Major Breakthrough As Quantum Computing in Silicon Hits 99% Accuracy

Serwan Asaad, Andrea Morello and Mateusz Mądzik

L-R Asaad, Morello, Madzik (composite image): Serwan Asaad, Andrea Morello, and Mateusz Mądzik are lead authors of the UNSW paper which demonstrated 99 percent error-free quantum operations. Credit: Kearon de Clouet / UNSW

UNSW Sydney-led research paves the way for large silicon-based quantum processors for real-world manufacturing and application.

Australian researchers have proven that near error-free quantum computing is possible, paving the way to build silicon-based quantum devices compatible with current semiconductor manufacturing technology.

Today’s publication in Nature shows our operations were 99 percent error-free,” says Professor Andrea Morello of UNSW, who led the work.

Silicon Quantum Electronic Device

The silicon nanoelectronic device used to hold the quantum processor was built using methods compatible with industry standards for existing computer chips. (The authors demonstrated universal quantum logic operations using a pair of ion-implanted 31P nuclei in a silicon nanoelectronic device. The device is manufactured using methods compatible with the industry-standard processes used for all existing computer chips.) Credit: Tony Melov / UNSW

“When the errors are so rare, it becomes possible to detect them and correct them when they occur. This shows that it is possible to build quantum computers that have enough scale, and enough power, to handle meaningful computation.”

This piece of research is an important milestone on the journey that will get us there,” Prof. Morello says.

Quantum computing in silicon hits the 99% threshold

Morello’s paper is one of three published today in Nature that independently confirm that robust, reliable quantum computing in silicon is now a reality. This breakthrough features on the front cover of the journal.

  • Morello et al achieved 1-qubit operation fidelities up to 99.95 percent, and 2-qubit fidelity of 99.37 percent with a three-qubit system comprising an electron and two phosphorous atoms, introduced in silicon via ion implantation.
  • A Delft team in the Netherlands led by Lieven Vandersypen achieved 99.87 percent 1-qubit and 99.65 percent 2-qubit fidelities using electron spins in quantum dots formed in a stack of silicon and silicon-germanium alloy (Si/SiGe).
  • A RIKEN team in Japan led by Seigo Tarucha similarly achieved 99.84 percent 1-qubit and 99.51 percent 2-qubit fidelities in a two-electron system using Si/SiGe quantum dots.
Three Qubit Quantum Processor

A visualization of UNSW’s three-qubit system, which can perform quantum logic operations with over 99% accuracy. (Quantum operation fidelities above 99% were obtained in a three-qubit silicon quantum processor. The first two qubits (Q1, Q2) are the nuclear spins of individually-implanted phosphorus atoms (red spheres). The third qubit (Q3) is the spin of an electron that wraps around both nuclei (shiny ellipse).) Credit: Tony Melov / UNSW

The UNSW and Delft teams certified the performance of their quantum processors using a sophisticated method called gate set tomography, developed at Sandia National Laboratories in the U.S. and made openly available to the research community.

Morello had previously demonstrated that he could preserve quantum information in silicon for 35 seconds, due to the extreme isolation of nuclear spins from their environment.

Entangled Three-Qubit System

The three qubits can be prepared in a quantum entangled state, which unlocks the exponential power of quantum computers. (Nuclear spins are exceptionally good qubits, because of their exceptional isolation from the environment. This same feature, however, makes it difficult for them to interact and perform quantum logic operations. The team’s breakthrough consists in using a common electron to mediate the interaction, leading to high-fidelity universal quantum logic operations. Furthermore, the electron itself is a high-quality qubit, and can be placed in a fully quantum-entangled state with the two nuclei.) Credit: Tony Melov / UNSW

“In the quantum world, 35 seconds is an eternity,” says Prof. Morello. “To give a comparison, in the famous Google and IBM superconducting quantum computers the lifetime is about a hundred microseconds – nearly a million times shorter.”

But the trade-off was that isolating the qubits made it seemingly impossible for them to interact with each other, as necessary to perform actual computations.

Nuclear spins learn to interact accurately

Today’s paper describes how his team overcame this problem by using an electron encompassing two nuclei of phosphorus atoms.

“If you have two nuclei that are connected to the same electron, you can make them do a quantum operation,” says Dr. Mateusz Madzik, one of the lead experimental authors.

