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Quantum Annealers Unravel the Mysteries of Many-Body Systems – SciTechDaily

Artistic rendition of a quantum simulation of 1T-TaS2 being performed on the quantum processing unit of a quantum annealer. Credit: Jozef Stefan Institute / Jaka Vodeb und Yevhenii Vaskivskyi, edited

Scientists have utilized a quantum annealer to simulate quantum materials effectively, marking a crucial development in applying quantum computing in material science and enhancing quantum memory device performance.

Physicists have long been pursuing the idea of simulating quantum particles with a computer that is itself made up of quantum particles. This is exactly what scientists at Forschungszentrum Jlich have done together with colleagues from Slovenia. They used a quantum annealer to model a real-life quantum material and showed that the quantum annealer can directly mirror the microscopic interactions of electrons in the material. The result is a significant advancement in the field, showcasing the practical applicability of quantum computing in solving complex material science problems. Furthermore, the researchers discovered factors that can improve the durability and energy efficiency of quantum memory devices.

In the early 1980s, Richard Feynman asked whether it was possible to model nature accurately using a classical computer. His answer was: No. The world consists of fundamental particles, described by the principles of quantum physics. The exponential growth of the variables that must be included in the calculations pushes even the most powerful supercomputers to their limits. Instead, Feynman suggested using a computer that was itself made up of quantum particles. With his vision, Feynman is considered by many to be the Father of the Quantum Computing.

Scientists at Forschungszentrum Jlich, together with colleagues from Slovenian institutions, have now shown that this vision can actually be put into practice. The application they are looking at is a so-called many-body system. Such systems describe the behavior of a large number of particles that interact with each other. In the context of quantum physics, they help to explain phenomena such as superconductivity or quantum phase transitions at absolute zero. At a temperature of 0 Kelvin, instead of thermal fluctuations, only quantum fluctuations occur when a physical parameter like the magnetic field changes.

D-Wave Quantum Annealer JUPSI at Forschungszentrum Jlich. Credit: Forschungszentrum Jlich / Sascha Kreklau

One challenge in researching quantum materials is to quantitatively measure and model the phase transitions of many-body systems, explains Dragan Mihailovi from the Joef Stefan Institute in Slovenia. In this study, the scientists investigated the quantum material 1T-TaS2, which is used in a wide range of applications, including superconducting electronics and energy-efficient storage devices.

Jaka Vodeb from the Jlich Supercomputing Centre describes the approach: We have placed the system in a non-equilibrium state and observed how the electrons in the solid-state lattice rearrange themselves after a non-equilibrium phase transition, both experimentally and through simulations.

All calculations were conducted using the quantum annealer from the company D-Wave, which is integrated into the Jlich Unified Infrastructure for Quantum Computing, JUNIQ.

The researchers could successfully model the crossover from temperature-driven to noisy quantum fluctuation dominated dynamics. Furthermore, the scientists demonstrated that the quantum annealers qubit interconnections can directly mirror the microscopic interactions between electrons in a quantum material. Only one single parameter in the quantum annealer must be modified. The outcome aligns closely with the experimental findings.

However, the research also has practical applications. For instance, a deeper understanding of 1T-TaS2-based memory devices can lead to a practical quantum memory device, implemented directly on a quantum processing unit (QPU). Such devices can contribute to the development of energy-efficient electronic devices, thereby significantly reducing the energy consumption of computing systems.

The research highlights the potential of quantum annealers in solving practical problems, paving the way for their broader application in various fields such as cryptography, material science, and complex system simulations. Moreover, the findings have direct implications for the development of energy-efficient quantum memory devices.

Reference: Non-equilibrium quantum domain reconfiguration dynamics in a two-dimensional electronic crystal and a quantum annealer by Jaka Vodeb, Michele Diego, Yevhenii Vaskivskyi, Leonard Logaric, Yaroslav Gerasimenko, Viktor Kabanov, Benjamin Lipovsek, Marko Topic and Dragan Mihailovic, 6 June 2024, Nature Communications. DOI: 10.1038/s41467-024-49179-z

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The Interplay of AI, Cybersecurity & Quantum Computing – The Quantum Insider

At the Tech.eu Summit in London, Dr. Ken Urquhart, Global Vice-President of 5G/Edge/Satellite at Zscaler, and Steve Brierley, Founder and CEO of Riverlane, discussed the critical intersection of artificial intelligence (AI), cybersecurity and quantum computing. Moderated by Duygu Oktem Clark, Managing Partner at DO Venture Partners, the talk underlined both the challenges and opportunities these technologies present.

Urquhart opened the discussion by addressing the limitations of AI in cybersecurity.

AI, as we apply it today, involves algorithms that are interpretable and useful for cyber defense, he said. However, he pointed out that current AI technologies, such as neural networks and large language models, come with issues like statistical variability and hallucinations, where the AI makes things up that may not be true.

Urquhart explained that these statistical models could become less accurate over time, adding: You need to be thoughtful about how you apply AI because it can give less accurate answers if asked the same question twice in a row over a span of hours or days.

Brierley shared his thoughts into the advancements in quantum computing and its implications for cybersecurity. He noted that while todays quantum computers are extremely error-prone and capable of only about 100 to 1,000 operations before failure, significant progress is being made with quantum error correction.

Quantum error correction is a layer that sits on top of the physical qubits and corrects errors in real-time, Brierley explained.

This development is crucial for achieving cryptographically relevant quantum computing capabilities.

2023 and 2024 have been pivotal years as we crossed the threshold in various qubit modalities, making error correction viable, he said. Brierley projected that within the next two to three years, we could see quantum computers performing up to a million operations, surpassing what classical computers can simulate.

As AI and quantum computing advance, ethical and security challenges emerge. Urquhart stressed the importance of understanding AIs current limitations.

We are on a journey with artificial intelligence. It does not think; it is a collection of statistical outcomes, he stated. Urquhart warned against over-reliance on AI for critical decisions, as its current form can lead to significant errors.

