How did life make the leap from single cells to coordinated, multicellular organisms? And how do genetically identical cells ...

Numerical simulations in physics often require estimating a multitude of parameters, making the process computationally ...

Quantum entanglement is a state in which particles are entwined with each other. In this entwined state, the properties of ...

Chemical bonding is one of the central organizing principles of the microscopic world. It determines how atoms combine and ...

Honeycombs are famous for their elegant design, but now they may have found a new application: quantum computing. To collect ...

Scientists at the University of California, Riverside are making breakthroughs in understanding how quantum wave functions move across ultra-thin materials—research that could eventually improve solar ...

Quantum computers have the potential to transform science, accelerating breakthroughs in drug development, cosmology, ...

The planar Hall effect is a tabletop diagnostic tool for special quantum properties useful in basic research and ...

For nearly a century, there were two known kinds of magnets. Ferromagnets are the classic magnets that attract metal and keep pictures stuck to the refrigerator. Antiferromagnets hide their magnetism ...

Topological phases are unusual states of matter that give rise to properties protected by a material's overall structure (i.e., "topology"), as opposed to microscopic details. These phases are of ...

Quantum mechanics is a physics framework that describes how matter and energy behave at an extremely small scale, ...

Using a conventional computer and cutting-edge mathematical tools and code, physicists at the Center for Computational ...