• Scientists have developed a new method to use nickel-based compounds for safely modifying proteins inside living cells, a task previously limited by toxicity concerns. This breakthrough enables researchers to track viruses and bacteria inside cells and deeply study how proteins function, opening doors to new types of biological research and drug discovery. Source →

• A new review establishes a clear link between the microscopic structure of molten fluoride salts and their large-scale physical properties, a concept termed “fluoroacidity”. This framework is crucial for designing safer and more efficient materials for next-generation nuclear reactors and advanced metal processing. Source →

• Researchers have created a guide that explains complex quantum materials like Dirac and Weyl semimetals using simple model examples, building on the foundational discovery of graphene. This tutorial helps scientists and students understand the exotic electronic behaviors in these materials, which are essential for developing future ultra-fast electronics and quantum computers. Source →

• A new review summarizes the latest advances in using lasers to precisely modify and functionalize ultra-thin two-dimensional materials known as transition metal dichalcogenides (TMDs). This precise laser processing is key to tailoring these materials for next-generation applications in flexible electronics, sensors, and energy storage devices. Source →

• Scientists are reviewing progress on solid-state battery electrolytes made from natural biopolymers that allow only one type of ion to move. This design prevents the formation of dangerous metal spikes called dendrites, paving the way for safer, longer-lasting, and higher-energy lithium and sodium batteries for electric vehicles and portable electronics. Source →