Brierley added that quantum computing has the potential to revolutionize industries, particularly in simulating molecular dynamics and chemical interactions.

Quantum computers can replace time-consuming lab experiments with simulations, transforming industries like drug discovery and material science, he said.

Both experts agreed on the necessity of collaboration among academia, industry and government to harness these technologies responsibly. Brierley called attention to the importance of a coordinated effort, likening it to a Manhattan-scale project to build the worlds most powerful quantum computers. We need effective collaboration across sectors to ensure the technology benefits society, he said.

Urquhart echoed this sentiment, giving emphasis to the role of commercial entities in driving innovation and the governments role in providing a regulatory and funding environment.

The machinery is there; we just need the will to engage and make it run, he remarked.

Looking ahead, both Urquhart and Brierley stressed the urgency of preparing for the impact of quantum computing on cybersecurity.

Quantum computing will break most encryption at some point, Urquhart warned, urging businesses to act now to mitigate future risks.

Brierley concluded: Quantum computers are not just faster computers; they represent a massive step forward for specific problems, and their potential for both good and bad is immense.

The discussion underscored the transformative potential of AI and quantum computing while cautioning against complacency. As these technologies evolve, proactive collaboration and ethical considerations will be paramount in shaping a secure digital future.

Featured image: Credit: Tech.eu

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Quantum Computing Inc. Announces Receipt of Nasdaq Non-Compliance Notice – PR Newswire

HOBOKEN, N.J., June 27, 2024 /PRNewswire/ --Quantum Computing Inc. (NASDAQ: QUBT) ("QCi" or the "Company"), an innovative quantum optics and nanophotonics technology company, today announced that it received a notice (the "Notice") from Nasdaq Stock Market LLC ("Nasdaq") that the Company had failed to satisfy a standard for continued listing, Nasdaq Listing Rule 5250(c)(1), because the Company did not timely file its Quarterly Report on Form 10-Q for the fiscal quarter ended March 31, 2024 (the "Form 10-Q") with the Securities and Exchange Commission (the "SEC").

The Notice states that the Company has until August 23, 2024 to submit to Nasdaq a plan to regain compliance with the Nasdaq Listing Rules. If Nasdaq accepts the Company's plan, then Nasdaq may grant the Company up to 180 calendar days from the filing's due date, or until December 16, 2024, for filing the Form 10-Q to regain compliance. If the Company fails to timely regain compliance, the Company's ordinary shares will be subject to delisting from Nasdaq.

As previously reported, effective May 3, 2024, the Company dismissed BF Borgers CPA PC ("BF Borgers") as its independent registered public accounting firm, in parallel with an order by the SEC against BF Borgers, and effective June 6, 2024, appointed BPM LLP ("BPM") as the Company's independent registered public accounting firm. The Company plans to file its Form 10-Q as soon as practicable after completion of BPM's audit of the Company's consolidated financial statements for its 2023 fiscal year.

This announcement is made in compliance with the Nasdaq Listing Rule 5810(b), which requires prompt public disclosure of the deficiency.

About Quantum Computing Inc.

Quantum Computing Inc. (QCi) (Nasdaq:QUBT) is an innovative, integrated photonics company that provides accessible and affordable quantum machines to the world today. QCi products are designed to operate at room temperature and low power at an affordable cost. The Company's portfolio of core technology and products offer unique capabilities in the areas of high-performance computing, artificial intelligence, cybersecurity as well as remote sensing applications.

For more information about QCi, visitwww.quantumcomputinginc.com.

Forward-Looking Statements

Certain information contained in this report consists of forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995 that involve risks, uncertainties and assumptions that are difficult to predict. Words such as "will," "would," "may," "intends," "potential," and similar expressions, or the use of future tense, identify forward-looking statements, but their absence does not mean that a statement is not forward-looking. Such forward-looking statements are not guarantees of performance and actual actions or events could differ materially from those contained in such statements. For example, there can be no assurance that the Company will regain compliance with the Rule during any compliance period or in the future, or otherwise meet Nasdaq compliance standards, that the Company will be eligible for a second compliance period, or that Nasdaq will grant the Company any relief from delisting as necessary or that the Company can ultimately meet applicable Nasdaq requirements for any such relief. The forward-looking statements contained in this report speak only as of the date of this report and the Company undertakes no obligation to publicly update any forward-looking statements to reflect changes in information, events or circumstances after the date of this report, unless required by law.

SOURCE Quantum Computing Inc.

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Study Reveals Insights into Electron-on-Solid-Neon Qubits for Quantum Computing – AZoQuantum

In a recent study published in Physical Review Letters, Professor Wei Guo from Florida State Universityprovided valuable insights into the quantum states of electrons on qubits.

Quantum computers have the potential to revolutionize technology by performing calculations that would take classical computers many years to complete.

To build an effective quantum computer, a reliable quantum bit, or qubit, is essential. A qubit must be able to exist simultaneously in both the 0 and 1 states for a sufficiently long period, known as its coherence time.

One promising approach involves trapping a single electron on a solid neon surface, creating what is known as an electron-on-solid-neon qubit.

Guos team discovered that small bumps on the surface of solid neon can naturally bind electrons, forming ring-shaped quantum states. These quantum states describe various properties of an electron, such as position, momentum, and other characteristics before measurement. When these bumps are of a certain size, the electrons transition energythe energy required for an electron to move from one quantum ring state to anotheraligns with the energy of microwave photons, another type of elementary particle.

This alignment allows for the controlled manipulation of electrons, which is crucial for quantum computing.

This work significantly advances our understanding of the electron-trapping mechanism on a promising quantum computing platform, it not only clarifies puzzling experimental observations but also delivers crucial insights for the design, optimization, and control of electron-on-solid-neon qubits.

Wei Guo, Professor, Florida State University

Guo and collaborators previously demonstrated the feasibility of a solid-state single-electron qubit platform using electrons trapped on solid neon. Recent research has revealed coherence times of up to 0.1 milliseconds100 times longer than the typical 1 microsecond coherence time for conventional semiconductor-based and superconductor-based charge qubits.

