University of Tokyo, Argonne National Laboratory, Fundacion Ikerbasque, Qedma, Algorithmiq, University of Washington, University of Cologne, Harvard University, UC Berkeley, Q-CTRL demonstrate new research to explore power of utility-scale Quantum Computing.
IBM has debuted IBM Quantum Heron – the first in a new series of utility-scale quantum processors with an architecture engineered over the past four years to deliver IBM’s highest performance metrics and lowest error rates of any IBM Quantum processor to date.
IBM also unveiled IBM Quantum System Two, the company’s first modular quantum computer and cornerstone of IBM’s quantum-centric supercomputing architecture.
The first IBM Quantum System Two, located in Yorktown Heights, New York, has begun operations with three IBM Heron processors and supporting control electronics.
With this critical foundation now in place, along with other breakthroughs in quantum hardware, theory, and software, the company is extending its IBM Quantum Development Roadmap to 2033 with new targets to significantly advance the quality of gate operations.
Doing so would increase the size of quantum circuits able to be run and help to realize the full potential of Quantum Computing at scale.
“We are firmly within the era in which quantum computers are being used as a tool to explore new frontiers of science,” said Dario Gil, IBM SVP and Director of Research.
“As we continue to advance how quantum systems can scale and deliver value through modular architectures, we will further increase the quality of a utility-scale quantum technology stack – and put it into the hands of our users and partners who will push the boundaries of more complex problems.”
As demonstrated by IBM last year on a 127-qubit IBM Quantum Eagle processor, IBM Quantum systems can now serve as a scientific tool to explore utility-scale classes of problems in chemistry, physics, and materials beyond brute force classical simulation of quantum mechanics.
Since that demonstration, leading researchers, scientists and engineers from organizations including the US Department of Energy’s Argonne National Laboratory, the University of Tokyo, the University of Washington, the University of Cologne, Harvard University, Qedma, Algorithmiq, UC Berkeley, Q-CTRL, Fundacion Ikerbasque, Donostia International Physics Center and the University of the Basque Country, as well as IBM, have expanded demonstrations of utility-scale Quantum Computing to confirm its value in exploring uncharted computational territory.
This includes experiments already running on the new IBM Quantum Heron 133-qubit processor, which IBM is making available for users via the cloud.
IBM Heron is the first in IBM’s new class of performant processors with significantly improved error rates, offering a five-times improvement over the previous best records set by IBM Eagle.
Additional IBM Heron processors will join IBM’s industry-leading, utility-scale fleet of systems over the course of the next year.
IBM Quantum System Two and Extended IBM Quantum Development Roadmap
IBM Quantum System Two is the foundation of IBM’s next generation Quantum Computing system architecture. It combines scalable cryogenic infrastructure and classical runtime servers with modular qubit control electronics.
The new system is a building block for IBM’s vision of quantum-centric supercomputing. This architecture combines quantum communication and computation, assisted by classical computing resources, and leverages a middleware layer to appropriately integrate quantum and classical workflows.
As part of the newly expanded ten-year IBM Quantum Development Roadmap, IBM plans for this system to also house IBM’s future generations of quantum processors.
Also, as part of this roadmap, these future processors are intended to gradually improve the quality of operations they can run to significantly extend the complexity and size of workloads they are capable of handling.
Qiskit and Generative AI to Increase Ease of Quantum Software Programming
IBM is also detailing plans for a new generation of its software stack, within which Qiskit 1.0 will be a pivot point defined by stability and speed. Additionally, and with the goal of democratizing Quantum Computing development, IBM is announcing Qiskit Patterns.
Qiskit Patterns will serve as a mechanism to allow quantum developers to create code more easily. It is based in a collection of tools to simply map classical problems, optimize them to quantum circuits using Qiskit, executing those circuits using Qiskit Runtime, and then postprocess the results.
With Qiskit Patterns, combined with Quantum Serverless, users will be able to build, deploy and execute workflows integrating classical and quantum computation in different environments, such as cloud or on-prem scenarios.
All of these tools will provide building blocks for users to build and run quantum algorithms more easily.
Additionally, IBM is pioneering the use of generative AI for quantum code programming through watsonx, IBM’s enterprise AI platform.
IBM will integrate generative AI available through watsonx to help automate the development of quantum code for Qiskit. This will be achieved through the finetuning of the IBM Granite model series.
“Generative AI and Quantum Computing are both reaching an inflection point, presenting us with the opportunity to use the trusted foundation model framework of watsonx to simplify how quantum algorithms can be built for utility-scale exploration,” said Jay Gambetta, Vice President and IBM Fellow at IBM.
“This is a significant step towards broadening how Quantum Computing can be accessed and put in the hands of users as an instrument for scientific exploration.”
With advanced hardware across IBM’s global fleet of 100+ qubit systems, as well as easy-to-use software that IBM is debuting in Qiskit, users and computational scientists can now obtain reliable results from quantum systems as they map increasingly larger and more complex problems to quantum circuits.