Understanding nature’s process could inform the next generation of artificial photosynthetic systems that produce clean and renewable energy from sunlight and water.

New machine learning methods bring insights into how lithium ion batteries degrade, and show it’s more complicated than many thought.

It combines human knowledge and expertise with the speed and efficiency of “smart” computer algorithms.

The lab is responding to the coronavirus crisis by imaging disease-related biomolecules, developing standards for reliable coronavirus testing and enabling other essential research.

The 1950s and ‘60s poisoning event was long attributed to methylmercury, but studies at SLAC suggest a different compound was to blame. The findings could reshape toxicologists’ understanding of disease related to mercury poisoning.

A better understanding of this phenomenon, which is crucial to many processes that occur in biological systems and materials, could enable researchers to develop light-sensitive proteins for areas such as biological imaging and optogenetics.

These inexpensive photosensitizers could make solar power and chemical manufacturing more efficient. Experiments at SLAC offer insight into how they work.

In regions that lack the resources to treat the contaminated water, it can lead to disease, cancer, and even death.

A new understanding of the nucleation process could shed light on how the shells help microbes interact with their environments, and help people design self-assembling nanostructures for various tasks.

What they learned could lead to a better understanding of how antibiotics are broken down in the body, potentially leading to the development of more effective drugs.

A better understanding of these materials and how they store and transport oil and gas could one day enable more efficient fossil fuel production.

It reveals an abrupt transition in cuprates where particles give up their individuality. The results flip a popular theory on its head.