artifacts with untold stories.

The NSF-DOE Vera C. Rubin Observatory has released its first images, marking the debut of a groundbreaking 3,200-megapixel digital camera—the most powerful ever built. Perched atop Cerro Pachón in Chile, the observatory is poised to collect more astronomical data than all previous optical telescopes combined.

In just 10 hours of initial test observations, the observatory’s 8.4-meter telescope discovered 2,104 previously unknown asteroids and captured images of 10 million galaxies. Over the next decade, it is expected to map 20 billion galaxies while exploring dark matter and dark energy, which together make up about 95% of the universe.

Yale researchers have developed a promising new method to electrochemically convert nitrate—a common and harmful water pollutant—into ammonia. This innovation offers two major benefits: purifying contaminated water and generating a valuable product that can be used for fertilizers and carbon-free fuels.

Nitrate, while essential for plant growth, is a prevalent contaminant in wastewater and can significantly harm water quality when overly abundant. Converting nitrate into ammonia is not a new idea, but doing so efficiently and affordably has remained a major challenge. Scientists have long struggled to achieve both high selectivity—minimizing unwanted byproducts—and high activity, which refers to the speed of conversion.

The technology addresses critical safety concerns in high-pressure occupations where mental fatigue significantly contributes to accidents. Recent incidents—such as a January collision at Reagan National Airport attributed to understaffed air traffic control operations—underscore the urgent need for objective mental workload assessment tools.

Traditional EEG monitoring relies on bulky caps with multiple electrodes and conductive gels, which can be unstable due to variations in head shape. A new approach using disposable electronic tattoos overcomes these limitations with custom-fitted adhesive sensors designed to conform to individual facial geometry.

Detecting airborne hazardous chemicals has long posed a challenge due to their dilute concentrations and high mobility. Yet, effective monitoring of these substances is essential for protecting public health and the environment. A newly developed device, known as ABLE, offers a promising solution by making airborne hazard collection and detection both more efficient and accessible.

Developed by researchers from the University of Notre Dame and the University of Chicago, ABLE is a compact device measuring just four by eight inches. Despite its small size and low cost—under $200—it has demonstrated powerful capabilities in capturing and analyzing airborne contaminants.