Exploring uncharted territory: physicists discover endless possibilities of quantum states

A spin (blue ball with arrow) interacts with surrounding bosons described by non-Gaussian states – a new computational method to accurately describe what happens inside quantum devices. Credit: Jiří Minář

A new method developed by Amsterdam researchers uses non-Gaussian states to efficiently describe and configure quantum spin-boson systems, promising advances in quantum computing and feeling.

Many modern quantum devices operate using arrays of qubits or spins, which have only two energy states: ‘0’ and ‘1’. However, in current devices, these spins also interact with photons and phonons, collectively known as bosons, making the calculations much more complex. In a recent study published in Physical review papers, researchers from Amsterdam have developed a method to effectively describe these spin-boson systems. This discovery could help efficiently deploy quantum devices to achieve specific desired states.

Quantum devices use the strange behavior of quantum particles to perform tasks that go beyond what ‘classical’ machines can do, including quantum computing, simulation, sensing, communication and metrology. These devices can take many forms, such as a collection of superconducting circuits, or a lattice of atoms or ions held in place by lasers or electric fields.

Regardless of their physical realization, quantum devices are usually described in simplified terms as a collection of quantum bits or two-level interacting spins. However, these spins also interact with other things in their surroundings, such as light in superconducting circuits or oscillations in the lattice of atoms or ions. Particles of light (photons) and vibrational modes of a lattice (phonons) are examples of bosons.

Innovative descriptions of quantum states

Unlike spins, which have only two possible energy levels (‘0’ or ‘1’), the number of levels for each boson is infinite. Consequently, there are very few computational tools for describing spins associated with bosons. In their new work, physicists Liam Bond, Arghavan Safavi-Naini and Jiří Minář of the University of Amsterdam, QuSoft and Centrum Wiskunde & Informatica work around this limitation by describing systems composed of spins and bosons using so-called non-Gaussian states . . Each non-Gaussian state is a combination (a superposition) of much simpler Gaussian states.

Each blue-red pattern in the image above represents a possible quantum state of the spin-boson system. “A Gaussian state would look like a plain red circle, without any interesting blue-red patterns,” explains PhD candidate Liam Bond. An example of a Gaussian state is laser light, in which all light waves are perfectly in sync. “If we take a lot of these Gaussian states and start overlapping them (so they’re in an overlap), these beautifully complicated patterns emerge. We were particularly excited because these non-Gaussian states allow us to store a lot from the powerful mathematical machinery that exists for Gaussian states, while enabling us to describe a much more diverse set of quantum states.

Bond continues: “There are so many possible patterns that classical computers often struggle to calculate and process them. Instead, in this publication we use a method that identifies the most important of these patterns and ignores the others. This allows us to study these quantum systems and create new ways of preparing interesting quantum states.”

The new approach can be exploited to efficiently prepare quantum states in a way that outperforms other traditionally used protocols. “Rapid quantum state preparation can be useful for a wide range of applications, such as quantum simulation or even quantum error correction,” notes Bond. The researchers also demonstrate that they can use non-Gaussian states to prepare ‘critical’ quantum states that correspond to a system undergoing a phase transition. Besides the fundamental interest, such states can significantly increase the sensitivity of quantum sensors.

While these results are very encouraging, they are only a first step towards more ambitious goals. So far, the method has been demonstrated for a single rotation. A natural but challenging extension is to include many spins and many bosonic modes simultaneously. A parallel direction is to consider environmental effects that perturb spin-boson systems. Both of these approaches are under active development.

Reference: “Fast Quantum State Preparation and Bath Dynamics Using Non-Gaussian Variation Ansatz and Optimal Quantum Control” by Liam J. Bond, Arghavan Safavi-Naini and Jiří Minář, 23 April 2024, Physical review papers.
DOI: 10.1103/PhysRevLett.132.170401