Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
The study of complex oxides using a local probe reveals exciting secrets — from magnetic domains arranged like bricks in a wall to the possible first visualization of a polaronic charge carrier.
Quantum states of matter with topological order are of great fundamental — and potential practical — interest. Polar molecules stored in optical lattices could offer a platform for realizing such 'exotic' states.
The ability to generate intense attosecond pulses of light promises unprecedented opportunities to study the lightest and fastest of all chemically relevant particles — electrons. Two techniques demonstrate progress towards measuring and controlling their attosecond dynamics.
The sensitivity and dynamic range of a network made of neuron-like elements is now shown to be maximized at the critical point of a phase transition. This raises the question of whether critical senses might improve survival in a critical world.
It's a twenty-year-old question: how much do the constituent quarks and gluons contribute to the spin of a nucleon? New results from the COMPASS experiment add to the picture.
As the duration of pulses generated by modern lasers approaches that of a single optical cycle, the absolute phase of the wave-packets in such pulses becomes important. A new method for measuring this phase could aid their use in both high-field physics and attosecond pulse generation.
The ability to confine alpha particles within a burning deuterium–tritium plasma is likely to be crucial to the future of fusion power generation. Resonant interactions between alpha particles and magnetohydrodynamic vibrations could threaten their confinement.
For more than a hundred years, optical physicists have been fascinated by the effects that can arise when light interacts anomalously with diffraction gratings. A new experimental study shows how nanofabrication and diagnostic techniques can pull apart the physics behind the so-called anomalies.
'Large ellipticals' are the lords of the galaxies in terms of mass, size and evolutionary development. Different theories for their formation have been proposed, but the debate might now be resolved by new models and observations.
Nanoscale engineering can now take advantage of a new ratchet device: it acts as a diode for superconducting vortices, but its directionality can be controlled and repeatedly reversed to become an effective 'two-way street'.
The broken symmetry at an interface between two different oxides is a source of unexpected behaviour. For instance, the modified orbital physics at the interface can lead to induced magnetism in a superconductor.
The tendency of a stationary droplet, sitting on the surface of a large body of liquid, to eject a smaller droplet when it eventually coalesces with the body has long been known but its details poorly understood. A combination of high-speed imaging and numerical simulations casts new light on this intriguing phenomenon and its widespread implications.
The zero-point entropy of glass-like states can be an abstruse concept, but the study of a chemical modification of 'spin ice' promises to bring it out into the open.
In Flatland, glasses reproduce all the behaviour of their three-dimensional relatives. A simulation of a two-dimensional molecular glass-forming liquid takes advantage of the unimpeded view, and shows how fluctuations in structure can produce domains of slow molecules on cooling.
The fine-structure constant plays a central role in our understanding of electromagnetic interaction. A new approach to determining its value complements the most precise measurements made so far.
A breakthrough in the ability to cool high-energy antiproton beams could provide the key to unleashing the potential of the world's highest-energy particle collider.
What happens if the 'weak link' between two superconductors in a Josephson junction is a carbon nanotube, with a limited number of states available for electron transport? A supercurrent flows, but in a unique fashion.
When it comes to superconducting device components, there is no such thing as too thin, but superconductivity has its limits. Now, ultrathin lead films with crystalline perfection have been shown to be able to carry large dissipationless currents down to a thickness of a few monolayers.
Electron spins are traditionally manipulated by a resonant magnetic field, but spin–orbit coupling provides a better option of achieving spin operation, using a resonant electric field. A theoretical treatment now fills in the microscopic detail of this process.
In the early 1900s, the Solvay conferences famously brought together the early protagonists of quantum theory. At the latest meeting in the series, the issue was now the quantum structure of space–time itself.
