CAMBRIDGE, MA – In the future, quantum computers could rapidly simulate new materials or help scientists develop faster machine-learning models, opening the door to many new possibilities. But these ...

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Record-breaking rearrangement: MIT and ORNL scientists moved 40,000 atoms in 40 minutes, surpassing a milestone first set in 1989. 3D at room temperature: The technique manipulates atoms inside ...

Record-breaking rearrangement: MIT and Oak Ridge scientists moved 40,000 atoms in 40 minutes, surpassing decades-old atomic ...

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It's been 37 years since scientists first demonstrated the ability to move single atoms, suggesting the possibility of ...

A team of researchers from the Massachusetts Institute of Technology (MIT) and the Oak ...

Researchers have developed a novel superconducting qubit architecture that can perform operations between qubits with much higher accuracy than scientists have yet been able to achieve. This ...

Researchers demonstrated extremely strong nonlinear light-matter coupling in a quantum circuit. Stronger coupling enables faster quantum readout and operations, ultimately improving the accuracy of ...

Researchers at MIT, Cambridge, Mass., say they have demonstrated what they believe is "the strongest nonlinear light-matter coupling ever achieved in a quantum system." They add that their experiment ...

Building on a long-standing MIT–IBM collaboration, the new lab will chart the convergence of AI, algorithms, and quantum computing The MIT-IBM Computing Research Lab builds on a distinguished history ...

Coupling between artificial atoms and photons processes quantum information in nanoseconds. Strong nonlinear light-matter coupling in a quantum circuit. Researchers at MIT, Cambridge, Mass., say they ...