Hydrogen peroxide (H 2 O 2) packs so much chemical energy into a small space that it is powerful enough to fuel rockets. But this same ability to concentrate energy also makes hydrogen peroxide useful ...

Figure showing the systematic design of the photocatalytic covalent organic frameworks (COFs) for manufacturing hydrogen peroxide using flow reactors. (a) The COF with segregated donor and acceptor ...

A sprinkling of magnetic nanoparticles is just enough to power up catalysts, so they can make hydrogen peroxide production more efficient. Researchers have achieved a breakthrough in improving the ...

Researchers have developed metal-organic frameworks (MOFs) that efficiently produce hydrogen peroxide (H 2 O 2) using small temperature differences, offering a sustainable approach to chemical ...

(Left) Schematic representation of the structure of a porous carbon catalyst with boron doping on the surface and carbon walls forming the mesopores. (Right) Mesopore structure and atomic-scale ...

Cornell scientists have discovered a potentially transformative approach to manufacturing one of the world's most widely used chemicals—hydrogen peroxide—using nothing more than sunlight, water and ...

New research led by the University of Bath has shown that surface-modified graphene could transform the production of hydrogen peroxide (H 2 O 2) for industrial use as a bleaching agent or ...

While hydrogen peroxide (H 2 O 2) has numerous applications, its industrial production is costly and energy-intensive due to rare metal catalysts. Zinc is an abundant and historically-used element … ...

Researchers have developed metal-organic frameworks (MOFs) that efficiently produce hydrogen peroxide using small temperature differences, offering a sustainable approach to chemical production. This ...