Tag: Substrate (chemistry)

InnovationScience

Scientists Engineer Programmable Enzyme Systems Through Multiscale Confinement Strategies

Researchers are harnessing nature’s blueprint for enzyme efficiency through innovative multiscale confinement strategies. These approaches enable programmable biocatalysis that could transform sustainable chemical manufacturing and organic synthesis.

Nature-Inspired Breakthrough in Biocatalyst Engineering

Scientists are revolutionizing enzyme catalysis by implementing multiscale confinement strategies that mimic nature’s highly efficient cellular environments, according to a recent review published in Nature Synthesis. The report states that this innovative approach enables programmable biocatalysis with enhanced performance, stability, and specificity that could transform sustainable chemical manufacturing.

by Elisa Romero
InnovationScience

Artificial Photoenzymes Enable Selective Energy Transfer for Asymmetric Synthesis

Scientists have engineered artificial photoenzymes that compartmentalize energy transfer catalysis, enabling highly enantioselective photocycloadditions. The system uses strategic triplet quenching to suppress background reactions while maintaining high yields and stereochemical control across diverse substrates.

Breakthrough in Enantioselective Photocatalysis

Researchers have developed a novel approach to enantioselective energy transfer catalysis using compartmentalized triplet photoenzymes, according to a recent study published in Nature Catalysis. The system reportedly addresses longstanding challenges in controlling stereochemistry during photochemical reactions by creating protected environments within engineered protein scaffolds.

by Nathan Cole
InnovationScience

Scientists Illuminate Dark Excitons in 2D Materials Using Plasmonic Tips

Researchers have made significant progress in controlling previously inaccessible dark excitons in 2D materials. The breakthrough involves using plasmonic tips to overcome fundamental limitations that have kept these quantum states dark and non-emissive.

Breakthrough in Dark Exciton Control

Scientists have developed a novel approach to activate and control dark excitons in tungsten diselenide (WSe₂) monolayers, according to recent research published in npj 2D Materials and Applications. The study reportedly demonstrates how plasmonic effects from metallic tips can brighten these typically non-radiative quantum states, overcoming fundamental limitations that have previously made them inaccessible for optical applications.

by Elisa Romero