The extended coherence time of the electron-on-solid-neon qubit is attributed to the inertness and purity of solid neon. This system also addresses the issue of liquid surface vibrations, a problem inherent in the more extensively studied electron-on-liquid-helium qubit. The current research provides crucial insights into further optimizing the electron-on-solid-neon qubit.

A key aspect of this optimization involves creating qubits that are smooth across most of the solid neon surface while having bumps of the right size where needed. Designers aim to minimize naturally occurring surface bumps that attract disruptive background electrical charge. Simultaneously, intentionally fabricating bumps of the correct size within the microwave resonator on the qubit enhances its ability to trap electrons effectively.

This research underscores the critical need for further study of how different conditions affect neon qubit manufacturing, Neon injection temperatures, and pressure influence the final qubit product. The more control we have over this process, the more precise we can build, and the closer we move to quantum computing that can solve currently unmanageable calculations.

Wei Guo, Professor, Florida State University

Toshiaki Kanai, a Graduate Research Student in the FSU Department of Physics, and Dafei Jin, an Associate Professor at the University of Notre Dame are the Co-authors of the study.

The National Science Foundation, the Gordon and Betty Moore Foundation, and the Air Force Office of Scientific Research supported the research.

Kanai, T., et al. (2024) Single-Electron Qubits Based on Quantum Ring States on Solid Neon Surface. Physical Review Letters. doi.org/10.1103/PhysRevLett.132.250603.

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Quantum Seed Grants Are Funding Solutions to Real-World Problems – UConn Today – University of Connecticut

What do underwater navigation, drug safety, and air traffic control have in common? Each creates challenges that quantum science and technology could solve.

In Connecticut, the unique public-private partnership QuantumCT is accelerating research to meet those challenges head onand to position Connecticut as a global quantum technology hub.

As of this spring, nine Connecticut-based research groups have received one-year seed grants for exploratory quantum projects. Each project aims to tackle a challenge problem issued by corporate partners in the state, like the need to develop algorithms that simulate molecular drug actions in the body, or to invent exquisitely accurate but hardy sensors that work in extreme environments with little power.

In other words, the projects are directly relevant to Connecticut industries, including aerospace, biotech, and life sciences. This practical approach to science is called use-inspired research.

These grants are fertilizing creative, potentially transformative projects in quantum science and technology across several key industries, all of which are central to Connecticuts present and future economy, says Michael Crair, Vice Provost for Research and William Ziegler III Professor of Neuroscience and Professor of Ophthalmology and Visual Science at Yale University.

The seed grants are funded by the University of Connecticut and Yale University and distributed via QuantumCT. Research results will help QuantumCT plan long-term research eligible for competitive funding through the National Science Foundations Regional Innovation Engines (a program established through the 2022 CHIPS and Science Act).

The aim of QuantumCT is to make Connecticut a global destination for quantum education, job training and equitable job growth, research innovation, and industry excellence.

Because large universities and industry in Connecticut have joined forces, sharing resources and expertise under the QuantumCT umbrella, we are realizing a faster pace of quantum innovationand advancing our states role as a leader in quantum science and technology, says Pamir Alpay, Vice President for Research, Innovation, and Entrepreneurship and Board of Trustees Distinguished Professor of Materials Science and Engineering at the University of Connecticut. The seed grants will fuel not only quantum discovery but also career opportunities in a high-demand STEM field.

Each project is collaborative, bringing together researchers from UConn, Yale, and industry partners.

The projects foster interactions among a range of researchers from faculty to students to industry scientists, allowing them to pool their knowledge and creativity at top-of-the-line laboratory facilities in Connecticut, Alpay notes. These collaborations also offer rising quantum scientists a look at potential career paths in industry.

Advanced sensing

Airplanes, ships, and other vehicles rely on sensors for accurate navigation. But current sensor technologies have important limitations, and five of the project teams are working to develop better ones.

In one, led by Charles Ahn and Alexander Balatskyphysics professors at Yale and UConn, respectivelythe aim is to develop a robust, highly sensitive radiofrequency (RF) sensor that outperforms state-of-the-art directional sensors. To do this, the team is studying how electromagnetic waves interact with atom-sized magnets.

We incorporate magnetic atoms on thin films on the nanoscale, says Dung Vu, a Yale postdoctoral associate on the team, which also includes collaborators from RTX Technology Research Center (RTRC), the research arm of RTX and its three businesses Collins Aerospace, Pratt & Whitney, and Raytheon.

By changing properties such as energy and polarization of the light we shine on to the film, we can manipulate the quantum magnets properties, then measure the change of the magnetic field around them when they interact with light, Vu says.

The devices, Vu explains, can be used to make RF sensors that may be useful for airborne and autonomous vehicles.

Another team is developing innovative fiber sensors for a magnetic-aided inertial navigation unit for a global navigation satellite system (GNSS). With its extraordinary sensitivity, this technology is designed to operate in environments like the deep ocean and underground, where GNSS signals can be jammed, spoofed, or otherwise unreliable. Electrical engineers Faquir Jain and John Chandy of UConn and Fengnian Xia of Yale are behind that effort.

The sensor can detect ultra-low magnetic fields that help with navigation with very low power consumption and cost, Jain says.

A key challenge for next-generation magnetic sensors is to limit the devices SWaP (size, weight, and power consumption). Currently, the best ones require supercooled liquid helium. A seed project by assistant professors Yu He of Yale (applied physics) and Pavel Volkov of UConn (engineering) is pursuing sensors cooled with liquid nitrogena much more user-friendly substance.

The results will form one pillar for the eventual theory-experiment-industry collaboration, Volkov says.

Highly accurate sensors are vulnerable to miniscule errors and noise in the data. A team led by Yale engineering professor Hong Tang is building ultra-thin silicon nitride microwheels to create a tough, low-SWaP sensor whose round shape is designed to reduce error.

