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Researchers created the first quantum circuit with logical qubits, marking a significant stride toward reliable, scalable quantum computing

Their innovative use of Rydberg atoms as logical qubits overcame previous limitations in quantum error correction

Unique properties of Rydberg qubits strongly position them as a platform for building large-scale quantum processors

DARPA’s decades of investments into quantum science provided crucial knowledge enabling this breakthrough

While more work remains, this marks a watershed moment clearly charting the course to quantum supremacy

Logical Qubits: DARPA Unlocks the Pathway to Scalable Quantum Computing

A watershed moment has arrived for quantum computing. In a major breakthrough, researchers funded by the Defense Advanced Research Projects Agency (DARPA) have created the first quantum processor using logical qubits (Arute et al., 2023). By overcoming a key limitation in quantum error correction, this discovery promises to accelerate the advent of reliable, scalable quantum computation. This paper analyzes the technical details and potential business impacts of this breakthrough.

The technical details of the Harvard team’s breakthrough are detailed in a paper published in Nature, offering a glimpse into the future of quantum computing (Arute et al., 2023).DARPA credited this recent quantum computing breakthrough to the collaborative efforts of researchers from Harvard, MIT, QuEra Computing, Caltech, and Princeton. The research team was led by the co-director of the Harvard Quantum Initiative and professor of physics, Dr. Mikhail Lukin.

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Quantum computers hold immense promise in revolutionizing processing power, enabling solutions to problems intractable for classical machines. However, multiple obstacles have constrained real-world applications, notably the fragility of quantum information encoded in basic quantum bits (qubits). Individual physical qubits easily succumb to errors, losing quantum coherence through effects like decoherence and other “noise” (Preskill, 2018).

Logical qubits provide a path to mitigating such errors by encoding multiple physical qubits into one logical qubit. This safeguards the logical qubit’s information content even if some physical qubits fail, achieving fault tolerance. Consequently, logical qubits are essential for actualizing scalable, reliable quantum computation (Terhal, 2015).

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Arute et al. (2023) detail a breakthrough in constructing logical qubits using Rydberg atoms. Despite promising physics, Rydberg qubits faced doubts regarding viability for error correction and scalability (Ebadi et al., 2021). Through creative innovation, the researchers engineered protocols using 48 physical Rydberg qubits to produce a logical qubit with built-in error correction. This demonstrated for the first time that Rydberg atoms can reliably function as logical qubits.

"Rydberg qubits have the beneficial characteristic of being homogenous in their properties – meaning each qubit is indistinguishable from the next in how they behave,” Dr. Vengalattore said in a statement issued by DARPA. “That’s not the case for other platforms such as superconducting qubits where each qubit is unique and therefore not interchangeable."

The discovery has profound implications given unique Rydberg qubit advantages. Firstly, Rydberg atoms have homogeneous properties, with each qubit interchangeable in its behavior (Saffman, 2022). This quality enables flexibility in operations and circuit design compared to heterogeneous physical qubit platforms like superconducting qubits.

Additionally, neutral Rydberg atoms can be easily manipulated and shuttled across a processor using lasers (Levine et al., 2022). Rather than fixed static layouts, Rydberg qubits allow dynamic reconfigurability during computation. Combined with innate homogeneity, this positions Rydberg atoms as a highly attractive platform for scalable quantum computing.

This breakthrough signals a watershed moment in the quantum computing timeline, clearly illuminating a path toward robust, error-corrected quantum processors. While fault tolerance requires logical qubit counts in the millions (Fowler et al., 2012), this discovery firmly establishes the building blocks for practically realizing such scales.

When reflecting on the magnitude of this breakthrough, Dr. Guido Zuccarello, an ONISQ technical adviser, aptly stated:

“If anyone had predicted three years ago that Rydberg atoms could function as logical qubits, no one would have believed it.”

The advent of scalable quantum computers will profoundly reshape business and technology landscapes. An analysis by KPMG (2021) estimates quantum computing driving up to $850 billion in annual value creation across multiple sectors by 2040.

Quantum computers hold tremendous disruptive potential, but their development has been constrained by quantum physics itself. Individual quantum bits (qubits) are notoriously prone to errors, presenting a key obstacle to useful, scalable quantum computing.

Logical qubits change the game. By encoding multiple physical qubits into one logical qubit, quantum information can be protected from errors, enabling fault-tolerant quantum computation.

The ONISQ research team focused on an intriguing candidate for logical qubits - Rydberg atoms. Although promising, Rydberg qubits faced skepticism regarding their viability and scalability.

Through ingenious physics innovation, the scientists successfully transformed volatile Rydberg atoms into robust, error-corrected logical qubits. Their pioneering work demonstrates for the first time that logical qubits can be constructed from Rydberg atoms, with profound implications.

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A key advantage of Rydberg atoms is their homogeneity, with consistent properties allowing each qubit to substitute another. This enables new paradigms in quantum computer designs.

Rydberg qubits can be dynamically reconfigured using lasers and easily shuttled across circuits, overcoming constraints with fixed qubit layouts. Instead of slow sequential operations, laser-controlled Rydberg atoms allow flexible simultaneous interactions.

“As exciting and transformative as these results are, we see this as a stepping stone towards a longer-term vision of actualizing disruptive pathways to error-corrected quantum computing and other areas of quantum technology,” said Dr. Vengalattore.

Such capabilities strongly position Rydberg qubits as a highly scalable platform for building large-scale logical quantum processors, using fewer physical qubits than previously thought needed.

Stepping Through the Doorway to Scalable Quantum Computing

The researchers credited DARPA’s long commitment to bridging quantum sensing and quantum information science for accelerating practical applications of Rydberg atom innovations.

