Quantum Brilliance CEO Discusses the Future of Quantum Computing with Synthetic Diamonds

 Quantum Brilliance CEO Discusses the Future of Quantum Computing with Synthetic Diamonds

Highlights:

• Quantum Brilliance leads in quantum computing innovation using synthetic diamonds.
• The company’s rapid growth stems from its spin-out from the Australian National University (ANU).
• Quantum Brilliance’s technology offers miniaturized, energy-efficient quantum computers.
• Quantum at the edge promises to revolutionize industries like healthcare, defense, and AI.
• Partnerships with global leaders, including Oak Ridge National Laboratory, are paving the way for groundbreaking advancements.

---

Pioneering Quantum Computing with Synthetic Diamonds

Quantum Brilliance, led by CEO Mark Luo, is making waves in the world of quantum computing by leveraging synthetic diamonds to create miniaturized, energy-efficient quantum computers. Unlike conventional quantum computers that require massive cooling systems, Quantum Brilliance’s diamond-based quantum computers operate at room temperature, making them more adaptable to various environments, from satellites to submarines.

Mark Luo explained in an interview, "We're using synthetic diamond as the material to maintain quantum bits without needing large fridges or high-power lasers. This approach allows for quantum systems to be deployed anywhere, normalizing quantum technology for everyday applications."

A Rapidly Growing Company with Australian Roots

Quantum Brilliance's journey began as a spin-out from the Australian National University (ANU), a global leader in diamond quantum technology. Since its inception in 2020, the company has experienced rapid growth, boasting a global workforce of 85 staff across three countries. According to Luo, this success is largely thanks to Australia’s robust research infrastructure.

“We've signed about $50 million in contracts across industries such as supercomputing, defense, and aerospace. This wouldn't have been possible without Australia's support from institutions like ANU, La Trobe, and RMIT,” Luo added.

Transforming Quantum Computing at the Edge

Quantum Brilliance’s approach is revolutionizing the concept of quantum computing at the edge, a technology that could dramatically enhance industries by enabling faster, more accurate processing closer to the data source. This could range from healthcare diagnostics to driverless systems.

Mark Luo explained the potential: "Quantum technology could enable more sophisticated processing, even at the edge, transforming industrial robotics, satellites, and autonomous vehicles by enhancing their decision-making capabilities in real-time."

A Commercially Viable Quantum Future

Quantum Brilliance's innovations offer distinct commercial advantages, with projections estimating the quantum computing market could reach $100 billion, with edge applications constituting half of that. Additionally, quantum sensing, another area of focus, is expected to be a $10 billion market.

Luo gave a concrete example: “Imagine every electric vehicle being equipped with a quantum sensor for better battery management. With millions of EVs set to be sold by the decade’s end, the potential for quantum sensing at the edge is enormous.”

Collaborating with Oak Ridge National Laboratory

Quantum Brilliance is actively working with global leaders, including a key partnership with Oak Ridge National Laboratory in Tennessee, to advance quantum computing applications. This collaboration aims to deploy the first on-premise quantum computer cluster, helping to explore the possibilities of quantum computation.

Luo shared his excitement: "Having a physical quantum computer on-premise allows us to engage with real applications. The discoveries we make here will shape the future of quantum technology."

Supporting Australia's Semiconductor Industry

Quantum Brilliance is also a strong advocate for Australia’s semiconductor industry. The company is a major supporter of the Semiconductor Australia 2024 conference, working alongside organizations like S3B to uplift Australia’s role in the global semiconductor value chain. As the semiconductor market is poised to hit $1 trillion by the end of the decade, Australia has an opportunity to take a share of this massive industry.

Luo emphasized, “Australia has world-class semiconductor engineers, and by connecting with global leaders in quantum technology, we can carve out a competitive advantage in this fast-growing market.”

Source: Quantum computers and diamonds | Finance News Network (finnewsnetwork.com.au)

 

Advancing Science: Microsoft and Quantinuum Achieve Breakthrough in Quantum Computing

Introduction

In a groundbreaking collaboration, Microsoft and Quantinuum have achieved a significant milestone in the field of quantum computing. By combining Microsoft’s innovative qubit-virtualization system with Quantinuum’s cutting-edge ion-trap hardware, they have demonstrated the most reliable logical qubits on record. This achievement promises to revolutionize scientific research and industry applications, unlocking new possibilities for solving complex problems.