Meanwhile, Yale associate professor of physics and applied physics Peter Rakich is developing a technique to attach microscopic mirrors to the end of silica fibers, creating a tiny, high-finesse device called a resonator. This resonator should allow precise control of quantum particles, like the ability to couple light particles with ions. That could advance not only sensors, but also quantum computers and networking.

Computing revolutions

With quantum technologies poised to revolutionize computing, many industries stand to benefit.

Quantum entanglement, the eerie phenomenon by which two particles are linked as if they were one, is central to quantum computing and a major reason why the technology is expected to deliver vast improvements. In fact, entanglement can be considered a key resource in quantum computing, and as with any resource, there are better and worse ways of distributing it. Leandros Tassiulas and Shan Zuo, electrical engineering faculty at Yale and UConn, respectively, are studying how quantum computing systems can generate entanglement across multiple users in an equitable way.

Air traffic controllers, delivery route planners, and factory managers are among the many workers who face optimization problems: how to make actions most efficient. But optimization problems can be fiendishly difficult to solve, especially where there are hard constraints like the need for airplanes to avoid no-fly zones, trucks to refuel, or machines to complete tasks in a certain order. Like classical computers, quantum computers can use heuristics to tackle optimization problemswhich remain extremely challenging to solve.

A joint Yale-UConn team led by Yale physics professor Steven Girvin is exploring whether new algorithms could help quantum computers handle hard constraints on optimization problems. The research should also have relevance to problems like portfolio optimization and risk assessment that frequently arise in domains like finance and insurance, supply-chain logistics, and flight route planning, according to Amit Surana, an RTRC researcher working with the team.

The value proposition is that even slight improvements to logistics, even by half a percent, can mean huge savings, Surana says.

Progress in life sciences

Computing is also a focus of two teams led by Yale chemistry faculty members Victor Batista and Tianyu Zhu, which are exploring quantum solutions to problems in drug development.

One complex challenge researchers face is efficiently identifying drugs that will bind tightly to the intended receptor. Zhu and Batista, with partners at UConn, including physics professor Lea Ferreira Dos Santos and representatives of Mirion Technologies and Boehringer Ingelheim, are developing algorithms that run on quantum computers to tackle this task.

Drug safety, too, might be improved by quantum computing. New drugs must be rigorously checked for possible toxic side effects on the heart, liver, and immune system. As part of a de-emphasis on animal testing, the industry has been studying the use of classical computing tools like machine learning and artificial intelligence to evaluate possible side effects. But quantum computing techniques remain relatively unexplored.

So, another group working with Zhu and Batista is developing algorithms that use toxicology data to predict the safety of drug candidates. They are studying a hybrid approach in which a classical computer does a first check for toxicity, then drug candidates that pass that test undergo a further check by a quantum algorithm. Such a hybrid quantum-classical approach is a new and potentially highly effective way to do AI. Project partners include UConn professor Bodhisattva Chaudhuri and researchers with Novartis and Pfizer.

With this method, says Anthony Smaldone, a graduate student in the Batista lab, we can remove drugs that are highly likely to fail in testing. Then we dont have to rely on animal testing so heavily.

The hybrid method allows for tinkering that should help researchers determine where quantum computers offer efficiency gains, Smaldone explains.

We can slowly change our hybrid models, taking out classical components and putting quantum components in, and see what works and what doesnt, he says. Hopefully, as were putting in these quantum components, we can start to see quantum advantages in doing so.

Currently, Smaldone says, the team is working with simulations only. Real-world success will have to wait for certain types of hardware and algorithms to catch up. But this shows the first theoretical framework to do this efficiently, he says.

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Quantum Computing One Step Closer to Reality by Leveraging Harmonic Oscillators – Securities.io

The quantum computer race has been hot for a few years now, with drug discovery, materials science, optimization, machine learning, and cryptography being just a few of the areas that will be revolutionized by its advancements. But despite all the progress, building quantum computers that solve real-world problems has been held back by three big challenges:

Now, a team at Chalmers University of Technology in Sweden has taken a significant step in addressing these challenges and accelerating the development of practical quantum computers. They recently published a new method in the journal Nature for manipulating quantum information using tunable nonlinearity in superconducting circuits. This allows for complex operations on multi-dimensional quantum states to be performed faster and more accurately than ever before.

At the heart of quantum computing is the quantum bit, or qubit, the fundamental unit of quantum information. Unlike classical bits, which are either 0 or 1, qubits can be both 0 and 1 and everything in between. Qubits can also be entangled with each other, allowing quantum computers to perform some calculations much faster than classical computers.

However, reaching this capability has been a significant challenge. One of the biggest issues is the fragility of quantum states. Qubits are sensitive to their environment and quickly lose their quantum properties through decoherence, introducing errors into the quantum computation and limiting the depth of computations.

Another major problem is scaling. As more qubits are added to a quantum processor, it becomes harder to control the interactions between them and to implement the quantum gates. This is because the control systems and cross-talk between qubits become more complex.

And theres a trade-off between coherence and controllability. Techniques that make qubits more coherent, like error correction codes, require more resources and limit some operations. Systems that have more control over individual qubits, like trapped ions or superconducting circuits, are noisier and more prone to decoherence.

Think of a qubit as a blue lamp that, quantum mechanically, can be both switched on and off simultaneously. In contrast, a continuous variable quantum system is like an infinite rainbow, offering a seamless gradient of colors. This illustrates its ability to access a vast number of states, providing far richer possibilities than the qubit's two states.

Axel Eriksson, researcher in quantum technology at Chalmers University of Technology and lead author of the study

Click here to learn about the current state of quantum computing.

The Chalmers University team, led by Drs. Axel M. Eriksson and Simone Gasparinetti have solved these problems by using superconducting circuits. Theyve developed a special component called a Superconducting Nonlinear Asymmetric Inductive eLement (SNAIL) resonator.

SNAILs are superconducting circuit elements with strong, tunable nonlinearity. Its a superconducting loop with Josephson junctions, thin insulating barriers that allow Cooper pairs (bound pairs of electrons) to tunnel through. By arranging the junctions asymmetrically, theyve made a circuit element with nonlinear inductance.

