UK startup Phasecraft says its new THRIFT algorithm makes quantum simulations 10 times larger and longer, potentially unlocking major breakthroughs in materials, energy, and climate tech.
Breakthrough
Phasecraft, a Bristol- and London-based quantum computing startup, has announced what it calls the most significant leap yet in quantum simulation efficiency. Its new algorithm, THRIFT, allows simulations to run for ten times longer and at ten times the scale, a breakthrough that could accelerate discoveries in battery storage, sustainable materials, and climate-critical technologies.
Removes Limitations From Quantum Simulations
The advancement, published in Nature Communications, improves how quantum computers simulate complex physical systems. Unlike classical computers, which struggle to handle the vast number of possibilities within quantum mechanics, quantum computers are uniquely suited to model the changing behaviour of particles and molecules, but they’ve been limited by short run times and error-prone results. That’s what THRIFT aims to fix.
What Are Quantum Simulations And Why Do They Matter?
Quantum simulations are a way of using quantum computers to model how physical systems behave and change over time, especially at the atomic and molecular level. This includes things like how molecules interact in a new medicine, or how the internal structure of a battery changes as it charges and discharges. The value of such simulations is that they let scientists observe outcomes before running costly or time-consuming experiments in the real world.
Promising For Sustainability
The potential for more efficient quantum simulations is especially powerful for sustainability challenges. For example:
– Creating more efficient batteries by simulating materials at the quantum level.
– Designing catalysts for cleaner hydrogen production.
– Modelling carbon capture processes or low-impact construction materials.
However, until now, simulations on quantum hardware have been severely limited, often too small or too short to provide truly useful data.
What Makes Phasecraft’s ‘THRIFT’ Approach Different?
THRIFT, which stands for Trotter Heuristic Resource Improved Formulas for Time-dynamics, is Phasecraft’s new method for breaking down and simulating complex quantum systems more efficiently. The core idea lies in how quantum simulations evolve over time. Traditional methods divide these evolutions into small time steps using a “Trotter” formula. The problem is that they treat all interactions equally, which bloats the simulation and leads to unnecessary operations.
“Existing methods are slow, resource-intensive, and struggle to scale,” says Raul Santos, Lead Quantum Scientist at Phasecraft. “They use a high number of quantum gates to maintain accuracy, but this becomes impractical as the simulation grows.”
However, THRIFT counters these issues by prioritising the parts of the system that matter most. For example, some interactions evolve more slowly or contribute less to the overall behaviour of the system, so THRIFT allocates fewer computational resources to them. This streamlined process dramatically reduces the number of quantum operations required, cutting errors and allowing for much longer and more detailed simulations.
Simulations 10x Larger and 10x Longer
In trials, THRIFT improved estimates for a widely used benchmark in quantum physics, the one-dimensional transverse-field Ising model, achieving simulations 10x larger and 10x longer than with standard methods, without increasing circuit size or computational cost.
Built for Today’s Quantum Machines
One of the key strengths of THRIFT is that it works on today’s imperfect quantum computers and is not just designed for the powerful machines of the future. Quantum hardware is still ‘noisy’, meaning it’s prone to errors and has limited capacity. Phasecraft’s innovation, however, appears to be in designing software that maximises what’s possible even on current-generation devices.
“We’ve shown a 10x increase on today’s machines,” says Santos. “And we’d expect this to only get better as hardware advances and quantum computers become better at tolerating errors.”
Focusing On Working With Today’s Hardware
Rather than waiting for quantum hardware to mature, Phasecraft appears to be focusing on making the most of what’s available today. The hope is that this approach will put the company in a strong position as Big Tech continues to pour investment into next-generation quantum processors, including Google’s Willow chip, Microsoft’s Majorana platform, and Amazon’s Ocelot. As Phasecraft’s Raul Santos says: “This algorithm enhances efficiency on near-term devices, like those Google and Microsoft have announced,” and that “Any improvements in their performance can only enhance our approach.”
Real-World Impact
The theory is that the longer and more detailed the simulation, the better scientists can understand how a system behaves and ultimately design better materials and molecules. This means Phasecraft’s THRIFT breakthrough could open the door to real-world applications in areas where incremental efficiency gains could have massive sustainability impacts. For example, as Phasecraft CEO and co-founder Ashley Montanaro says:
“Work by Raul and the team has delivered the highest-performance quantum algorithms known for simulating some prominent and well-studied physical systems. This improvement will push us closer to real-world quantum applications in materials science, chemistry, and beyond.”
Examples of areas where it could make a real difference include:
– Energy Storage. More accurate simulations of battery chemistries could reduce the need for rare and environmentally damaging materials.
– Pharmaceuticals. Simulating molecular interactions more precisely could speed up drug development and reduce lab waste.
– Manufacturing. Discovering lighter or more durable materials through simulation can lower emissions across supply chains.
The point is that it’s not just about speed, but it’s about being able to run simulations that were previously impossible. This could fundamentally reshape how innovation happens in sectors critical to net-zero goals.
Challenges and Next Steps
Despite the reported progress, Phasecraft’s achievement doesn’t mean quantum simulations are ready for widespread commercial use just yet. THRIFT has so far been tested on a simplified benchmark, i.e. the Ising model which, while important, doesn’t fully represent the complexity of real-world systems.
There’s also the broader challenge of access. Running quantum simulations still requires deep technical expertise and partnerships with hardware providers. Although Phasecraft collaborates with companies like Google, IBM, and QuEra, the barrier to entry remains high for most organisations.
Energy use is another factor. While quantum computers promise efficiency gains in the long run, current machines require cryogenic cooling and specialised environments, which come with their own environmental footprint. For now, those costs must be weighed against the potential gains in simulation efficiency.
What Does This Mean For Your Organisation?
In enabling longer, larger, and more efficient simulations on existing hardware, Phasecraft’s THRIFT algorithm essentially brings practical quantum applications closer, particularly in areas such as energy storage, materials design, and low-impact manufacturing.
For UK businesses and organisations, this could pave the way for faster development of green technologies, from energy storage systems and new materials to more efficient chemical processes. Companies working in advanced manufacturing, cleantech, and pharmaceuticals could benefit from earlier and more accurate testing and from reducing the risks and costs involved in developing sustainable solutions. As the UK looks to maintain its edge in science-led innovation, the ability to work with cutting-edge quantum tools, developed on home soil, could also become a valuable strategic asset.
In essence here, rather than simply accepting the limitations of current quantum hardware and waiting for future machines to deliver breakthroughs, Phasecraft’s work shows that smart software (grounded in real scientific insight) can start delivering value now. That approach could influence how other startups, institutions and governments think about the role of quantum technologies in addressing real-world challenges, from climate resilience to resource efficiency.
That said, there’s still a long way to go. Scaling these simulations to solve complex, real-world problems will require further advances in both algorithms and hardware. Access to quantum platforms remains limited, and widespread commercial adoption is still some way off. However, by closing the gap between theoretical potential and practical application, Phasecraft’s THRIFT algorithm brings quantum computing one step closer to playing a meaningful role in shaping a more sustainable future.