How The Quantum Switch Confirms Indefinite Causal Order

Knowing Indefinite Causal Order

Classical philosophy says cause precedes effect. However, quantum mechanics allows events to occur in a superposition of possibilities, creating an indeterminate causal order. It appears events are not chronological.

Many consider the quantum switch, which applies two operations to a target system in a superposition of orders, the classic example. This theory has significant implications for quantum information processing problems like channel identification, query complexity, and communication over noisy channels.

The Need for Device-Independent Certification

Years of experimental experiments, including the quantum switch, have proven indefinite causal order using lab apparatus presumptions. A certification that is independent of the device is highly desired in order to provide more solid and persuasive verification of these phenomena.

By eliminating reliance on assumptions on the internal operations of the apparatus, this approach increases the validity of findings by depending solely on the statistics of measurement outcomes, much like the violation of a Bell inequality certifies Bell nonlocality. Prior studies had suggested that, when seen in isolation, the quantum switch might not be able to provide such device-independent certification.

A Theory Breakthrough: 2023 Nature Communications Tein van der Lugt, Jonathan Barrett, and Giulio Chiribella’s September 2023 publication in Nature Communications marked a major advancement towards device-independent certification. This study proposes a novel inequality to guarantee indefinite causal order in the quantum switch device-independently.

Their method adds a second spacelike-separated observer to the typical causal inequality scenario. The framework, which describes the DRF polytope as statistical correlations, has three main assumptions:

Definite Causal Order: A partial causal order between the four agents Alice 1 (A₁), Alice 2 (A₂), Bob (B), and Charlie (C) is defined by the premise that a hidden variable (λ) exists for every experiment run. Only in this order may causes spread.

Relativistic Causality: This weaker causality theory maintains the experiment's lightcone structure within the established causal ordering (λ). Charlie operates in Alice 1 and 2's future lightcone, ruling out retrocausation, while Bob's involvement is spacelike-separated, ruling out superluminal causation. This assumption and Free Interventions imply parameter independence for Bell's theorem, but the stronger Bell Locality is not imposed.

Free Interventions: According to this assumption, the agents’ measurement settings have no pertinent causes; they are contingent on λ and statistically independent of the results of agents that are not part of their causal future. This eliminates signals outside the causal sequence.

All correlations that meet these three requirements must satisfy a certain inequality that the researchers came up with (Theorem 1, known as Inequality 6 in the source). The inequality for binary settings and results is: p(b=0, a₂=x₁ | y=0) + p(b=1, a₁=x₂ | y=0) + p(b⊕c=yz | x₁=x₂=0) ≤ 7/4

They showed that the quantum switch violates this new inequality even if it does not break previously thought-of causal inequalities when isolated. With Alice’s measure-and-prepare instruments and a maximally entangled state between the control qubit (C) and Bob’s system (B) in their suggested configuration (Fig. 3 in the source), the quantum switch produces a value of roughly 1.8536, which is much higher than the classical limit of 7/4 (1.75).

In order for Bob and Charlie to violate a CHSH inequality, Bob’s outcome must be simultaneously correlated with Charlie’s measurements and the presumed causal order. This underpins this infringement. Since it distinguishes these inequalities from conventional causal inequalities, which can be broken by classical processes, this link to Bell nonlocality is essential.

Recent Experimental Verification: The 2025 Quantum

On June 23, 2025, Quantum News published an article about a new experimental confirmation of indefinite causal order that is device-independent, building on these theoretical developments and current research. The University of Vienna team led by Carla M. D. Lee A. Richter, Philip Walther, Huan Cao, Michael Antesberger, and Huan Cao. Rozema published a paper titled “Towards an Experimental Device-Independent Verification of Indefinite Causal Order” that described their progress.

Their work effectively used a technique that is completely independent of devices to demonstrate indefinite causal order. In order to create a situation where two events could occur in a superposition of ordering, this experiment used a quantum switch to guide photons over a network. The experimental violation of a Bell-like inequality, with a value of 2.78, was the main discovery.

The non-classical phenomena of indefinite causal order is statistically supported by this result, which surpasses the classical limit by an astounding 24 standard deviations. This study demonstrates that quantum systems are capable of displaying behaviours in which the temporal sequence of events is not fixed.

Implications for Quantum Technology and Fundamental Physics Wide-ranging effects result from these developments in the confirmation of indeterminate causal order. Practically speaking, modifying causal structures may open up new computing paradigms that could improve the capabilities of quantum algorithms and result in the development of more secure and effective quantum communication protocols.

Although the majority of existing quantum switch

implementations rely on optical interferometric setups, it is still up for discussion whether these experiments actually achieve the quantum switch or only imitate it from a fundamental physics standpoint. Even yet, experimental violations of these novel device-independent inequalities may limit the range of plausible, observationally consistent theories of quantum gravity.

In order to better understand the interaction between indefinite causal order and other quantum effects, future research will try to scale up similar experiments to more complicated systems.The certification method, which was motivated by recent findings in Wigner’s friend situations, also implies that it may be used to the certification of other quantum phenomena. The effort to fully utilise quantum causality’s strange yet potent character for upcoming technology advancements and a better comprehension of reality is still ongoing.