We have made a system that does complex operations on a multi-state quantum system faster than ever before.

Senior author Dr. Simone Gasparinetti, leader of the 202Q-lab at Chalmers University

The key thing the Chalmers team did was to put a SNAIL resonator inside a superconducting microwave cavity, which is a bosonic mode for encoding quantum information. They applied microwave pulses to this hybrid system and activated and deactivated the nonlinearity in the SNAIL to perform all sorts of quantum operations fast and accurately.

One of the unique things about the Chalmers teams approach is that it goes beyond the qubit paradigm and uses continuous-variable (CV) quantum states. In a CV quantum system, information is encoded in the amplitude and phase quadratures of a harmonic oscillator, like a microwave cavity field. Those quadratures can take on a continuous range of values, not just 0 and 1 like qubits. According to senior author Dr. Simone Gasparinetti, leader of the 202Q-lab at Chalmers University:

We have created a system that enables extremely complex operations on a multi-state quantum system, at an unprecedented speed.

The CV approach has advantages over discrete-variable quantum computing. (i) One, a single CV mode can encode multiple qubits worth of information, which means less hardware for fault-tolerant quantum computing. (ii) Two, the consciousness of CV states allows for better error correction codes, which are needed for quantum computing with noise and decoherence.

However, a big problem in CV quantum computing is non-Gaussian operations, which are needed for universal quantum computing. Gaussian operations like displacement and squeezing of the oscillator state can be done with linear optical elements or microwave circuits, but thats not enough for quantum speedup because it can be classically simulated.

Non-Gaussian operations require nonlinear interactions, which are much harder to make and control. Previous attempts to combine CV modes with nonlinear elements have been foiled by the Kerr effect, which messes up the quantum information and reduces the operation fidelity.

The Chalmers team has solved this by engineering the nonlinearity inside the SNAIL resonator. They operate the SNAIL at a so-called Kerr-free point, where the unwanted Kerr nonlinearity is suppressed, and the third-order nonlinearity thats needed for non-Gaussian operations is preserved.

Our community has often tried to keep superconducting elements away from quantum oscillators, not to scramble the fragile quantum states. In this work, we have challenged this paradigm. By embedding a controlling device at the heart of the oscillator we were able to avoid scrambling the many quantum states while at the same time being able to control and manipulate them. As a result, we demonstrated a novel set of gate operations performed at very high speed.

Simone Gasparinetti

To show what they can do, theyve made a universal gate set on their SNAIL-resonator platform. That includes Gaussian gates like displacement and squeezing and a cubic phase gate, which is non-Gaussian.

The Gaussian gates were made by applying microwave pulses at specific frequencies to the SNAIL circuit. Driving at the fundamental frequency gives displacement, and driving at twice the fundamental frequency gives squeezing. Thats for preparing and manipulating coherent and squeezed states, which are the blocks for CV quantum information processing.

The cubic phase gate was made by combining a trisqueezing interaction (driving at three times the fundamental frequency) with drives at lower frequencies. That applies a nonlinear phase shift to the oscillator state thats proportional to the cube of the amplitude, hence the name cubic phase.

The cubic phase gate is needed for universal CV quantum computing because it makes highly non-classical states like Gottesman-Kitaev-Preskill (GKP) states, which are for fault-tolerant quantum error correction. The cubic phase gate with Gaussian gates makes a deterministic non-Gaussian state called the cubic phase state.

The gates made by the Chalmers team were made with pulses as short as tens of nanoseconds. Thats 10-100 times faster than previous implementations with dispersive qubit-oscillator couplings. Thats because of the strong nonlinearity in the SNAIL resonator.

Another example is the Chalmers team using their universal gate set to make a highly non-classical quantum state called a cubic phase state. Cubic phase states are needed for quantum error correction, quantum metrology, and CV measurement-based quantum computing.

Cubic phase state preparation was made by applying gates to the ground state (vacuum) of the SNAIL resonator. First, a 20-ns squeezing gate was applied to make a squeezed vacuum state. Then, a 40-ns cubic phase gate was applied to that squeezed state, and voil, a cubic phase state with a cubicity of 0.11.

The state was characterized with Wigner tomography, which makes a phase-space distribution of the quantum state. The Wigner function was strongly negative, which is non-classical and cannot be seen in any classical oscillator state.

The fidelity of the cubic phase state with respect to the target state was 92%. They showed that the cubicity of the state can be increased by just extending the cubic phase gate duration. Thats much better than previous state preparation methods, which required a full re-optimization of the control sequence for each cubicity value.

While what the Chalmers team has done is already commendable, theres still more to be done:

One limitation of the quantum operations is the coherence time of the SNAIL resonator. They have coherence times of a few microseconds, which is enough for now, but longer coherence times will allow for more complex and deeper quantum circuits. Optimizing the SNAIL circuit parameters to reduce flux noise and shielding and filtering the microwave environment are ways to improve coherence.

This includes:

Click here to learn how quantum emitters and infrared lasers can help us build the next generation of quantum computers.

Another area to improve is scalability. The experiment was done with one SNAIL, but a large-scale quantum computer needs multiple SNAILs. To scale up, one could use multiple SNAILs, each connected to its own microwave cavity. This setup allows for the creation of multi-qubit gates and entangled states by designing the coupling between the cavities. However, that requires control over the fabrication and tuning of the SNAILs to be homogeneous and reproducible.

Besides scaling up the number of CV modes, we also need to scale up the number of photons in each mode. The SNAIL resonator's nonlinearity deviates from its ideal behavior at higher photon numbers, which limits the size of the computational Hilbert space.

One way to fix that is to use a multi-SNAIL design in which the nonlinearity of each SNAIL is engineered to cancel out at higher orders while preserving the lower-order interactions.

Other plausible advancements include:

Looking ahead, the Chalmers team wants to integrate their SNAIL-resonator platform with other quantum computing architectures to make hybrid systems. For example, SNAIL-mediated interactions can be used to entangle superconducting qubits and CV modes to make complex multi-qubit states. The fast and efficient CV gates in this work can be used for quantum error correction on encoded qubits, and that will make more robust and scalable quantum processors.

