For decades, it has been widely believed that electrons move most efficiently in materials that are clean and highly ordered.

Electron transfer is enhanced by minimal energetic driving force at the organic-semiconductor interface in upconversion (UC) organic light emitting diodes (OLEDs), resulting in efficient blue UC-OLEDs ...

Electron transfer processes underpin the quest to develop sustainable energy systems by emulating the natural photosynthetic machinery. Artificial photosynthesis seeks to convert solar energy into ...

A new study reveals how an advanced iron-modified biochar can harness the natural chemistry of soils to break down persistent ...

A long-standing mystery in bacterial bioenergetics is beginning to unravel as researchers capture fleeting structural states of a sodium-pumping enzyme in action.

A newly identified mechanism reveals how proton motion can subtly yet powerfully influence triplet energy transfer in ...

Researchers have visualized atoms in motion just before a radiation-driven decay process occurs, revealing a surprisingly ...

Perovskites with an ABO 3 structure, where A represents divalent and B tetravalent metal cations, are widely used in fields like dielectrics, ferroelectrics, magnetics, and energy storage. Their high ...

Using a new method, physicists found a way to 'catapult' electrons across solar materials in quadrillionths of a second.

Researchers developed a quantum-dot circularly polarized light sensor using chiral charge transport layers, spanning ultraviolet to short-wave infrared wavelengths.

The findings deepen the understanding of electron transfer from CT to T1 state, paving the way toward efficient optoelectronic devices. Electron transfer is an elementary process in which an electron ...