For decades, ferromagnetic materials have driven technologies like magnetic hard drives, magnetic random access memories and ...

Researchers from the Faculty of Physics at the University of Warsaw and the University of British Columbia have described how ...

With 70% of the proton's spin coming from gluons and orbital interactions, and with experiments and Lattice QCD calculations improving hand-in-hand, we're finally closing in on exactly why the ...

Developing technology that allows quantum information to be both stable and accessible is a critical challenge in the development of useful quantum computers that operate at scale. Research published ...

Recent physics studies have found that light can sometimes flow in unexpected ways, behaving like a so-called "superfluid." Superfluids, such as ultracold atomic gases or helium-4 below specific ...

Scientists have discovered a revolutionary new method for creating quantum states by twisting materials at the M-point, revealing exotic phenomena previously out of reach. This new direction ...

Physicists used lasers (one shown) to trap rubidium atoms in a quantum simulator, coaxing them to exhibit the physics of a strange, elusive substance called a quantum spin liquid. Jon Chase ...

The figure illustrates the adiabatic cooling process of a spin supersolid, as compared to paramagnetic cooling, highlighting the unique features of spin supersolid cooling. The triangular lattice ...

The new calculation hints that quantum spin ice could give a glimpse at physics within an alternate universe where the constant is much larger.

Luckily, however, the spin quantum number, interpreted abstractly and having nothing whatsoever to do with rotation despite its name, has become an essential feature of modern physics.

How tennis players create spin is about as complicated a physics question you can set about solving without invoking subatomic particles.