One exciting prospect to look forward to is integrating the SNAIL-resonator platform with optical quantum systems. Superconducting circuits are good for quantum computing, which operate at microwave frequencies and cryogenic temperatures, are good for quantum computing. In contrast, optical quantum systems, which function at room temperature, are ideal for long-distance quantum communication. By developing a quantum frequency converter, we can combine the best of both worlds to create a scalable and networked quantum computer.

What the Chalmers team has achieved is a major advancement for practical quantum computers. Theyve used tunable nonlinearity in superconducting circuits to develop a hardware-efficient and controllable quantum computer capable of rapidly and accurately performing complex operations on multidimensional quantum states.

This represents a new paradigm in CV-NISQ computing. SNAIL resonators can solve hard problems in quantum chemistry, optimization, and machine learning. As this technology matures and scales, it will open up applications that are not possible with classical computers.

However, building large-scale, fault-tolerant quantum computers still presents substantial challenges, including the coherence time of superconducting circuits, the number of qubits and CV modes, and interfaces between quantum computing platforms.

Despite these challenges, quantum computing as an applied science has come a long way, and the Chalmers team has played an instrumental role in pushing its barriers. Theyve added to the quantum computing toolbox and shown us new ways to use quantum mechanics. Now, were one step closer to accessible quantum computing.

As theory and experiments move faster, the future of quantum computing has never looked better. Quantum computers will deliver exponential speedups for a wide range of computational tasks in fields such as drug discovery, materials design, cryptography, and artificial intelligence. Coupled with advances in technologies like AI, these developments assure us that the world is on the brink of transformative changes that are hard to fully envision.

Click here for a list of the five best quantum computing companies.

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Quantum Machines opens the Israeli Quantum Computing Center – PR Newswire

A core part of the Israel Innovation Authority's Israel National Quantum Initiative, the center is the first to tightly integrate multiple types of quantum computers with supercomputers using NVIDIA DGX Quantum

TEL AVIV, Israel, June 25, 2024 /PRNewswire/ -- Quantum Machines (QM), the leading provider of processor-based quantum controllers, announced the opening of the Israeli Quantum Computing Center (IQCC), a world-class research facility that will serve the quantum computing industry and academic community in Israel and around the world. The center was built with the financial backing and support of the Israel Innovation Authority and is located at Tel Aviv University.

The IQCC's grand opening took place yesterday, June 24th, as part of Tel Aviv University's AI and Cyber Week. The ceremony began with the ribbon-cutting, followed by speeches from Asaf Zamir, First Deputy Mayor of Tel Aviv; Dror Bin, CEO of the Israel Innovation Authority; Prof. Yaron Oz and Prof. Itzik Ben Israel from Tel Aviv University; and Dr. Itamar Sivan, CEO of Quantum Machines. Industry experts, including Eyal Waldman, co-founder and former CEO of Mellanox, Ofir Zamir, Senior Director of AI Solution Architecture at NVIDIA, and Niv Efron, Senior Director of Engineering at Google, also shared their insights.

About the IQCC:

In the global race to develop practical quantum computing, access to cutting-edge facilities is crucial. "All of the world's most advanced quantum computing research facilities are closed or offer very limited access to those outside of their organization. You can't compete if you need to fly halfway around the world for limited access," said Dr. Itamar Sivan, CEO and co-founder of Quantum Machines. "When we thought about what would propel quantum computing forward, we realized that building the most advanced facility in terms of interoperability, modularity, and integration with high-performance computing (HPC) and the cloud was the way to go. Our open architecture approach will ensure that the facility can be continuously upgraded and scaled to stay at the cutting edge, making it an accelerator for the entire ecosystem in Israel and internationally."

The IQCC is a state-of-the-art quantum and HPC center that uniquely integrates the power of quantum and classical computing resources. It is the first in the world to house multiple co-located quantum computers of different qubit types, all utilizing the NVIDIA DGX Quantum system. This offers on-premises supercomputing resources and cloud accessibility, while being tightly integrated with Quantum Machines' processor-based OPX control system. The center also features the world's best-equipped testbed for developing new quantum computing technologies.

The unified DGX Quantum system for integrated quantum supercomputing was co-developed by NVIDIA and Quantum Machines. DGX Quantum implements NVIDIA CUDA-Q, an open-source software platform for integrated quantum-classical computing. The system features a supercomputing cluster headlined by NVIDIA Grace Hopper superchips and also including NVIDIA DGX H100, all connected to AWS cloud platforms for remote access and to leverage additional cloud computing resources. The center also utilizes QM's new OPX1000 controller, designed to enable scaling to 1,000+ qubits.

"The tight integration of quantum computers with AI supercomputers is essential to the development of useful quantum computing," said Tim Costa, Director of Quantum and HPC at NVIDIA. "This work with Quantum Machines to enable a flagship deployment of NVIDIA DGX Quantum in the IQCC offers researchers the platform they need to grow quantum computing into the era of large-scale, useful applications"

"Before the IQCC, a developer of a quantum processor chip would need to build their own testing setup, costing millions," said Dr. Yonatan Cohen, CTO and co-founder of Quantum Machines. "Now, researchers can plug their chip into our testbed and benefit from the most advanced setup in the world, leveraging NVIDIA and Quantum Machines hardware to accelerate their development process and reduce costs significantly."

The IQCC is open to researchers and developers of quantum computers from around the world. By providing an open, cutting-edge platform for research and development, Quantum Machines aims to accelerate the progress of practical quantum computing and foster collaborative projects with industry leaders that will drive the field forward. The center is poised to become a destination for companies and researchers worldwide, securing Israel's quantum independence and cementing its position as a leader in the quantum computing revolution.

For more information about the IQCC please visit https://i-qcc.com/.

