Non-target LC–HRMS captures thousands of wastewater features, enabling detection of unexpected removals and leachables beyond ...

Sunlight-powered chemistry: Cambridge scientists used simulated sunlight and a cobalt molybdenum sulfide catalyst to convert plastic waste into anilines with yields up to 99%. Waste as resource: The ...

Dual waste solution: Cambridge teams use recovered battery acid and plastic waste to generate hydrogen fuel or chemical feedstocks, addressing two environmental problems simultaneously.

Cambridge scientists use sunlight, battery acid, and plastic waste to make industrial chemicals with 99% yield. Researchers ...

Battery acid from old cars, with a little help from a catalyst, can give plastic waste a new purpose, using it to drive the ...

A new breakthrough by University of Chicago chemists shows how to easily customize molecules by swapping carbon-oxygen pairs ...

Synthetic” and “natural” are largely useless terms. But not “semisynthetic.” It’s a real word that describes a critical ...

A new biodegradable material could transform how the plastics industry addresses waste by creating products that literally ...

Researchers at the University of Cambridge have developed a process that converts plastic trash into clean hydrogen fuel ...

Natural rubber, tapped from trees as latex, is the world's most widely used bio-elastomer. Comprising long molecular chains ...

Scientists at the University of Adelaide have mapped out a dual-purpose solution known as solar-driven photoreforming.

Scientists are advancing a promising solution to two of the world's biggest challenges—plastic pollution and clean energy—by ...