Scaling Up Silicon Quantum Processor

The three-qubit system paves the way to scaling up the quantum processor in the future, because the electron can be easily entangled with other electrons or moved across the chip. (The three-qubit entangled state of nuclei and electron paves the way to scaling up the quantum processor in the future. The electron can be easily entangled with other electrons, or physically moved across the chip. In this way, the UNSW team will be able to manufacture and operate large arrays of qubits capable of robust and useful computations.) Credit: Tony Melov / UNSW

“While you don’t operate the electron, those nuclei safely store their quantum information. But now you have the option of making them talk to each other via the electron, to realize universal quantum operations that can be adapted to any computational problem.”

“This really is an unlocking technology,” says Dr. Serwan Asaad, another lead experimental author. “The nuclear spins are the core quantum processor. If you entangle them with the electron, then the electron can then be moved to another place and entangled with other qubit nuclei further afield, opening the way to making large arrays of qubits capable of robust and useful computations.”

Serwan Asaad

Serwan Asaad, one of the lead authors. Credit: UNSW

David Jamieson, research leader at the University of Melbourne, adds: “The phosphorous atoms were introduced in the silicon chip using ion implantation, the same method used in all existing silicon computer chips. This ensures that our quantum breakthrough is compatible with the broader semiconductor industry.”

All existing computers deploy some form of error correction and data redundancy, but the laws of quantum physics pose severe restrictions on how the correction takes place in quantum computer. Prof. Morello explains: “You typically need error rates below 1 percent, to apply quantum error correction protocols. Having now achieved this goal, we can start designing silicon quantum processors that scale up and operate reliably for useful calculations.”

About the three papers

Semiconductor spin qubits in silicon are well-placed to become the platform of choice for reliable quantum computers. They are stable enough to hold quantum information for long periods and can be scaled up using techniques familiar from existing advanced semiconductor manufacturing technology.

Mateusz Mądzik

Mateusz Mądzik, one of the lead authors. Credit: UNSW

“Until now, however, the challenge has been performing quantum logic operations with sufficiently high accuracy,” Prof. Morello says.

“Each of the three papers published today shows how this challenge can be overcome to such a degree that errors can be corrected faster than they appear.”

  • The UNSW team led by Andrea Morello created two-qubit universal quantum logic operations between two nuclear spins formed by phosphorous donors, introduced in silicon via the industry-standard method of ion implantation. The quantum operations involved an electron, whose probability wave is spread across both nuclei. The individual nuclei operated with fidelities up to 99.95%, and two-qubit operations with 99.37% fidelity, as certified by gate set tomography (GST). The electron spin is itself a qubit, which can be entangled with the two nuclei to create a three-qubit quantum entangled state, with fidelity of 92.5%.
    Paper: https://www.nature.com/articles/s41586-021-04292-7; DOI: https://doi.org/10.1038/s41586-021-04292-7
  • The Delft team led by Lieven Vandersypen created a two-qubit system in a material made from a carefully grown stack of silicon and silicon-germanium alloy (Si/SiGe). The quantum information is encoded in the spins of electrons confined in quantum dots. They applied gate set tomography not only to quantify, but also to improve the accuracy of the quantum operations and reached 99.5 percent fidelity on the two-qubit logic gate. “Pushing the two-qubit gate fidelity well beyond 99 percent required improved materials and specially designed qubit control and calibration methods,” Xiao Xue, lead author of the publication in Nature, said.
    Paper: https://doi.org/10.1038/s41586-021-04273-w
  • The RIKEN group in Tokyo, led by Seigo Tarucha, one of the founders of the field of quantum dots, took a similar path, creating two electron quantum bits in Si/SiGe using the same material stack produced by the Delft group. They achieved single-qubit fidelities of 99.8% and two-qubit fidelity of 99.5 percent with very fast electrical operations. They measured the fidelity using randomized benchmarking.
    Paper: https://www.nature.com/articles/s41586-021-04182-y; DOI: https://doi.org/10.1038/s41586-021-04182-y

Collaborations and exchanges

While the three papers report independent results, they illustrate the benefits that arise from free academic research, and the free circulation of ideas, people and materials. For instance, the silicon and silicon-germanium material used by the Delft and RIKEN groups was grown in Delft and shared between the two groups. The isotopically purified silicon material used by the UNSW group was provided by Kohei Itoh, from Keio University in Japan.

