Postselection-free experimental observation of the measurement-induced phase transition in circuits with universal gates

TL;DR

This paper demonstrates a method to observe the measurement-induced phase transition in quantum circuits without postselection, using a tree-structured circuit with Haar-random unitaries, enabling practical experimental detection and theoretical analysis.

Contribution

The authors introduce a postselection-free protocol for detecting the MIPT using tree circuits with classical decoding, bridging the gap between theory and experiment.

Findings

Successfully observed MIPT on a trapped-ion quantum computer.

The classical decoding complexity scales linearly with system size.

Provided an exact theoretical description of the MIPT, including critical point and scaling.

Abstract

Monitored many-body systems can exhibit a phase transition between entangling and disentangling dynamical phases by tuning the strength of measurements made on the system as it evolves. This phenomenon is called the measurement-induced phase transition (MIPT). Understanding the properties of the MIPT is a prominent challenge for both theory and experiment at the intersection of many-body physics and quantum information. Realizing the MIPT experimentally is particularly challenging due to the postselection problem, which demands a number of experimental realizations that grows exponentially with the number of measurements made during the dynamics. Proposed approaches that circumvent the postselection problem typically rely on a classical decoding process that infers the final state based on the measurement record. But the complexity of this classical process generally also grows exponentially with the system size unless the dynamics is restricted to a fine-tuned set of unitary operators. In this work we overcome these difficulties. We construct a tree-shaped quantum circuit whose nodes are Haar-random unitary operators followed by weak measurements of tunable strength. For these circuits, we show that the MIPT can be detected without postselection using only a simple classical decoding process whose complexity grows linearly with the number of qubits. Our protocol exploits the recursive structure of tree circuits, which also enables a complete theoretical description of the MIPT, including an exact solution for its critical point and scaling behavior. We experimentally realize the MIPT on Quantinuum's H1-1 trapped-ion quantum computer and show that the experimental results are precisely described by theory. Our results close the gap between analytical theory and postselection-free experimental observation of the MIPT.