Scientists demonstrate a new method for stretching the length of time qubits can maintain information — by disrupting the symmetry of their environment.
The third Workshop on Quantum Repeaters and Networks, locally co-organized by the Q-NEXT quantum research center and the Chicago Quantum Exchange, provides a forum for advancing next-generation information technologies.
In a report published in ACS Nano, researchers demonstrate a near-infrared nanolaser using a polymer microsphere as the microcavity and semiconducting single-walled carbon nanotubes as the gain material.
Five undergraduate fellows supporting research at the Q-NEXT quantum research center share what they’ve learned about quantum information science, their research experiences and their aspirations.
While having their own unique areas of expertise and resources, the NQISRCs are all aligned to the same mission — the advancement of quantum information science.
Global quantum ecosystem company ColdQuanta and startup Super.tech have merged to address pressing needs in quantum research through innovative hardware and software platforms.
In a paper appearing in Quantum Science and Technology, researchers present a theoretical analysis showing that a single-electron qubit floating on a solid neon could achieve a coherence time as long as 81seconds.