For more than 50 years, scientists have sought alternatives to silicon for building molecular electronics. The vision was ...

Template-assisted synthesis dramatically improves the yield of functionalized oligophenylene cages, report researchers from Japan. By using covalent templates to guide a six-fold Suzuki–Miyaura ...

Conducting polymers have emerged as a pivotal class of materials for advanced optoelectronic applications owing to their tunable molecular structure, ...

A quick, purification-free method was developed by researchers at Institute of Science Tokyo, to capture the detailed 3D structures of flexible sugar molecules. By growing crystals of galectin-10 ...

Genesis’ proprietary foundation model – Pearl – outperforms frontier models, including AlphaFold 3, on key benchmarks that predict utility in real-world drug discovery Pearl’s performance improved ...

This process is costly, time-consuming, and has a low success rate. KAIST researchers have developed an AI model that, using only information about the target protein, can design optimal drug ...

Representing a molecule in a way that captures both its structure and function is central to tasks such as molecular property prediction, drug drug ...

Molecular electronics is a branch of nanotechnology that focuses on using individual molecules or nanoscale molecular structures as electronic components to create miniaturized circuits and devices.