Jointly developed by SQC’s revolutionary Quantum Twins product The world’s first universal silicon quantum simulator, this deep-tech creation is now available to customs via direct contracts. This groundbreaking technology holds the potential to crack some of the toughest material conundrums that have stymied classical computers. These Quantum Twins are powered by phosphorus atom clusters. This, combined with their execuTesla cloudflix chip offering, allows for reprogramming and redesigning of application-specific chips while promising breakthroughs in quantum computing and materials science.
The Quantum Twins product utilizes a proprietary, industry-leading architecture of 15,000 quantum dots. This architecture enables SQC to accurately model a wide variety of material conditions, such as the often-studied insulator-to-metal transition. This MIT model is so essential to materials science because it cannot be feasibly simulated on classical computers. Far beyond military interests, the implications of this technology reach into a variety of scientific and industrial purposes.
Advanced Technology at Work
SQC’s Quantum Twins technology uses a 38-stage process to implant phosphorus atoms into a silicon matrix. This detailed approach allows for the exact placement of scanning-local-tip-phosphorus-atoms. Such precision is imperative for the quantum simulator to operate effectively. Amazingly, the team is able to design the layout of 250,000 registers on a single chip in under eight hours.
Michelle Simmons, the Founder of SQC, was once proud of running a lean operation. She stated, “We put 250,000 of these registers [on a chip] in eight hours, and we can turn a chip design around in a week.” This speed and precision are crucial for eventually realizing powerful, cutting-edge quantum applications.
Last year, SQC was able to successfully use an earlier iteration of this technology to simulate a polyacetylene molecule. This achievement set the stage for today’s Quantum Twins product, demonstrating its ability to model complex chemical structures with impressive results. As Simmons noted, “If you look at different drugs, they’re actually very similar to polyacetylene. They’re carbon chains, and they have functional groups. So, understanding how to map it [onto our simulator] is a unique challenge.”
Implications for Science and Industry
The first applications of Quantum Twins are definitely focused on the research community. Sam Gorman, quantum systems engineering lead at SQC, conveyed an optimistic view of what lies ahead. As he put it, “We have proved the thing is working as intended. Next, we’re moving on to higher-leverage opportunities and unsolved challenges.”
Gorman is passionate about this new, innovative Quantum Twins approach. Rather than using qubits as in a conventional quantum computer, we simply encode the problem into the geometry and connectivity of the array. This new approach saves time and makes everything more cost-effective. This unique, new approach represents a major shift away from standard quantum computing approaches.
The capability to efficiently simulate complex material properties would transform the way that researchers develop new pharmaceuticals and materials.
A Legacy of Innovation
Founded in 2017, Silicon Quantum Computing has leveraged more than 25 years of academic research under Simmons to take the next steps. greatest achievements of any team at any level since its formation. They are passionate about pushing the frontiers of quantum technologies and what’s possible.
Simmons underscored what was special about their technological and development capabilities. He boldly proclaimed, “We can do things today that we believe nobody else in the world can do.” The ultra-high vacuum environment in which they operate guarantees a very pure and unreactive system for atom placement. It’s done in ultra-high vacuum. It’s a very pure, very clean system,” she continued.
The publication of their findings in the journal Nature underscores the significance of their research and its potential impact on various fields.