The Quest for Reliable Quantum Computing

Quantum computing holds immense promise for tackling some of humanity’s most pressing challenges, from climate change to drug discovery. However, the inherent fragility of quantum bits (qubits) has been a major hurdle. Physical qubits are susceptible to errors due to environmental noise and other factors, limiting their reliability.

The Breakthrough

Microsoft’s qubit-virtualization system, coupled with error diagnostics and correction, has transformed the landscape. Here are the key highlights:

1. Logical Qubits: Unlike physical qubits, logical qubits are robust and resilient. By applying the qubit-virtualization system, Microsoft and Quantinuum achieved an error rate 800 times better than physical qubits.

2. 14,000 Error-Free Experiments: The joint effort involved running over 14,000 individual experiments without encountering a single error. This remarkable feat demonstrates the stability and reliability of the logical qubits.

3. Quantum Computation Without Destruction: Traditionally, diagnosing and correcting errors in quantum systems required destroying the qubits. However, this breakthrough allows for error diagnostics and corrections without compromising the qubits’ integrity.

Moving Beyond NISQ to Resilient Quantum Computing

The current state of quantum computing is often referred to as Noisy Intermediate-Scale Quantum (NISQ). With the successful demonstration of reliable logical qubits, we are now entering Level 2 Resilient quantum computing. This advancement paves the way for more robust quantum algorithms and applications.

The Path Forward

A hybrid supercomputing system powered by 100 reliable logical qubits would significantly impact scientific research. Scaling up to 1,000 reliable logical qubits could unlock commercial advantages. Imagine simulating complex molecular interactions, optimizing supply chains, or revolutionizing drug discovery—all powered by quantum computing.

Azure Quantum Elements Preview

For those eager to explore these capabilities, advanced features based on logical qubits will be available in private preview for Azure Quantum Elements customers in the coming months. Researchers, innovators, and industry leaders can harness the power of quantum computing to accelerate their work.

Conclusion

The collaboration between Microsoft and Quantinuum represents a leap forward in quantum computing reliability. As we continue to refine and expand our understanding of logical qubits, we move closer to a future where quantum solutions drive positive change across various domains. From fundamental scientific research to practical applications, the era of reliable quantum computing is upon us.

Learn more about this achievement in the official Microsoft blog post.

Australian Government Invested A$26 million for Development of Advanced Quantum Computing

A$26 million for development of advanced quantum computing

12 Feb 2016

The Australian Government recently announced an investment of A$26 million over five years to support the development of advanced quantum computingin Australia.

[caption id="attachment_729" align="aligncenter" width="563"]                            Australian Government Invested A$26 million for             Development of  Advanced Quantum Computing[/caption]

The funding, part of the new National Innovation & Science Agenda initiative, is being given to the Centre for Quantum Computation and Communications Technology (CQC2T) at the University of New South Wales (NSW).

The Centre is at the forefront of the race to build the world’s first functioning quantum computer.

In classic computing, information is represented in one of two states, either zero or one. In quantum computing, information can be stored in a large number of different states at the same time, meaning that quantum computers will have the astonishing potential to solve in minutes problems that now take conventional computers hundreds of years to process.

In October last year, the team at CQC2T announced a major quantum computing breakthrough, which was reported around the world. The NSW scientists found a way to incorporate quantum computing technology into silicon-based computer chips.

A significant advance and widely regarded, this has been reported as the first step in developing a practical quantum computing system because silicon, the building block of modern electronic devices, is cheap, easy to manufacture, and already widely available.

Quantum computing will have a transformational effect on the world as we know it today: the capacity to find information at lightning speed within a massive dataset will be a game changer in many fields, including aeronautics, finance, information technology, medicine and security.

‘It’s the space race of the computing era,’ says Professor Michelle Simmons, Director of the CQC2T at the University of New South Wales.

News Release Source : A$26 million for development of advanced quantum computing

Image Credit : UNSW