The genome is more than a linear code; it is a dynamic structure whose three-dimensional folding dictates how genes are regulated. Traditional sequencing technologies capture base-level variation but ...

Materials called relaxor ferroelectrics have been used for decades in technologies like ultrasounds, microphones, and sonar ...

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 ...

How do organic solar cells work on the inside? The answer lies in structures far too small to see—and difficult to access even with advanced techniques. So far, researchers have relied mainly on X-ray ...

From classrooms to cutting-edge labs, 3D molecular visualization is transforming how we understand chemistry. Digital tools, physical models, and quantum-informed simulations are making the invisible ...

MIT-led researchers have, for the first time, directly mapped the three-dimensional atomic and charge structure of relaxor ferroelectrics, materials used in sensors, ultrasound, and sonar. Using multi ...

In a recent study published in the journal Nature Methods, a group of researchers developed a novel method called Ribonucleic Acid (RNA) High-Order Folding Prediction Plus (RhoFold+). This deep ...

Most fat stores energy; the body's brown fat does the opposite. Unlike the white fat that accumulates just under our skin, ...

Research on low-dimensional perovskites shows that precise molecular design can enhance solar cell performance, addressing key challenges in commercialization.