Using qudits, Rochester scientists have solved a notoriously difficult problem involving Hilbert space, or the quantum matrix.
Quantum computers have the potential to revolutionize computing by solving complex problems that stump even today鈥檚 fastest machines. Scientists are exploring whether quantum computers could one day help streamline global supply chains, create ultra-secure encryption to protect sensitive data against even the most powerful cyberattacks, or even develop more effective drugs by simulating their behavior at the atomic level.
But building efficient quantum computers isn鈥檛 just about developing faster chips or better hardware. It also requires a deep understanding of quantum mechanics鈥攖he strange rules that govern the tiniest building blocks of our universe such as atoms and electrons鈥攁nd how to effectively move information through quantum systems.
In a paper published in , a team of physicists鈥攊ncluding graduate student Elizabeth Champion and assistant professor from the 鈥檚 鈥攐utlined a method to address a tricky problem in quantum computing: how to efficiently move information within a multi-level system using quantum units called qudits.
鈥淓fficiently controlling a qudit processor has been a long-standing challenge,鈥 says Champion, the paper鈥檚 first author. 鈥淭he methods we developed allow the core operations of a qudit-based quantum computer to be performed in far fewer steps, making full use of the hardware. This can potentially enable quantum computations and simulations that were not possible before.鈥
Inside Hilbert space鈥攁ka the quantum matrix
In the 1999 sci-fi movie The Matrix, the main character Neo sees the world not as physical objects such as streets and skyscrapers but as a stream of 1s and 0s鈥攖he raw data underlying his reality. In quantum physics, there is a similar underlying framework beneath the familiar world of particles and forces. This matrix is called Hilbert space.
In classical computers, information lives in specific places on a chip. But in quantum computers, information isn鈥檛 tied to a specific location. Instead, it lives in the more abstract world of Hilbert space, a massive mathematical landscape. Here, particles aren鈥檛 just tiny dots zipping around but also abstract waves of probability, existing in many locations and states at once. Although Hilbert space is not something you can see or locate in the physical computer chip, it鈥檚 where the computational power of quantum computing happens.
鈥淭he mathematical structure that we use to represent a state of a quantum computer and a calculation is literally a matrix,鈥 Blok says. 鈥淭he goal for a quantum computer is to efficiently move information around in that matrix.鈥
Beyond bits and qubits
Moving information through the abstract mathematical landscape of Hilbert space is no small feat. To do this, scientists rely on quantum building blocks called qubits鈥攁nd, more powerfully, qudits.
While classical computers transport information using billions of tiny switches called bits, quantum computers typically move information through Hilbert space using qubits鈥攓uantum bits that can exist in multiple states at once. In classical systems, each bit is either a 鈥0鈥 (off) or a 鈥1鈥 (on). Qubits, however, are governed by the strange laws of quantum mechanics and can be both 鈥0鈥 and 鈥1鈥 at the same time.
But even qubits have their limits. Blok likens qubits to 鈥渂uilding a sprawling city with too many roads, such as Los Angeles.鈥 His research introduces a fundamentally different approach to moving information within Hilbert space using qudits, which can store more information in a single location. In other words, qudits go beyond 鈥0s鈥 and 鈥1s鈥 and might have three or more states (鈥0,鈥 鈥1,鈥 鈥2,鈥 etc.) in which to encode information. This makes the architecture more like 鈥渁 dense, high-rise city such as New York,鈥 he says.
The new method developed by Blok and Champion employs 鈥渢he largest qudit and the most efficient method to operate it,鈥 Blok says. The method is inspired by nuclear magnetic resonance, a technique that uses magnetic fields to manipulate a quantum property of particles called 鈥渟pins.鈥
鈥淚t鈥檚 like connecting all the floors of a high-rise building simultaneously,鈥 Blok says. 鈥淏y tapping into techniques from big-spin physics, we’ve discovered a much more efficient way to route quantum information within each qudit, potentially unlocking faster, more scalable quantum computers with far fewer operational bottlenecks.鈥
