IBM Launches Most Advanced Quantum Computers, Fueling New Scientific Value and Progress towards ....
IBM announced quantum
hardware and software advancements to execute complex algorithms on IBM quantum computers
with record levels of scale, speed, and accuracy.
IBM Quantum
Heron, the company's most performant quantum processor
to-date and available in IBM's global quantum data centers, can now leverage
Qiskit to accurately run certain classes of quantum circuits with up to 5,000
two-qubit gate operations. Users can now use these capabilities to expand
explorations in how quantum computers can tackle scientific problems across
materials, chemistry, life sciences, high-energy physics, and more.
This continues
the achievement of milestones on IBM's Quantum Development
Roadmap, and
further advances the era of quantum utility as IBM and its partners progress
towards quantum advantage and IBM's advanced, error-corrected system planned
for 2029.
The combined
improvements across IBM Heron and Qiskit can execute certain mirrored kicked
Ising quantum circuits of up to 5,000 gates, which is nearly twice the number
of gates accurately run in IBM's 2023 demonstration of quantum
utility. This
work further extends the performance of IBM's quantum computers beyond the
capabilities of brute-force classical simulation methods. The 2023 utility
experiment, published in Nature, demonstrated the speed
results in terms of time to process, per data point, which totaled 112 hours.
The same experiment, using the same data points, was run on the latest IBM
Heron processor and can be completed in 2.2 hours, which is 50 times faster.
IBM has further
evolved Qiskit into the world's most performant quantum software to allow
developers to more easily build complex quantum circuits with stability,
accuracy, and speed. This is evidenced by results gathered
and published on arXiv.org using Benchpress, an open-source
benchmarking tool which IBM used to measure Qiskit across 1,000 tests, largely
from third parties, and found it to be the highest-performing, most reliable
quantum software development kit against other selected platforms.
"Advances
across our hardware and Qiskit are enabling our users to build new algorithms
in which advanced quantum and classical supercomputing resources can be knit
together to combine their respective strengths," said Jay Gambetta, Vice President, IBM
Quantum. "As we advance on our roadmap towards error-corrected quantum
systems, the algorithms discovered today across industries will be key to
realizing the potential to solve new problems realized through the convergence
of QPUs, CPUs, and GPUs."
New Software Tools to Advance Development of Next-Generation
Algorithms
The IBM
Quantum Platform is further expanding options with new Qiskit services
such as generative AI-based capabilities and software from IBM partners,
allowing a growing network of experts across industries to build
next-generation algorithms for scientific research.
This includes
tools such as the Qiskit Transpiler Service to
power the efficient optimization of quantum circuits for quantum hardware with
AI; Qiskit Code Assistant to
help developers generate quantum code with IBM Granite-based generative AI
models; Qiskit Serverless to
run initial quantum-centric supercomputing approaches across quantum and
classical systems; and the IBM Qiskit Functions
Catalog to make services available from IBM, Algorithmiq, Qedma,
QunaSys, Q-CTRL, and Multiverse Computing for capabilities such
as reducing the performance management of quantum noise, as well as abstracting
away the complexities of quantum circuits to simplify the development of
quantum algorithms.
"Algorithmiq's
tensor error network mitigation algorithm (TEM), available through the IBM
Qiskit Functions Catalog, offers state-of-the-art error mitigation for circuits
at utility scale by leveraging steps towards quantum-centric supercomputing
approaches, delivering the fastest quantum runtime we've yet offered to
users," said Matteo Rossi, CTO, Algorithmiq. "With the recent advancements
we've made to combine quantum computers with post-processing on GPUs, we are
pushing TEM's capabilities to support circuits with up to 5,000 entangled
quantum gates – a milestone for scaling quantum experiments and tackling
complex problems. This could open the door to quantum simulations and
computations previously constrained by noise limitations."
