Quantum computers hold the potential to revolutionize the possibilities for solving difficult computational problems that would take classical computers many years to resolve. But for those computers ...

Recent advances in the study of quantum fluids and phase transitions on graphene have opened new avenues for understanding low-dimensional quantum phenomena and harnessing their potential for future ...

A never-before-observed phenomenon in quantum physics reportedly bears a striking resemblance to a world-famous work by Vincent van Gogh. Physicists from Osaka Metropolitan University and the Korea ...

Vincent Van Gogh's 136-year-old "The Starry Night" is making rounds on the internet. Apparently, the painting contained a replica of vortices produced during Kelvin-Helmholtz instability inside ...

The Einstein–de Haas effect, which links the spin of electrons to macroscopic rotation, has now been demonstrated in a quantum fluid by researchers at Science Tokyo. The team observed this effect in a ...

For the first time, scientists have observed electrons in graphene behaving like a nearly perfect quantum fluid, challenging a long-standing puzzle in physics. By creating ultra-clean samples, the ...

For nearly a century, some of the simplest questions in quantum theory have stubbornly resisted clean answers, turning basic ...

The Einstein-de Haas effect has been observed in a quantum fluid, showing that changes in magnetization transfer angular momentum from atomic spins to collective motion. (Nanowerk News) In 1915, ...

For more than 50 years, scientists have dreamed of seeing the hidden patterns that govern the motion of nonlinear waves—the unpredictable ripples that shape tsunamis, tides, and turbulent flows. Now, ...

Libby Heaney’s Growler (2024) is a glass sculpture that looks anything but. Despite its crystalline surface, it appears as if viscous, gummy and glutinous as it sags and drips down the side of its ...

In a spinor-dipolar Bose–Einstein condensate of europium atoms, near-zero magnetic fields allow dipole–dipole interactions to drive spin relaxation, producing circulating flow in the quantum fluid.