Q&A: Searching for the Quantumness of Gravity

In my opinion, quantum gravity tackles one of the most fundamental questions of physics: what is spacetime? In tackling this question, I helped unearth surprising connections between quantum gravity, many-body physics, and quantum information. These connections truly fascinate me.

To model quantum effects in matter, like entanglement, I use so-called tensor networks—mathematical tools that describe patterns of quantum correlations among the states of a large number of interacting particles. My breakthrough—and my interest in quantum gravity— came when I realized that these tensor-network tools might also be applied to describe the physics of gravity.

The connection with gravity is possible thanks to an important theoretical result obtained about 20 years ago by string physicist Juan Maldacena. He proposed the so-called AdS/CFT (anti de Sitter/conformal field theory) correspondence, which states that for every quantum system with gravity there exists an exactly equivalent system without gravity. This result means that researchers could potentially study a universe with gravity by modeling a simpler, gravityless universe. One promising gravityless quantum system for such studies is an ensemble of quantum particles with carefully tailored interactions—a system very similar to the condensed-matter ones I describe using tensor networks. I am exploring this possibility with others via a multidisciplinary collaboration called “It from Qubit.”

The collaboration name is a play on the late Princeton physicist John Wheeler’s phrase “it from bit,” which he used to epitomize the idea that every physical quantity—every “it” in the universe—derives its significance from binary bits of information. His idea was almost correct, but it didn’t consider the full quantum nature of information, hence the qubits. “It from Qubit” brings together quantum information scientists and high-energy physicists, two communities that normally don’t communicate with each other. Together, we develop a new language and new tools to explore the links between quantum information and the physical theories that describe our Universe. One idea developing from the collaboration is that spacetime could emerge from entanglement.

The idea is that gravity could emerge from interacting qubits much like a phase of matter can emerge from interacting electrons. We don’t yet have a clear idea of what these qubits could be. But several independent results hint at a similar conclusion: many-body correlations among elementary quantum mechanical objects could lead to the same geometry of spacetime as the one on which general theory of relativity is based.

Long-term, blue-sky funding from “It from Qubit” has been essential. It’s not the kind of research where funders get fast returns on their dollars so it can be hard to get individual grants. Teaching has also been extremely valuable—questions from young people approaching these problems for the first time bring me a fresh perspective. What’s more, the need to convey my ideas to others has a powerful clarifying effect.

I would like to bring quantum gravity theories to the point that they can be tested in experiments.

Cold atoms are an exceptional platform to engineer and control quantum states. They could be used to build networks of fermions that interact with each other in a specific way, realizing the so-called Sachdev-Ye-Kitaev model. As a version of AdS/CFT, this system would be equivalent to a universe with quantum gravity. There are no conceptual barriers for these experiments, but they pose serious engineering challenges. Still, I am confident that researchers will be carrying out these experiments within a decade.

Know a physicist with a knack for explaining their research to others? Write to physics@aps.org. All interviews are edited for brevity and clarity.