Tag Archive for 'Qubit'

A rendering of the ion trap chip. Image credit: Jochen Wolf & Tom Harty, University of Oxford.

Scientists Set New Record for Qubit Operation Accuracy

Jun 10, 2025 by News Staff

A team of physicists at the University of Oxford has achieved the lowest-ever error rate for a quantum logic operation — just 0.000015%, or one error...

Yang et al. generated highly mixed quantum states with distinct quantum properties. Image credit: University of Innsbruck.

Scientists Generate ‘Hot Schrödinger Cat States’

Apr 4, 2025 by News Staff

The quantum superposition principle allows us to prepare a system in a superposition of two arbitrary states. The paradigmatic example is the superposition...

An artist’s impression of defect centers in diamond nanostructures. They can be used as quantum bits. Via quantum entanglement, quantum information can be stored in emitted single photons and transmitted in optical fibers in the future quantum internet. Image credit: HU Berlin / AG Integrierte Quantenphotonik.

Scientists are One Step Closer to Quantum Internet

Apr 6, 2023 by News Staff

A team of researchers from the Humboldt-Universität zu Berlin and the Ferdinand-Braun-Institut has succeeded in generating photons with stable frequencies...

Shoshany et al. define and analyze a new model of time travel paradoxes, which is fully compatible with all known physics; the model consists of a wormhole time machine in 3+1 spacetime dimensions, which can be either permanent (existing eternally) or temporary (activated only for a short time). Image credit: Genty.

New Quantum Breakthrough Paves Way for ‘Local Wormholes’

Mar 13, 2023 by News Staff

A local wormhole is a physical system characterized by the no-cloning of information that mediates the action of an exchange-free quantum computer: locally...

Left: a fully assembled quantum system at Google Quantum AI; prominently displayed is the dilution refrigerator in which the computations occur, the quantum processor and quantum-limited amplifiers installed at the bottom stage of the refrigerator, various cables connecting bottom to top, and control electronics of quantum computer in the back. Right: two generations of Sycamore processors fabricated by Google Quantum AI; each processor features two chips that are bonded together: a chip containing the quantum bits (qubits), and a chip containing the wiring between the qubits and the outside world; the latest generation of the Sycamore processor on the right is notably larger than previous generations, but also has several modifications to the qubits resulting in improved performance. Image credit: Google Quantum AI.

Google Quantum AI Team Improves Error Correction in Quantum Computing

Feb 23, 2023 by News Staff

A new work from Google Quantum AI represents a step towards the development of scalable quantum error correction to enable quantum computers to reach sufficiently...

Dimer model in Rydberg atoms arrays: (A) fluorescence image of 219 atoms arranged on the links of a kagome lattice; Rydberg atoms are marked with red dimers on the bonds of the kagome lattice; (B) a state consistent with the Rydberg blockade at maximal filling can then be viewed as a dimer covering of the kagome lattice, where each vertex is touched by exactly one dimer; (C) the quantum spin liquid state corresponds to a coherent superposition of exponentially many dimer coverings. Image credit: Semeghini et al., doi: 10.1126/science.abi8794.

Physicists Observe Quantum Spin Liquid for First Time

Dec 3, 2021 by News Staff

First theorized in 1973 by physicist Philip W. Anderson, quantum spin liquids are exotic phases of matter with topological order. They feature long-range...

Schematic representation of the key steps of the teleportation protocol and its verification: (1) realization of an EPR source: the Stokes scattering of a pair of nanobeams results in an entangled state between the photon polarization state and the phonon population state in the nanobeams; (2) an arbitrary input state is encoded in the polarization basis of a weak coherent state; (3) a BSM of the polarization teleports the input state onto the joint mechanical memory state; (4) a short anti-Stokes pulse maps the teleported state (ψout) back onto the photon polarization for verification. Image credit: Fiaschi et al., doi: 10.1038/s41566-021-00866-z.

Scientists Demonstrate Optomechanical Quantum Teleportation

Oct 14, 2021 by News Staff

Quantum teleportation of an unknown input state from an outside source onto a quantum node is considered one of the key components of long-distance quantum...

A schematic diagram of the quantum teleportation system consisting of Alice, Bob, Charlie, and the data acquisition (DAQ) subsystems. Image credit: Valivarthi et al., doi: 10.1103/PRXQuantum.1.020317.

