
Cryptography
contributed
Mon, 31 Aug 2026, 11:30 - 11:30
- Randomness from causally independent processesMartin Sandfuchs (ETH Zurich); Carla Ferradini (ETH Zurich); Renato Renner (ETH Zurich)[abstract]Abstract: We consider a pair of causally independent processes, modelled as the tensor product of two channels, acting on a possibly correlated input to produce random outputs X and Y. We show that, assuming the processes produce a sufficient amount of randomness, one can extract uniform randomness from X and Y. This generalizes prior results, which assumed that X and Y are (conditionally) independent. Note that in contrast to the independence of quantum states, the independence of channels can be enforced through spacelike separation. As a consequence, our results allow for the generation of randomness under more practical and physically justifiable assumptions than previously possible. We illustrate this with the example of device-independent randomness amplification, where we can remove the constraint that the adversary only has access to classical side information about the source.
- A complexity theory for non-local quantum computationAndreas Bluhm (Univ. Grenoble Alpes, CNRS, Grenoble INP, LIG); Simon Höfer (Univ. Grenoble Alpes, CNRS, Grenoble INP, LIG); Alex May (Perimeter Institute for Theoretical Physics); Mikka Stasiuk (Perimeter Institute for Theoretical Physics); Philip Verduyn Lunel (Sorbonne Université, Paris); Henry Yuen (Columbia University)[abstract]Abstract: Non-local quantum computation (NLQC) replaces a local interaction between two systems with a single round of communication and shared entanglement. Despite many partial results, it is known that a characterization of entanglement cost in at least certain NLQC tasks would imply significant breakthroughs in complexity theory. Here, we avoid these obstructions and take an indirect approach to understanding resource requirements in NLQC, which mimics the approach used by complexity theorists: we study the relative hardness of different NLQC tasks by identifying resource efficient reductions between them. Most significantly, we prove that $f$-measure and $f$-route, the two best studied NLQC tasks, are in fact equivalent under $O(1)$ overhead reductions. This result simplifies many existing proofs in the literature and extends several new properties to $f$-measure. For instance, we obtain sub-exponential upper bounds on $f$-measure for all functions, and efficient protocols for functions in the complexity class $\mathsf{Mod}_k\mathsf{L}$. Beyond this, we study a number of other examples of NLQC tasks and their relationships.
