Despite the funding and safety protocols that have slowed down R&D in various scientific fields except for COVID-19-related work this year due to the current COVID-19 pandemic, federal governments around the world have kept quantum projects on-track.

“‘Quantum’ has not slowed down—there were a lot of research initiatives announced this summer and [our project] is a program to support quantum education,” says Emily Edwards of the University of Illinois at Urbana-Champaign, co-principal investigator of Q2Work, a program funded by the US National Science Foundation.

Anna Grassellino, director of Fermilab's Superconducting Quantum Materials and Systems Center (SQMS), and David Awschalom, director of Argonne National Laboratory's Next Generation Quantum Science and Engineering Center (Q-NEXT), each began receiving funds for their quantum centers. The US Department of Energy announced this summer that they will provide USD$625 million over five years to fund five National Quantum Information Science Research Centers, including SQMS and Q-NEXT.

In the UK, Dominic O'Brien, director, and David Lucas, principal investigator, head up the UK Quantum Computing & Simulation Hub, which began its five-year program at the end of 2019. The Hub is a collaboration of 17 universities and more than 25 industrial and government partners and is led by the University of Oxford. The current Hub was preceded by the Networked Quantum Information Technologies Hub (NQIT), which ran from 2014 to 2019.

The UK focuses its quantum initiative on technology, launching the UK National Quantum Technologies Programme in 2013. From 2014 to 2019, UK Research and Innovation invested £120 million (∼USD$156 million) for four quantum technology hubs managed by the Engineering and Physical Sciences Research Council. The four hubs then received £94 million (∼USD$122 million) for the next five years comprising the second phase.

David Awschalom, a physicist at the University of Chicago and Argonne National Laboratory, reviews data from a quantum information experiment with a graduate student in his laboratory. Credit: University of Chicago.

Tadashi Sakai, R&D manager of Q-LEAP's (Quantum Leap Flagship Program) Quantum Metrology & Sensing, a 10-year program in Japan commissioned by the Government of Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT), says, “Following the government's state of emergency [due to COVID-19], we were forced to refrain from activities for about two months. During that time, we stopped experiments. It is now back to almost normal activity levels.”

In its FY 2020 budget highlights released earlier this year, MEXT includes ¥3.2 billion (∼USD$30 million) for its Q-LEAP initiative. This represents an increase by ¥1 billion (∼USD$9.5 million) from FY 2019 and exemplifies Japan's 10-year Fifth Science and Technology Basic Plan known as Society 5.0 (approved by the Japanese Cabinet in January 2016). In Society 5.0, the government's emphasis is on an “inclusive society” that values knowledge and information, versus the capital-intensive society of the 20th century.

When the Q-LEAP initiative was adopted in 2018, it focused on three general areas: quantum information technology (quantum simulator, quantum computer), quantum metrology and sensing, and the next-generation laser.

These are just a few examples of the quantum science megaprojects that have taken off globally.

“Quantum has been funded before for computing, Internet, sensors, but has never been pushed to this level of bringing together academia and all the stakeholders,” Grassellino tells MRS Bulletin, referring to the US initiative. “I see this is important now to accelerate [R&D]. Either we're going to be serious about it or progress is going to be too slow.”

Since the US government signed the US National Quantum Initiative Act into law at the end of 2018, it has authorized just over USD$1.2 billion for the first five years (starting in fiscal year 2019), spread across the National Institute of Standards and Technology (USD$80 million), the National Science Foundation (NSF) (USD$10 million), and the US Department of Energy (DOE) (USD$25 million). All three already have quantum programs in place (see MRS Bulletin, doi:10.1557/mrs.2019.49).

This summer, the White House Office of Science and Technology Policy (OSTP) partnered with DOE to further quantum materials education and research.

In response to the OSTP/DOE partnership, Awschalom tells MRS Bulletin, “When this intriguing opportunity arose, our team began to identify the most important challenges of quantum information science that could not be easily addressed by a single group and that, if overcome, would revolutionize the field.”

One of the challenges they chose to address is developing the science and technology to control and distribute quantum information across distances ranging from microns to kilometers. “We felt that if you don't produce these types of quantum connections it will be difficult to develop many practical quantum technologies. When you build quantum sensors you need to connect them to quantum machines within an ecosystem that is entirely quantum mechanical,” Awschalom says.

Oxford-built ion trap with a single strontium ion-qubit held at the center. Credit: David Nadlinger, winner of the UK science photo competition 2018.

To build a communication network, researchers need to link quantum sensors and computers together, he says. For example, a significant level of quantum communication is required to build a quantum supercomputer. “We realized that in order to create and control quantum information with these quantum connections you need the appropriate materials as a basis to build the technology, and that meant we need to create foundries,” Awschalom says.

In order to create standardized, characterized high-quality materials for quantum science and technology, Q-NEXT will focus on scaling synthesis and integration of qubits for both semiconducting- and superconducting-based materials for quantum devices and systems. To do so, the Center will create two national quantum foundries, one for solid-state materials at Argonne National Laboratory west of Chicago, and one for superconducting materials at the SLAC National Accelerator Laboratory in California. “The foundries will produce well-characterized quantum materials and devices to support the broad national quantum initiative for the community,” Awschalom says.