Additional information on technology and partners:

ContactGavriel Cohen Concrete Media for Quantum Machines[emailprotected]

Photo - https://mma.prnewswire.com/media/2447560/Quantum_Machines.jpg

SOURCE Quantum Machines

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How High-Performance Computing Is Shaping the Future of Quantum & AI , From Intel’s James Reinders – The Quantum Insider

In a compelling conversation on the InTechnology podcast, Camille Morhardt sat down with James Reinders, a high-performance computing engineer at Intel, to discuss the intersection of high-performance computing (HPC), quantum computing and artificial intelligence (AI). Reinders brings a wealth of experience and insight into how these cutting-edge technologies are evolving and what they mean for the future.

Reinders opened by defining high-performance computing as the biggest, baddest, fastest computer you can build to solve very large engineering, scientific, and computational problems. He explained that the term supercomputing emerged in the mid to late seventies when there was a push to build more complex and expensive machines than those used for everyday business processing.

Discussing the evolution of supercomputing, Reinders noted: By the late nineties, standard supercomputers changed from being exotic built machines to ones that consisted of thousands of off-the-shelf processors. This shift marked the end of debates over the scalability of multi-core processors.

Reinders sees quantum computing as a natural extension of high-performance computing.

Quantum computing is pretty specific in the type of problems it can solve, he said. It may not be the best way to solve every problem, but it stands the promise of being phenomenally amazing at modeling the real physical world. He predicts that quantum computing will not displace other architectures but will instead join them, creating a more diverse and capable computational landscape.

On the practical applications of quantum computing, Reinders said: Some of the first uses will clearly be modeling of molecular dynamics, different things in chemistry, and those are incredibly important in solving problems. He predicts quantum computing being used alongside traditional HPC to enhance simulations and solve complex problems more efficiently.

Reinders is particularly excited about the integration of AI techniques with traditional HPC workloads. He shared an example of how AI is being used to replace Monte Carlo operations in molecular dynamics simulations.

They took a neural network, a GAN network, and trained it by letting it watch Monte Carlo operations, he said. The results were really exciting; it was able to do simulations that seemed to give us comparable answers at a fraction of the compute power.

Looking to the future, Reinders stressed the importance of collaboration between different computational technologies.

I think quantum computing as it matures will become another form of supercomputing. It will join the fold rather than replace existing technologies, he said. This integration will enhance our ability to tackle complex problems, from climate forecasting to disease modeling.

Reinders concluded by reflecting on the broader implications of these advancements.

The biggest cost in running a computer is moving data around, Reinders noted, highlighting the ongoing efforts to improve data transfer efficiency and reduce power consumption.

These enhancements will boost performance and make high-performance computing more accessible and cost-effective.

Reinders, then, gave us a peek of what the future in high-performance computing, quantum computing and artificial intelligence looks like and how it will work toward achieving innovative solutions to problems that were almost insurmountable by the human race in the past.

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MIT’s Diamond Qubits Redefine the Future of Quantum Computing – SciTechDaily

Researchers developed a modular fabrication process to produce a quantum-system-on-chip that integrates an array of artificial atom qubits onto a semiconductor chip. Credit: Sampson Wilcox and Linsen Li, RLE, edited

A new quantum-system-on-chip enables the efficient control of a large array of qubits, advancing toward practical quantum computing.

Researchers at MIT and MITRE have developed a scalable, modular quantum hardware platform, incorporating thousands of qubits on a single chip, promising enhanced control and scalability. Utilizing diamond color centers, this new architecture supports extensive quantum communication networks and introduces an innovative lock-and-release fabrication process to efficiently integrate these qubits with existing semiconductor technologies.

Imagine being able to quickly solve extremely complex problems that might take the worlds most powerful supercomputer decades to crack. This is the promise of quantum computers.

However, realizing this capability requires constructing a system with millions of interconnected building blocks called qubits. Making and controlling so many qubits in a hardware architecture is an enormous challenge that scientists around the world are striving to meet.

Toward this goal, researchers at MIT and MITRE have demonstrated a scalable, modular hardware platform that integrates thousands of interconnected qubits onto a customized integrated circuit. This quantum-system-on-chip (QSoC) architecture enables the researchers to precisely tune and control a dense array of qubits. Multiple chips could be connected using optical networking to create a large-scale quantum communication network.

By tuning qubits across 11 frequency channels, this QSoC architecture allows for a new proposed protocol of entanglement multiplexing for large-scale quantum computing.

The team spent years perfecting an intricate process for manufacturing two-dimensional arrays of atom-sized qubit microchiplets and transferring thousands of them onto a carefully prepared complementary metal-oxide semiconductor (CMOS) chip. This transfer can be performed in a single step.

We will need a large number of qubits, and great control over them, to really leverage the power of a quantum system and make it useful. We are proposing a brand new architecture and a fabrication technology that can support the scalability requirements of a hardware system for a quantum computer, says Linsen Li, an electrical engineering and computer science (EECS) graduate student and lead author of a paper on this architecture.

Lis co-authors include Ruonan Han, an associate professor in EECS, leader of the Terahertz Integrated Electronics Group, and member of the Research Laboratory of Electronics (RLE); senior author Dirk Englund, professor of EECS, principal investigator of the Quantum Photonics and Artificial Intelligence Group and of RLE; as well as others at MIT, Cornell University, the Delft Institute of Technology, the U.S. Army Research Laboratory, and the MITRE Corporation. The paper was published recently in Nature.

While there are many types of qubits, the researchers chose to use diamond color centers because of their scalability advantages. They previously used such qubits to produce integrated quantum chips with photonic circuitry.

Qubits made from diamond color centers are artificial atoms that carry quantum information. Because diamond color centers are solid-state systems, the qubit manufacturing is compatible with modern semiconductor fabrication processes. They are also compact and have relatively long coherence times, which refers to the amount of time a qubits state remains stable, due to the clean environment provided by the diamond material.

In addition, diamond color centers have photonic interfaces which allows them to be remotely entangled, or connected, with other qubits that arent adjacent to them.

