The 𝐆𝐞𝐧𝐞𝐬𝐢𝐬 𝐌𝐢𝐬𝐬𝐢𝐨𝐧 announced by @WhiteHouse and led by @ScienceUnderSec is a landmark moment for the global scientific community and a powerful signal that computer-led scientific discovery has entered a new era.
Today, we launched Helios, a technological marvel redefining the possible. Helios is the most accurate quantum computer in the world, with 98 of the highest fidelity physical qubits ever released, and 48 error-corrected logical qubits.
Learn more: https://t.co/pkvTsS9poF
Some thoughts on the recent Quantinuum magic state experiments: https://t.co/nHhgePYVOv https://t.co/zggjroNUuy (Disclaimer: I am a coauthor of the second paper.)
We tested a pre-release version of o3 and found that it frequently fabricates actions it never took, and then elaborately justifies these actions when confronted.
We were surprised, so we dug deeper 🔎🧵(1/)
https://t.co/IdBboD7NsP
Exciting progress from our partnership with RIKEN, Japan’s top research institute and operator of the Fugaku supercomputer.
A new paper in Physical Review Research marks the first big result from our quantum-HPC collaboration: researchers from RIKEN, Quantinuum, and Keio University showed how quantum information can be “scrambled” using a special quantum circuit.
This insight could deepen our understanding of quantum chaos, thermalization—and even black holes. Read more in our blog post here: https://t.co/5An9Li8tXc
Read the paper here: https://t.co/LKK2TsxRej
A thread on knots.
Every knot K has a corresponding Jones polynomial V(t), a Laurent polynomial in one complex variable.
Computing the Jones is hard.
The Jones is a knot invariant:
if V neq V', then K and K' are topologically inequivalent.
1/6
@newscientist covers our work at @QuantinuumQC on pushing both quantum and classical algorithms for a famous problem in knot theory: evaluating the Jones polynomial. This problem is quantum native and, therefore, a good candidate for exhibiting exponential quantum advantage.
This is what it is like to drive a huge American SUV in a Japanese city.
This clip is being shared in response to the Trump administration's claims that Japanese aren't buying enough American cars because of unfair trade barriers.
A fair comparison of classical and quantum algorithms to simulate quantum matter. A specific physics problem running on Quantinuum System Model H2 shows the reliability of quantum computing when classical techniques are failing.
Exciting times ahead!
Quantum breakthrough: Quantinuum’s System Model H2 demonstrates powerful capabilities in simulating quantum magnetism, pushing beyond classical computing limits. Is quantum computing now the new gold standard for material science simulations? https://t.co/X67X3YVzqU
We’re marking a major milestone in the intersection of AI and quantum computing with our latest paper, published in partnership with @GoogleDeepMind, in @NatMachIntell.
Read more in our blogpost here: https://t.co/siIjOFOZ0h
A poster at a train station in Tokyo warns against unconscious bias:
The speaker is assuming the transfer student isn't Japanese based on their physical appearance and praising his Japanese ability. If he was born and raised in Japan, this compliment could hurt his feelings.
As the only quantum computing company with a quantum computer powerful enough that it can't be simulated, Quantinuum has published a unique and highly influential paper on an end-to-end quantum algorithm that only a quantum computer can solve efficiently. https://t.co/Q46qLam6K4
🥇Announcing the 1st commercial application for quantum computers!
Quantinuum, along with our partners JPMorganChase, @Argonne, @ORNL, and @UTAustin, have turned our quantum computer into a reliable and accessible source of high-quality randomness.
🔗https://t.co/cThUiu3Oc5
Developing quantum algorithms involves combining well-crafted building blocks, much like building a house entails setting the foundation, framing the structure, and adding a roof. https://t.co/2jCfp0xivV