Condensed Matter Theory

Probabilistic Genotype-Phenotype Maps Reveal Mutational Robustness of RNA Folding, Spin Glasses, and Quantum Circuits

ArXiv 2301.01847 (2023)

Authors:

Anna Sappington, Vaibhav Mohanty

Data for "Spin skyrmion gaps as signatures of strong-coupling insulators in magic-angle twisted bilayer graphene"

University of Oxford (2023)

Authors:

Siddharth Ashok Parameswaran, Jiachen Yu, Benjamin A Foutty, Yves H Kwan, Mark E Barber, Kenji Watanabe, Takashi Taniguchi, Zhi-Xun Shen, Benjamin E Feldman

Abstract:

This is the experimental data for the paper "Spin skyrmion gaps as signatures of strong-coupling insulators in magic-angle twisted bilayer graphene", to appear in Nature Communications.

Topological Quantum

, 2023

Abstract:

At the intersection of physics, mathematics, and computer science, an exciting new field of study has formed, known as “topological quantum.” This research field examines the deep connections between the theory of knots, special types of subatomic particles known as anyons, certain phases of matter, and quantum computation. This book elucidates this nexus, drawing in topics ranging from quantum gravity to topology to experimental condensed matter physics. Requiring only an elementary background in quantum mechanics, this book is appropriate for all readers, from advanced undergraduates to the professional practitioner. The material in presented in a down-to-earth and entertaining way that is far less abstract than most of what is in the literature. While introducing the crucial concepts and placing them in context, the subject is presented without resort to the highly mathematical category theory that underlies the field. This book will be of interest to mathematicians and computer scientists as well as physicists working on a wide range of topics. “Topological quantum” has increasingly been a focus point in the fields of condensed matter physics and quantum information over the last few decades, and the forefront of research now builds on the basic ideas presented in this book. Those interested in working in these field will find this book to be an invaluable introduction as well as a crucial reference.

Utilizing bifurcations to separate particles in spiral inertial microfluidics

Physics of Fluids AIP Publishing 35:1 (2023) 011703

Authors:

Rahil N Valani, Brendan Harding, Yvonne M Stokes

Non-reciprocal multifarious self-organization.

Nature nanotechnology 18:1 (2023) 79-85

Authors:

Saeed Osat, Ramin Golestanian

Abstract:

A hallmark of living systems is the ability to employ a common set of building blocks that can self-organize into a multitude of different structures. This capability can only be afforded in non-equilibrium conditions, as evident from the energy-consuming nature of the plethora of such dynamical processes. To achieve automated dynamical control of such self-assembled structures and transitions between them, we need to identify the fundamental aspects of non-equilibrium dynamics that can enable such processes. Here we identify programmable non-reciprocal interactions as a tool to achieve such functionalities. The design rule is composed of reciprocal interactions that lead to the equilibrium assembly of the different structures, through a process denoted as multifarious self-assembly, and non-reciprocal interactions that give rise to non-equilibrium dynamical transitions between the structures. The design of such self-organized shape-shifting structures can be implemented at different scales, from nucleic acids and peptides to proteins and colloids.