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1. Finite image homomorphisms of the braid group and its generalizations

   https://doi.org/10.1017/S0017089523000022  

   Scherich, Nancy; Verberne, Yvon (March 2023, Glasgow Mathematical Journal)

   Abstract. Using totally symmetric sets, Chudnovsky–Kordek–Li–Partin gave a superexponential lower bound on the cardinality of non-abelian finite quotients of the braid group. In this paper, we develop new techniques using multiple totally symmetric sets to count elements in non-abelian finite quotients of the braid group. Using these techniques, we improve the lower bound found by Chudnovsky et al. We exhibit totally symmetric sets in the virtual and welded braid groups and use our new techniques to find superexponential bounds for the finite quotients of the virtual and welded braid groups. 

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2. Pure braid group actions on category $$\mathcal{O}$$ modules

   https://doi.org/10.4310/PAMQ.2024.v20.n1.a3  

   Appel, Andrea; Toledano Laredo, Valerio (January 2024, Pure and Applied Mathematics Quarterly)

   Let be a symmetrisable Kac–Moody algebra and Uhg its quantised enveloping algebra. Answering a question of P. Etingof, we prove that the quantum Weyl group operators of Uhg give rise to a canonical action of the pure braid group of g on any category O (not necessarily integrable) module. By relying on our recent results, we show that this action describes the monodromy of the rational Casimir connection on the Uhg-module corresponding to V. We also extend these results to yield equivalent representations of parabolic pure braid groups on parabolic category for Uhg and g. 

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3. Dyonic bound states

   https://doi.org/10.1007/JHEP03(2025)042  

   Hook, Anson; Ristow, Clayton (March 2025, Journal of High Energy Physics)

   A<sc>bstract</sc> We study (multi) fermion - monopole bound states, many of which are the states that dyons adiabatically transition into as fermions become light. The properties of these bound states depend critically on the UV symmetries preserved by the fermion mass terms, their relative size, and the value ofθ. Depending on the relative size of the mass terms and the value ofθ, the bound states can undergo phase transitions as well as transition from being stable to unstable. In some simple situations, the bound state solution can be related to the Witten effect of another theory with fewer fermions and larger gauge coupling. These bound states are a result of mass terms and symmetry breaking boundary conditions at the monopole core and, consequently, these bound states do not necessarily have definite quantum numbers under accidental IR symmetries. Additionally, they have binding energies that are$$ \mathcal{O}(1) $$ $O\left(1\right)$times the fermion mass and bound state radii of order their inverse mass. As the massless limit is approached, the bound state radii approach infinity, and they become new asymptotic states with odd quantum numbers giving a dynamical understanding to the origin of semitons. 

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4. Efficient Quantum Algorithms for Testing Symmetries of Open Quantum Systems

   https://doi.org/10.1142/S1230161223500178  

   Bandyopadhyay, Rahul; Rubin, Alex H.; Radulaski, Marina; Wilde, Mark M. (November 2023, Open Systems & Information Dynamics)

   Symmetry is an important and unifying notion in many areas of physics. In quantum mechanics, it is possible to eliminate degrees of freedom from a system by leveraging symmetry to identify the possible physical transitions. This allows us to simplify calculations and characterize potentially complicated dynamics of the system with relative ease. Previous works have focused on devising quantum algorithms to ascertain symmetries by means of fidelity-based symmetry measures. In our present work, we develop alternative symmetry testing quantum algorithms that are efficiently implementable on quantum computers. Our approach estimates asymmetry measures based on the Hilbert–Schmidt distance, which is significantly easier, in a computational sense, than using fidelity as a metric. The method is derived to measure symmetries of states, channels, Lindbladians, and measurements. We apply this method to a number of scenarios involving open quantum systems, including the amplitude damping channel and a spin chain, and we test for symmetries within and outside the finite symmetry group of the Hamiltonian and Lindblad operators. 

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5. Log-canonical coordinates for symplectic groupoid and cluster algebras

   https://doi.org/10.1093/imrn/rnac101  

   Chekhov, L.; Shapiro, M. (January 2022, International mathematics research notices)

   Using Fock--Goncharov higher Teichmüller space variables we derive Darboux coordinate representation for entries of general symplectic leaves of the A_n groupoid of upper-triangular matrices and, in a more general setting, of higher-dimensional symplectic leaves for algebras governed by the reflection equation with the trigonometric R-matrix. The obtained results are in a perfect agreement with the previously obtained Poisson and quantum representations of groupoid variables for A_3 and A_4 in terms of geodesic functions for Riemann surfaces with holes. We represent braid-group transformations for A_n via sequences of cluster mutations in the special A_n-quiver. We prove the groupoid relations for quantum transport matrices and, as a byproduct, obtain the Goldman bracket in the semiclassical limit. 

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