Researchers are proposing a new blueprint for quantum simulation utilizing arrays of helium-3 atoms, potentially achieving speeds three times faster than current systems based on lithium-6. The design, from Zheyuan Li of the University of Illinois Urbana-Champaign and colleagues, leverages the lighter mass of helium-3 to accelerate quantum tunneling, allowing for more complex calculations within the limits of atomic coherence. Unlike previous methods that relied solely on atomic position, this system encodes information in both positional and vibrational states, simulating both bosonic modes and fermionic lattice dynamics. The team reports in PRX Quantum that the large energy spacings between vibrational modes of helium-3 make it easy to convert an atom to an intended mode without accidentally exciting it to other levels. Beyond simulation, these helium-3 arrays could also enable precise fundamental measurements, including determining the size of atomic nuclei.
This potential for accelerated quantum simulations hinges on a novel approach utilizing helium-3 atoms, as detailed in theoretical work published in PRX Quantum. This departs from earlier methods that relied exclusively on positional data, offering a more comprehensive platform for complex calculations. The lighter mass of helium-3 enables a quantum tunneling rate approximately three times faster than that demonstrated with lithium-6, the next lightest trappable species, promising quicker processing speeds. The researchers’ design employs optical tweezers to trap helium-3 atoms held in a long-lived metastable state, ensuring stability during computation. These meticulously controlled helium-3 arrays offer a pathway to fundamental measurements previously limited by precision, and the team suggests they could be used to determine the size of atomic nuclei with greater accuracy, allowing for direct comparison with existing theoretical predictions. Science writer Sophia Chen notes that this capability extends the utility of the system beyond computational modeling, potentially refining our understanding of nuclear physics and atomic structure.
Quantum simulation currently relies on manipulating arrays of neutral atoms to model other quantum systems, but the coherence time of these atoms presents a significant barrier to increasing simulation complexity. This system departs from earlier methods by encoding information not only in the positional arrangement of the atoms, but also in their vibrational states; the vibrational states can simulate bosonic modes, while the atoms’ motion throughout the lattice can simulate fermionic lattice dynamics. This dual functionality, complex simulation and precise metrology, positions helium-3 arrays as a versatile tool for advancing quantum science.
