A new atom camera uses one ultracold rubidium atom to map light intensity and polarization with spatial resolution below 100 nanometers.

Scientists have created a process to make patterns in atom-thick layers that combine a conductor -- graphene -- and an insulator -- hexagonal boron nitride. The process may lead to new possibilities ...

A research group led by Assistant Professor Takafumi Tomita and Professor Kenji Ohmori at the Institute for Molecular Science, National Institutes of Natural Sciences, has developed a new microscopy ...

Defect-free pattern of 100 atomic qubits: a new platform for scalable quantum computing. Credit: Gerhard Birkl Neutral atoms trapped by light in arrays of dipole traps could be used as quantum bits ...

A research group led by Assistant Professor Takafumi Tomita and Professor Kenji Ohmori at the Institute for Molecular Science, National Institutes of Natural Sciences, has developed a new microscopy ...

Barredo and team report their use of precision optical-engineering methods to sort atoms into arbitrary 3D patterns. Barredo et al. extend their previously reported method for 2D atom sorting to three ...

Images of light patterns captured using the Atom Camera. (Left) Intensity distribution of a microscopic lattice structure generated by a specialized optical device. (Right) Non-trivial polarization ...