Condensed Matter Theory

Skyrmions in twisted bilayer graphene: stability, pairing, and crystallization

(2021)

Authors:

Yves H Kwan, Glenn Wagner, Nick Bultinck, Steven H Simon, SA Parameswaran

s-wave paired electron and hole composite fermion trial state for quantum Hall bilayers with ν=1

Physical Review Letters American Physical Society 127 (2021) 246803

Abstract:

We introduce a new variational wave function for a quantum Hall bilayer at total filling νT=1, which is based on s-wave BCS pairing between electron composite fermions in one layer and hole composite fermions in the other. In addition, we reexamine a trial wave function based on p-wave BCS pairing between electron composite fermions in both layers. We compute the overlap of the optimized trial functions with the ground state from exact diagonalization calculations of up to 14 electrons in a spherical geometry, and we find excellent agreement over the entire range of values of the ratio between the layer separation and the magnetic length. The s-wave trial wave function naturally allows for charge imbalance between the layers and provides important insights into how the physics at large interlayer separations crosses over to that at small separations in a fashion analogous to the BEC-BCS crossover.

Microscopic characterization of Ising conformal field theory in Rydberg chains

Physical Review B: Condensed matter and materials physics American Physical Society 104:23 (2021) 235109

Authors:

Kevin Slagle, David Aasen, Hannes Pichler, Roger SK Mong, Paul Fendley, Xie Chen, Manuel Endres, Jason Alicea

Abstract:

Rydberg chains provide an appealing platform for probing conformal field theories (CFTs) that capture universal behavior in a myriad of physical settings. Focusing on a Rydberg chain at the Ising transition separating charge density wave and disordered phases, we establish a detailed link between microscopics and low-energy physics emerging at criticality. We first construct lattice incarnations of primary fields in the underlying Ising CFT including chiral fermions, a nontrivial task given that the Rydberg chain Hamiltonian does not admit an exact fermionization. With this dictionary in hand, we compute correlations of microscopic Rydberg operators, paying special attention to finite, open chains of immediate experimental relevance. We further develop a method to quantify how second-neighbor Rydberg interactions tune the sign and strength of four-fermion couplings in the Ising CFT. Finally, we determine how the Ising fields evolve when four-fermion couplings drive an instability to Ising tricriticality. Our results pave the way to a thorough experimental characterization of Ising criticality in Rydberg arrays, and can inform the design of novel higher-dimensional phases based on coupled critical chains.

Stochastic dynamics of chemotactic colonies with logistic growth

EPL (Europhysics Letters) IOP Publishing 136:5 (2021) 50003

Authors:

Riccardo Ben Alì Zinati, Charlie Duclut, Saeed Mahdisoltani, Andrea Gambassi, Ramin Golestanian

Learning developmental mode dynamics from single-cell trajectories.

eLife 10 (2021) e68679

Authors:

Nicolas Romeo, Alasdair Hastewell, Alexander Mietke, Jörn Dunkel

Abstract:

Embryogenesis is a multiscale process during which developmental symmetry breaking transitions give rise to complex multicellular organisms. Recent advances in high-resolution live-cell microscopy provide unprecedented insights into the collective cell dynamics at various stages of embryonic development. This rapid experimental progress poses the theoretical challenge of translating high-dimensional imaging data into predictive low-dimensional models that capture the essential ordering principles governing developmental cell migration in complex geometries. Here, we combine mode decomposition ideas that have proved successful in condensed matter physics and turbulence theory with recent advances in sparse dynamical systems inference to realize a computational framework for learning quantitative continuum models from single-cell imaging data. Considering pan-embryo cell migration during early gastrulation in zebrafish as a widely studied example, we show how cell trajectory data on a curved surface can be coarse-grained and compressed with suitable harmonic basis functions. The resulting low-dimensional representation of the collective cell dynamics enables a compact characterization of developmental symmetry breaking and the direct inference of an interpretable hydrodynamic model, which reveals similarities between pan-embryo cell migration and active Brownian particle dynamics on curved surfaces. Due to its generic conceptual foundation, we expect that mode-based model learning can help advance the quantitative biophysical understanding of a wide range of developmental structure formation processes.