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Fractional statistics give rise to quantum behaviors that differ fundamentally from those of bosons and fermions. While two-dimensional anyons play a major role in strongly correlated systems and topological quantum computing, the nature of their one-dimensional (1D) counterparts remains the subject of intense debate, with renewed interest fueled by recent experimental progress. Theoretically, 1D anyons are predicted to host exotic many-body phases and quantum phase transitions, yet experimental signatures have remained elusive. Using ultracold atoms in an optical lattice, we prepare two-body ground states of the 1D anyon-Hubbard model by combining Hamiltonian engineering via quasiperiodic drives and adiabatic state manipulation. We uncover the effects of statistical interactions that lead to pseudo-fermionization and to the formation of chiral bound states when particles remain close together. Our results establish a link between lattice and continuum realizations of anyon models, and mark important steps towards the precise control of 1D anyons in both equilibrium and out-of-equilibrium settings.

Postdoc Sandra Brandstetter has joined the Erbium lab. Welcome, Sandra!

Postdoc Eunice Lee has joined the Rubidium lab. Welcome, Eunice!

Recent work in Nature from the lithium lab, reaches unprecedentedly low temperatures in the Hubbard model, bringing quantum simulations into a regime where they can be truly useful for addressing open questions in material science and condensed matter physics, and where classical simulations are at their limit.

Graduate students Alex Deters and Annie Zhi have joined the Greiner lab. Welcome!