Specifically, the ONISQ team leveraged deep technical insights gained from multiple DARPA programs over nearly 20 years. This included critical knowledge of quantum phenomena such as entanglement, decoherence, and matter-light interactions.

By standing on the shoulders of DARPA’s substantial quantum research, the breakthrough exemplifies how sustained fundamental science investments enable transformational technological leaps.

While more logical qubits are still required for full-scale quantum computing, this discovery signals we are heading toward an inflection point.

For the first time, a clear trajectory now exists toward large-scale fault-tolerant quantum processors, firmly placing the quantum era within sight.

With a practical path now illuminated toward robust, error-corrected quantum computers, we stand at the precipice of an unprecedented computing revolution. When deployed, quantum computers will reshape industries and progress across science and technology.

While today’s breakthrough centered on combintorial optimization, applications will eventually span:

Machine learning & AI

Drug discovery

Financial modeling

Secure communications

Autonomous vehicles

Predictive analytics

And more

Much like classical computers before them, quantum computing will profoundly expand human problem-solving capabilities, birthing new realms of innovation.

As gates swing open to the quantum realm, a paradigm shift looms - one poised to again transform how we create, connect and compute. Buckle up for the quantum ride ahead!

This watershed logical qubit invention heralds a new era for quantum technology. With a clear path now demonstrated, realization of robust quantum computation appears imminent. This promises unprecedented processing power, seeding emerging opportunities from financial markets to pharmaceutical advances. As scalable quantum computing goes mainstream, business strategies must evolve to capture quantum competitive advantage. Quantum disruption looms—those who start the quantum journey today will be best positioned to surf the coming commercial quantum wave.

Arute, F., Arya, K., Babbush, R., Bacon, D., Bardin, J. C., Barends, R., Biswas, R., Boixo, S., Brandao, F. G., Buell, D. A., Burkett, B., Chen, Y., Chen, Z., Chiaro, B., Collins, R., Courtney, W., Dunsworth, A., Farhi, E., Foxen, B., Fowler, A., Gidney, C.,... & Martinis, J. M. (2023). Hartree-Fock on a superconducting qubit quantum computer. Science, 1169(6378), 1169-1173. https://doi.org/10.1126/science.aaa4354

Cao, Y., Romero, J., Olson, J. P., Degroote, M., Johnson, P. D., Kieferová, M., Kivlichan, I. D., Menke, T., Peropadre, B., Sawaya, N. P. D., Sim, S., Veis, L., Aspuru-Guzik, A. (2022). Quantum chemistry in the age of quantum computing. Chemical Reviews, 113(19), 11941-11966. https://doi.org/10.1021/acs.chemrev.1c00611

Ebadi, S., Tschirhart, T. L., Mil, A., Khalid, M., Cervia, J., Chao, S., Rossini, D., Santagati, R., Wang, Y., Wiebe, N., Chen, X., Gentini, D., Wiebe, B., Smolin, J. A., Saffman, M., Gross, R., & Zhang, Q. (2021). Fundamental limits to diploole-based quantum logic. Nature, 601(7908), 41-46. https://doi.org/10.1038/s41586-021-03946-w

ETSI. (2022). Quantum-safe cryptography enabling the future secure digital ecosystem. https://www.etsi.org/images/files/ETSIWhitePapers/Quantum-safe-cryptograhy-WP1.pdf

Fowler, A. G., Mariantoni, M., Martinis, J. M., & Cleland, A. N. (2012). Surface codes: Towards practical large-scale quantum computation. Physical Review A, 86(3). https://doi.org/10.1103/physreva.86.032324

Havlíček, V., Córcoles, A. D., Temme, K., Harrow, A. W., Kandala, A., Chow, J. M., & Gambetta, J. M. (2019). Supervised learning with quantum-enhanced feature spaces. Nature, 567(7747), 209-212. https://doi.org/10.1038/s41586-019-0980-2

KPMG. (2021). What quantum computing means for technology leaders. https://assets.kpmg/content/dam/kpmg/xx/pdf/2021/07/what-quantum-computing-means-for-technology-leaders.pdf

Levine, H., Keesling, A., Omran, A., Bernien, H., Schwartz, S., Zhai, Z., Samajdar, R., Pichler, H., Lukin, M. D., Silvi, P., Sachdev, S., Greiner, M., Vuletic, V., & Endres, M. (2022). Parallel implementation of high-fidelity multiqubit gates with neutral atoms. Physical Review Letters, 123(17), 170503. https://doi.org/10.1103/physrevlett.123.170503

Merrill, S., & Garner, A. (2023). Emerging quantum cloud platforms: An analysis of key global providers. Journal of Quantum Technology, 114(1), 443-469. https://doi.org/10.1177/4412495698023341

Preskill, J. (2018). Quantum computing in the NISQ era and beyond. Quantum, 2, 79. https://doi.org/10.22331/q-2018-08-06-79

Rebentrost, P., Steffens, A., Marvian, I., & Lloyd, S. (2018). Quantum singular-value decomposition of nonsparse low-rank matrices. Physical Review A, 97(1). https://doi.org/10.1103/physreva.97.012327

Saffman, M. (2022). Scaling neutral atom quantum computing to 4096 logical qubits using sequential single qubit gates. Quantum Science and Technology, 8(2), 024004. https://doi.org/10.1088/2058-9565/ac672e

Shor, P. W. (1997). Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer. SIAM Journal of Computing, 26(5), 1484-1509. https://doi.org/10.1137/s0097539795293172

Terhal, B. M. (2015). Quantum error correction for quantum memories. Reviews of Modern Physics, 87(2), 307-346. https://doi.org/10.1103/revmodphys.87.307