Researchers led by Rice University's Guido Pagano used a specialized quantum device to simulate a vibrating molecule and ...

The ultrafast placement of an electron in a polar liquid generates collective molecular vibrations in a spherical nano-volume. The vibrations change the diameter of this sphere periodically for more ...

Scientists have discovered a remarkable way to destroy cancer cells. Stimulating aminocyanine molecules with near-infrared light caused them to vibrate in sync, enough to break apart the membranes of ...

A team of Johns Hopkins engineers has developed a new, more powerful method to observe molecular vibrations, an advance that could have far-reaching implications for early disease detection. The team, ...

The cell is grown on a Si-C-Membrane and embedded in its liquid medium. The tip of the s-SNOM detects vibrations, probed by Infrared-Light from BESSY II. Infrared vibrational spectroscopy at BESSY II ...

Waves don’t just shape oceans or ripple across a pond. They also shape the building blocks of our universe—light, sound, and even the tiny vibrations inside atoms and molecules. These vibrations, ...

A research group at The University of Tokyo has discovered a new principle by which helical chiral molecules acquire spin through molecular vibrations, enabling them to adhere to magnets. Until now, ...

Fig. 1. (a) Localized electron in a polar liquid. The scheme shows the probability density of a localized electron (contour) in an environment of solvent molecules with an electric dipole moment. (b) ...