Researchers Demonstrate High-Fidelity Quantum Teleportation

Dec 30, 2020 by News Staff

Quantum teleportation is essential for many quantum information technologies, including long-distance quantum networks. Using fiber-coupled devices, including...

Error-correcting Schrödinger’s cats. Image credit: Michael S. Helfenbein.

Physicists Develop Error-Correcting Schrödinger’s Cat

Aug 14, 2020 by News Staff

Physicists from the Department of Physics and the Department of Applied Physics at Yale University, the Paul Scherrer Institute and Inria Paris have developed...

3D render of the semiconductor nanostructure. Image credit: Hermann Edlbauer.

Researchers Control Quantum State of Single Electron Using High-Frequency Sound Waves

Oct 15, 2019 by News Staff

An international team of scientists sent high-frequency sound waves across a modified semiconductor device to direct the behavior of a single electron,...

Minev et al figured out how to catch and save Schrödinger’s famous cat, the symbol of quantum superposition and unpredictability. Image credit: Kat Stockton.

Physicists Find Way to ‘Catch and Save’ Schrödinger’s Cat

Jun 3, 2019 by News Staff

Schrödinger’s cat, a thought experiment envisioned by the Austrian physicist Erwin Schrödinger in 1935, is a paradox that applies the concept of superposition...

Quantum scrambling is one suggestion for how information can fall into a black hole and come out as random-looking radiation. Perhaps, the argument goes, it is not random at all, and black holes are just excellent scramblers. Image credit: E. Edwards / Joint Quantum Institute.

Physicists Use Seven-Qubit Quantum Computer to Simulate Scrambling inside Black Holes

Mar 7, 2019 by News Staff

A team of physicists from the Joint Quantum Institute, the University of Maryland, the University of California Berkeley and Perimeter Institute for Theoretical...

Changala et al used frequency combs, or ‘rulers of light,’ to observe individual quantum energy transitions in buckminsterfullerene. Image credit: Steven Burrows / JILA.

Physicists Uncover Quantum Structure of Buckminsterfullerene

Jan 29, 2019 by News Staff

A team of physicists from the Joint Institute for Lab Astrophysics (JILA) and IMRA America Inc. has measured hundreds of individual quantum energy levels...

A chip designed to operate as a 128-qubit superconducting adiabatic quantum optimization processor. Image credit: D-Wave Systems, Inc.

Physicists Demonstrate ‘Teleportation’ of Quantum Gate between Two Qubits

Sep 6, 2018 by News Staff

A team of scientists at Yale University has experimentally demonstrated one of the key steps in building the architecture for quantum computers —...

Schematic view of a large-scale quantum processor based upon phosphorus (31P) donors in silicon, operated and coupled through the use of an induced electric dipole. Idle qubits have electrons at the interface, leaving the 31P nucleus in the ultra-coherent ionized state. Electrons are partially shifted toward the donor for quantum operations. The sketch shows a possible architecture where a cluster of qubits is locally coupled via the electric dipole, and a subgroup thereof is further coupled to another cluster through interaction with a shared microwave cavity (aqua). Image credit: Guilherme Tosi, University of New South Wales.

Researchers Invent New Architecture for Quantum Computing

Sep 7, 2017 by News Staff

A new architecture, based on so-called ‘flip-flop’ qubits, allows for a silicon quantum processor that can be scaled up without the precise placement...

Sketch of the quantum Maxwell demon experiment: (A) after preparation (step 1) in a thermal or quantum state by a pulse at frequency fs, the system S (superconducting qubit) state is recorded (step 2) into the demon’s quantum memory D (microwave cavity); a pulse incoming toward port a at fD populates the cavity mode with a state ραin only if the qubit is in the ground state |g>s; this information is used to extract work W (step 3) which charges a battery B (a microwave pulse at frequency fs on port b) with one extra photon; importantly, the system emits this photon only when the demon’s cavity is empty; the work is determined by amplifying and measuring the average output power at fs on bout; the memory reset (step 4) is performed by cavity relaxation. (B) when the system starts in a quantum superposition of |g>s and |e>s, the demon and system are entangled after step 2. Image credit: Cottet et al, doi: 10.1073/pnas.1704827114.

Physicists See Maxwell’s Demon at Work

Jul 6, 2017 by News Staff

New research led by Paris Diderot University offers a view into the inner workings of the ‘mind’ of Maxwell’s demon, a famous thought experiment...