"Progress
across IBM quantum hardware and software are instrumental to Qedma's mission to
build services that will allow our users to run the longest and most complex
quantum circuits," said Dorit Aharonov, Chief Scientific Officer, Qedma. "Combined with our own
achievements in error mitigation, which we offer via Qedma's service in the IBM
Qiskit Functions Catalog, we look forward to furthering our mission of enabling
global users to build algorithms with today's quantum systems – and to achieve
increasingly accurate results of scientific value."
Qiskit Fuels Quantum and Classical Integration Towards Future of Computing
As the next
evolution of high-performance computing, IBM's vision of quantum-centric
supercomputing aims to integrate advanced quantum and classical computers
executing parallelized workloads to easily break apart complex problems with
performant software, allowing each architecture to solve parts of an algorithm
for which it is best suited. Such software is being designed to seamlessly and
quickly knit problems back together, allowing algorithms to be run that are
inaccessible or difficult for each computing paradigm on its own.
RIKEN, a
national scientific research institute in Japan, and Cleveland Clinic, a leading academic medical center and
biomedical research institution with an on-site and utility-scale IBM Quantum
System One, are exploring algorithms for electronic structure problems that are
fundamental to chemistry.
These
initiatives represent the first steps towards quantum-centric supercomputing
approaches to realistically model complex chemical and biological systems, a
task historically believed to require fault-tolerant quantum computers.
Early examples
of these types of workflows are methods based on parallel classical processing
of individual samples from quantum computers. Building on prior
techniques, such as QunaSys's QSCI method, IBM and RIKEN
researchers have performed sample-based quantum diagonalizations in
quantum-centric supercomputing environments, which make use of quantum hardware
to accurately model the electronic structure of iron sulfides, a compound present
widely in nature and organic systems.
Now available
as a deployable Qiskit service, this same technique is being leveraged by
Cleveland Clinic to explore how it could be used to implement
quantum-centric simulations of noncovalent interactions: bonds between
molecules that are essential to many chemical, biological, and pharmaceutical science
processes.
"This
research is an example of what makes our research partnership successful –
bringing together IBM's next-generation technologies with Cleveland Clinic's
world-renowned expertise in healthcare and life sciences," said Lara Jehi,
MD, Chief Research Information Officer at Cleveland Clinic. "Together, we
are pushing through traditional scientific boundaries using cutting-edge
technology such as Qiskit to advance research and find new treatments for
patients around the globe."
"With our
partners at IBM, we were able to leverage their advanced quantum computing
electronic structure algorithm to study – for the first time – intermolecular
interactions on the on-site IBM Quantum System One at Cleveland Clinic, which
are important for potential future applications in drug discovery and
design," said Kennie Merz, PhD and quantum molecular scientist at Cleveland Clinic.
"The RIKEN
Center for Computational Science (R-CCS) is conducting the Japan High
Performance Computing-Quantum (JHPC-Quantum) project, which aims to build a
quantum-HPC hybrid computing platform by integrating our supercomputer, Fugaku,
with an on-premises IBM Quantum System Two powered by an IBM Quantum Heron
processor. In the era of quantum utility, we will strongly support the initiative's
goal of demonstrating quantum-centric supercomputing approaches by using our
platform as a first step towards this new computing architecture," said
Mitsuhisa Sato, the director of Quantum-HPC Hybrid Platform Division, RIKEN
Center for Computational Science.
Additionally, Rensselaer Polytechnic Institute is using Qiskit
tools to take initial steps to build IBM's first realization of quantum-centric
supercomputing on a university campus. With performant software, RPI and IBM
are aiming to successfully connect workloads across the AiMOS classical
supercomputer and IBM Quantum System One, both located on RPI's campus, into a
single computational environment managed by a standard high-performance
computing resource manager.
"Since
unveiling IBM Quantum System One on the RPI campus earlier this year, we have
taken steps toward another significant first by starting the work to link the
quantum system and our AiMOS supercomputer," said Martin A. Schmidt, Ph.D., president of RPI.
"This moment is a testament to our longstanding partnership with IBM, and,
like the pairing of quantum computing and supercomputing, our two institutions
together will drive exciting breakthroughs in the years to come."
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