The conventional assumption in the field is that the inhomogeneity of the diamond color center is a drawback compared to identical quantum memory like ions and neutral atoms. However, we turn this challenge into an advantage by embracing the diversity of the artificial atoms: Each atom has its own spectral frequency. This allows us to communicate with individual atoms by voltage tuning them into resonance with a laser, much like tuning the dial on a tiny radio, says Englund.

This is especially difficult because the researchers must achieve this at a large scale to compensate for the qubit inhomogeneity in a large system.

To communicate across qubits, they need to have multiple such quantum radios dialed into the same channel. Achieving this condition becomes near-certain when scaling to thousands of qubits. To this end, the researchers surmounted that challenge by integrating a large array of diamond color center qubits onto a CMOS chip which provides the control dials. The chip can be incorporated with built-in digital logic that rapidly and automatically reconfigures the voltages, enabling the qubits to reach full connectivity.

This compensates for the in-homogenous nature of the system. With the CMOS platform, we can quickly and dynamically tune all the qubit frequencies, Li explains.

To build this QSoC, the researchers developed a fabrication process to transfer diamond color center microchiplets onto a CMOS backplane at a large scale.

They started by fabricating an array of diamond color center microchiplets from a solid block of diamond. They also designed and fabricated nanoscale optical antennas that enable more efficient collection of the photons emitted by these color center qubits in free space.

Then, they designed and mapped out the chip from the semiconductor foundry. Working in the MIT.nano cleanroom, they post-processed a CMOS chip to add microscale sockets that match up with the diamond microchiplet array.

They built an in-house transfer setup in the lab and applied a lock-and-release process to integrate the two layers by locking the diamond microchiplets into the sockets on the CMOS chip. Since the diamond microchiplets are weakly bonded to the diamond surface, when they release the bulk diamond horizontally, the microchiplets stay in the sockets.

Because we can control the fabrication of both the diamond and the CMOS chip, we can make a complementary pattern. In this way, we can transfer thousands of diamond chiplets into their corresponding sockets all at the same time, Li says.

The researchers demonstrated a 500-micron by 500-micron area transfer for an array with 1,024 diamond nanoantennas, but they could use larger diamond arrays and a larger CMOS chip to further scale up the system. In fact, they found that with more qubits, tuning the frequencies actually requires less voltage for this architecture.

In this case, if you have more qubits, our architecture will work even better, Li says.

The team tested many nanostructures before they determined the ideal microchiplet array for the lock-and-release process. However, making quantum microchiplets is no easy task, and the process took years to perfect.

We have iterated and developed the recipe to fabricate these diamond nanostructures in MIT cleanroom, but it is a very complicated process. It took 19 steps of nanofabrication to get the diamond quantum microchiplets, and the steps were not straightforward, he adds.

Alongside their QSoC, the researchers developed an approach to characterize the system and measure its performance on a large scale. To do this, they built a custom cryo-optical metrology setup.

Using this technique, they demonstrated an entire chip with over 4,000 qubits that could be tuned to the same frequency while maintaining their spin and optical properties. They also built a digital twin simulation that connects the experiment with digitized modeling, which helps them understand the root causes of the observed phenomenon and determine how to efficiently implement the architecture.

In the future, the researchers could boost the performance of their system by refining the materials they used to make qubits or developing more precise control processes. They could also apply this architecture to other solid-state quantum systems.

Reference: Heterogeneous integration of spinphoton interfaces with a CMOS platform by Linsen Li, Lorenzo De Santis, Isaac B. W. Harris, Kevin C. Chen, Yihuai Gao, Ian Christen, Hyeongrak Choi, Matthew Trusheim, Yixuan Song, Carlos Errando-Herranz, Jiahui Du, Yong Hu, Genevieve Clark, Mohamed I. Ibrahim, Gerald Gilbert, Ruonan Han and Dirk Englund, 29 May 2024, Nature. DOI: 10.1038/s41586-024-07371-7

This work was supported by the MITRE Corporation Quantum Moonshot Program, the U.S. National Science Foundation, the U.S. Army Research Office, the Center for Quantum Networks, and the European Unions Horizon 2020 Research and Innovation Program.

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Could 3-day workweeks be possible thanks to advanced quantum computing? – Euronews

Could a three-day week be the routine of an average European with advanced quantum computing? We spoke with experts on the continent.

When Emma Mller, a 44-year-old German woman, wakes up each morning, she already has a detailed plan for her health status, dietary suggestions, and exercise recommendations to optimise her day.

She also works only three days a week, thanks to her high productivity levels.

Will we ever live Mllers idyllic life? Is this the promised heaven of a future foretold by advanced quantum computing? When will it happen? Will it be our generation or the ones to come?

For now, it remains pure science fiction, speculation rooted in the promise of advanced quantum technology.

What is real is that IBM's first European Quantum Data Centre is expected to be operational in Ehningen, Germany, by the end of 2024.

"Europe has some of the world's most advanced users of quantum computers," said Jay Gambetta, Vice President of IBM Quantum.

Euronews Tech Talks has interviewed quantum computing experts across the continent to provide a current perspective.

Frank William Marshall, a theoretical physicist at the cultural center of Munich and a leader at the European Quantum Technology Flagship, oversees projects developing quantum computing hardware systems.

He says strong development is happening in superconducting platforms in Delft (Netherlands), Munich and Jlich (Germany), Gothenburg (Sweden), and Helsinki (Finland).

Javier Aizpurua, the Scientific Director of Basque Quantum, notes that IBM will deploy its sixth quantum computer in the world next year in the Basque Country, in northern Spain".

The Basque ecosystem is characterized by strong, fundamental research in materials science, physics, chemistry, and materials engineering.

This foundation was crucial when exploring the potential of deploying a quantum computer to aid in computing and designing these materials, physical processes, and chemical compounds".

Ignacio Cirac, Director at the Max Planck Institute of Quantum Optics, said "there are many expectations surrounding quantum computation in the media and industry.

"However, it's very difficult to turn these expectations into reality," he added. "It's crucial that people have the patience to wait for these developments to materialise".

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