The gate set tomography (GST) method, which was key to quantifying and improving the quantum gate fidelities in the UNSW and Delft papers, was developed at Sandia National Laboratories in the US, and made publicly available. The Sandia team worked directly with the UNSW group to develop methods specific for their nuclear spin system, but the Delft group was able to independently adopt it for its research too.

There has also been significant sharing of ideas through the movement of people between the teams, for example:

  • Mateusz Madzik, an author on the UNSW paper, is now a postdoctoral researcher with the Delft team.
  • Serwan Asaad, an author on the UNSW paper, was formerly a student at Delft.
  • Lieven Vandersypen, the leader of the Delft team, spent a five-month sabbatical leave at UNSW in 2016, hosted by Andrea Morello.
  • The leader of the material growth team, Giordano Scappucci, is a former UNSW researcher.

The UNSW-led paper is the result of a large collaboration, involving researchers from UNSW itself, University of Melbourne (for the ion implantation), University of Technology Sydney (for the initial application of the GST method), Sandia National Laboratories (Invention and refinement of the GST method), and Keio University (supply of the isotopically purified silicon material).

Authors

Mateusz T. Madzik1,2, Serwan Asaad1,2, Akram Youssry3,4, Benjamin Joecker1,2, Kenneth M. Rudinger5, Erik Nielsen5, Kevin C. Young5, Timothy J. Proctor5, Andrew D. Baczewski6, Arne Laucht1,2, Vivien Schmitt1,2, Fay E. Hudson1, Kohei M. Itoh7, Alexander M. Jakob8,2, Brett C. Johnson8,2, David N. Jamieson8,2, Andrew S. Dzurak1, Christopher Ferrie3, Robin Blume-Kohout5, and Andrea Morello1,2

Organisations

1 School of Electrical Engineering and Telecommunications, UNSW Sydney, Australia
2 Centre for Quantum Computation and Communication Technology, Australia
3 University of Technology Sydney
4 Ain Shams University, Cairo, Egypt
5 Sandia National Laboratories, Albuquerque and Livermore, USA
6 Center for Computing Research, Sandia National Laboratories, Albuquerque, NM 87185, USA
7 School of Fundamental Science and Technology, Keio University, Kohoku-ku, Yokohama, Japan
8 School of Physics, University of Melbourne, Melbourne, VIC 3010, Australia

Funding acknowledgment

The UNSW-UTS consortium was created as part of the AUSMURI Project, a multi-university Australia-US initiative, funded in Australia through the Defence Department’s Next Generation Technologies Fund. The AUSMURI project aims at using multi-qubit systems to reduce the overall quantum gate errors. This result is a key breakthrough in the direction of high-fidelity quantum processors in silicon.

Further funding came from the US Army Research Office, whose silicon quantum computing initiative supports UNSW, Melbourne, and Sandia National labs.

The ARC Centre of Excellence for Quantum Computation and Communication Technology supported the work at UNSW and Melbourne. The quantum device was fabricated using facilities in the UNSW node of the Australian National Fabrication Facility (ANFF).

Work at Delft was supported by the Dutch Government, and by the US Army Research Office, through the same scheme supporting the UNSW work.

The work at RIKEN was funded through several Japan government grants.

5 Comments on "Major Breakthrough As Quantum Computing in Silicon Hits 99% Accuracy"

  1. Phawat Sridechabowon | January 19, 2022 at 8:39 am | Reply

    Let’s take a look at the new document discussing parts of the original system and the analogy of looking at the problem in a nutshell.

  2. BRIAN Edward CRONER | January 19, 2022 at 12:27 pm | Reply

    One or two qubits? C’mon man.

  3. I searched this article for the words: Temperature, cryogenics, cooling ect. The only time superconductivity is used is in reference to the Google quantum computer. Does this think-box use cryo?

  4. How do you access fifth and sixth dimensional physics. You use an electron quantum physics Matrix. By going small you jump up

  5. If these quantum dots are built in planar systems, its seems the interactions are along the linear interfaces between dots – does this 1-d topology limit the number of qubits that can be in play at once? jr

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