Awschalom and his team developed the plan for these foundries working alongside 10 industry partners of Q-NEXT. He likens the materials that these foundries will deliver to the wafers that today's semiconductor companies use to fabricate their own devices. “We need quantum factories that will enable the development of quantum science and technology from sensing to communication to computing. This capability is currently lacking in the United States,” he says.

At the Quantum Computing & Simulation Hub in the UK, researchers are concentrating on a wide range of computing and simulation platforms including ion trap and silicon processors, superconductors, diamond nitrogen-vacancy (NV) centers, cold atoms, and photonics. On the software side, they are focused on applications, algorithms, architecture, verification and benchmarking, and on the fundamentals of quantum computers.

O'Brien says, “At present there is no clear winning platform that will ultimately lead to a widely usable quantum computer.” Taking a broad view also has other advantages, he tells MRS Bulletin: “Working across platforms allows you to learn from one platform to another. For example, error reduction is a challenge for all of the computing platforms and there may be techniques which cross over.”

Lucas says, “With the current 1% error rate, we're unable to achieve a quantum computer….We need a large number of qubits to tolerate a high error rate.” He tells MRS Bulletin that the more mature approaches are superconducting qubits and trapped-ion qubits. For the superconducting platform, such as used by Google and IBM, it may be easier to scale up the system. With trapped-ion qubits, as used by Honeywell and IonQ, he says, “there are fewer qubits under good control, but they are higher precision qubits.”

Other consortiums focus on one platform. “The Flagship Project of Q-LEAP Quantum Metrology & Sensing aims at ultrasensitive magnetic sensors using diamond, and focuses on diamond's NV defect control,” says Sakai of the Tokyo Institute of Technology. The advantage for this platform in developing solid-state quantum sensors is that spin coherence is good at room temperature and quantum states can be initialized and read out by light.

At Fermilab's SQMS Center, the focus is on the superconductivity platform. “The key problem that we try to overcome is quantum coherence for the lifetime of the qubit,” Grassellino says. “The lifetime fully depends on how long the photon can live inside of a cavity or the transmon qubit before the quantum state gets destroyed or the photon gets absorbed. That depends on the material we use.”

The superconducting two-dimensional transmon qubit is being used by Google and IBM where the qubit lifetime lasts for tens of microseconds. “We'll be building a quantum computer using the 3D [three-dimensional] superconducting architecture,” Grassellino says, which is based on their ultrahigh-quality-factor (ultrahigh-q) 3D resonator. One of the major partners in the consortium is Rigetti Computing. “From Rigetti, we'll receive hundreds of qubits that Fermi will distribute to the different research groups,” she says, from which they will be able to analyze materials properties. At Fermilab, researchers will insert the Rigetti qubit inside their 3D device to study how they will preserve the lifetime of the quantum state inside the cavity.

“Our vision after five years is to be a national user facility,” Grassellino says. “One of the things we want to build is a materials test bed where materials to be employed for quantum can be started in the most sensitive environment.”

Another outcome of Q-NEXT, says Awschalom, is a quantum devices database. “The database will be available to the scientific community and will serve as a collection of benchmarks and references for different materials of relevance to quantum technology,” Awschalom says. “It will serve as a resource for both theorists and experimentalists who will have access to the latest materials and device performance parameters and references.”

In 1992, when Awschalom received the Outstanding Young Investigator Award from the Materials Research Society (MRS), he presented a talk on “Spin dynamics and tunneling in quantum magnetic systems” (see the award announcement in MRS Bulletin, doi:10.1557/S0883769400041129). At the time, quantum science was just barely entering the materials research realm. “I think what's changed are advances in our understanding of the underlying science, materials research, and measurement techniques that are relevant to quantum technology. Taken together, these accomplishments have pushed forward new ways to create and control quantum states in broad classes of materials,” Awschalom says. “More mature quantum systems have emerged that are driving science and technology, enabling scientists and engineers to prototype devices and identify powerful materials platforms.”

Scientist Alex Romanenko holds up a small superconducting radio-frequency (SRF) cavity in Fermilab's Quantum Laboratory. Fermilab specializes in SRF cavities for particle physics and is now extending their applications into the world of quantum science. Credit: Reidar Hahn, Fermilab.

“To build a national resource focusing on pristine materials for quantum science and technology is an extraordinary opportunity for the national labs, universities, and industries—we all need access to these materials,” he says.

O'Brien and Lucas at the UK Hub agree. The UK initiative incorporates the technology component. “Research in universities and national labs has matured to a point of more and more industry interest and investment interest with no sign of progress slowing down,” Lucas tells MRS Bulletin.

At the Hub, specific mechanisms are in place to work with industry. Events are held at which early-career researchers can learn about career opportunities in quantum information science. Similarly the DOE centers are developing workforce programs that introduce students to research opportunities in industry.