“It’s an exciting time – our quantum computers can now probe complex phenomena that are challenging to capture with even the most sophisticated classical algorithms”, concluded Dr. Michael Foss-Feig.
Read more here: https://t.co/OreXMdWqDQ
We’re proud to share that our recent research on quantum magnetism has been published in @Nature, one of the world’s most prestigious scientific journals.
Read the scientific paper:
https://t.co/OreXMdWqDQ
In collaboration with @Caltech, Fermioniq, @EPFL, and the @TU_Muenchen, we were able to push the boundaries of quantum simulation using our System Model H2 quantum computer.
Read the scientific paper:
https://t.co/0cL5sNJzkZ
This work marks a shift away from narrowly defined “quantum advantage” experiments toward meaningful problems for future materials and devices where quantum computing has a tangible impact.
Last year, with @Microsoft, we published a breakthrough in logical computing, demonstrating logical qubits that outperformed physical qubits by a factor of 800. This work is now published in @Nature, one of the most highly regarded scientific journals. https://t.co/o4Z33J7fK3
Today, Quantinuum officially begins trading on NASDAQ under the ticker symbol QNT.
Today’s milestone is the direct result of the dedication of our team, trust of our partners, and support of the entire quantum community.
Thanks to everyone who helped us reach this historic day.
We invite applications from those with backgrounds in:
🧪 Chemistry
💎 Materials science
💻 Computer science
🧬 Computational biology
⚛ Condensed matter physics
🖥️ Computational physics
📐 Mathematics
Please find the full information, including application details, prices and an indicative programme, at: https://t.co/Vgt6xEey98
Introducing the InQuanto Summer School for Quantum Computational Chemists!
We’re pleased to announce dates for the inaugural InQuanto Summer School, taking place this September in Cambridge, UK -- September 14th - 18th, and registration is now open:
https://t.co/Vgt6xEey98
@nqcc_official The School is designed to:
1. Consolidate fundamentals in quantum computing and quantum chemistry
2. Jump-start participants’ work in a supportive environment
3. Foster cross-disciplinary collaborations
https://t.co/zjsOPjc06M
With 64 of our logical qubits, we were able to simulate quantum magnetism at a scale that can be exceedingly difficult for classical computers.
Read more in our blogpost here: https://t.co/UZyZ6yFYef
We’ve cut the qubit tax in time for tax season!
We’ve taken a big step toward large scale fault-tolerant quantum computing, squeezing 94 error-detected & 48 error-corrected qubits out of 98 physical qubits, an encoding that turns overhead into headroom.
https://t.co/ekYa1bjEQA
This marks a significant milestone for Quantinuum, and the ecosystem at large: a practical step from “connected hardware” to “usable hybrid compute” for real science.
Read more in our blogpost here: https://t.co/Mv4YF6JP2z
We’ve demonstrated an end-to-end hybrid workflow linking the Fugaku supercomputer & the Quantinuum Reimei quantum computer.
For the first time, they operate together as an integrated, end-to-end research platform running a complete scientific workflow.
https://t.co/Mv4YF6JP2z
Using a layered modeling approach to biochemistry, the classical supercomputer handled the large-scale environment, while the quantum device enhanced the treatment of the challenging electronic effects in the molecular “active site” - the part that most limits accuracy in biomolecular reaction simulation.
Read the scientific paper: https://t.co/4PSI416Syy