Traditional solar panels usually use rigid silicon wafers anywhere from 120 to 200 micrometers thick. Researchers develop ...

Perovskite solar cells have garnered widespread attention as a low-cost, high-efficiency alternative to conventional silicon ...

Scientists create perovskite film semiconductors at room temperature using lasers, which is a revolution for chips and solar ...

Solar power has long been constrained by a supposedly unbreakable ceiling on how much sunlight a panel can turn into ...

A research team has discovered a unique quantum state at the interface between organic materials and two-dimensional ...

The introduction of a nanometric germanium oxide layer drastically improved device performance and stability. As the global demand for clean energy accelerates, solar power continues to attract ...

Long before perovskite solar cells began smashing efficiency records and transforming the future of clean energy, their modern design first emerged from a quiet experiment at Northwestern University.

Research from Gagliardi Group offers a powerful new toolkit to understand and eventually design complex materials, including high-temperature superconductors and solar cell semiconductors. (Image: ...

According to Google DeepMind, the company will open its first automated materials discovery lab in the UK in 2026, fully integrated with the Gemini AI model. The lab will leverage AI-driven automation ...

ABSTRACT: This study uses TCAD numerical simulation to evaluate how key absorber parameters in Cu(In, Ga)Se2 (CIGS) thin-film solar cells influence device performance, with the objective of ...