# “Gauge Theory” Science-Research, November 2021 — summary from Astrophysics Data System, DOE Pages and Springer Nature

## Astrophysics Data System — summary generated by Brevi Assistant

In this paper, by utilizing a recently located great void service in the framework of the Poincaré gauge theory of gravity, we study gravitational lensing for a system where the lens is a fixed spherically symmetric black hole. By examining the formulas of motion for light rays in a spacetime with torsion, we acquire the deflection angle as the light given off from a source goes through near the black hole and numerically resolve the resulting important. We compute the Π_u and Σ_u^- hybrid fixed possibilities in SU latticework gauge theory making use of 4 various latticework spacings ranging from a = 0.040 fm to a = 0.093 fm. We introduce a class of non-invertible topological problems in d gauge theories whose combination regulations are the higher-dimensional analogs of those of the Kramers-Wannier flaw in the d critical Ising model. The low-lying Dirac settings end up being localized at the finite-temperature change in QCD and in other gauge theories, recommending a basic connection between their localisation and deconfinement. We examined SU gauge area theory with N_f=24 quarks. We examine the mass range of the theory as the quark mass is varied and obtain scaling legislation for meson masses and string tension. We consider two-dimensional N= supersymmetric gauge theory on discretized Riemann surfaces. We expand the exact same debate to the non-Abelian theory and show that the course important minimizes multiple integrals of Abelian concepts at the localization set points.

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## Source texts:

- https://ui.adsabs.harvard.edu/abs/2021MPLA.3650226Z/abstract
- https://ui.adsabs.harvard.edu/abs/2021arXiv211100741S/abstract
- https://ui.adsabs.harvard.edu/abs/2021arXiv211101141K/abstract
- https://ui.adsabs.harvard.edu/abs/2021arXiv211015293B/abstract
- https://ui.adsabs.harvard.edu/abs/2021arXiv211101618R/abstract
- https://ui.adsabs.harvard.edu/abs/2021arXiv211100676O/abstract

## DOE Pages — summary generated by Brevi Assistant

We explain the phase layout of a 2 +1-dimensional SU gauge theory of varying incommensurate spin density waves for the hole-doped cuprates. The confining stage of the gauge theory is a traditional Fermi liquid with a big Fermi surface. For the electron-doped cuprates, the spin density wave variations go to wave vector, and afterwards the matching SU gauge theory only has a crossover in between the confining and Higgs routines, with a greatly large confinement range deep in the Higgs program. We think about basic 5d SU quiver gauge theories whose nodes develop an ADE Dynkin layout of type G. Each node has SU gauge group of general rank, Chern-Simons degree κ i and extra w i basics. When the overall flavor number at each node is less than or equivalent to 2N i-2|κ i |, we provide basic policies under which the balances linked to instanton currents are enhanced to G × G or a subgroup of it in the UV 5d superconformal theory. In certain we find a huge course of gauge theories analyzed as S1 compactification of 6d superconformal concepts which are waiting for string/F-theory awareness. We take into consideration the problem of specifying local subsystems in gauge theory and gravity. We present a general formalism to link a gauge-invariant timeless stage space to a spatial piece with limit by introducing new levels of freedom on the border. In basic relativity, the new degrees of liberty are the location of a codimension-2 surface area and a selection of conformal regular structure. Quantum information theory and highly correlated electron systems share a typical theme of macroscopic quantum complication. Influenced by these connections, in this paper we introduce an easy model for fermions moving in the deconfined phase of a ℤ_2 gauge theory by coupling Kitaev’s toric code to mobile fermions. We lay out how the fermionic toric code can be carried out as a quantum circuit, hence giving a vital link between quantum materials and quantum info theory.

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## Source texts:

## Springer Nature — summary generated by Brevi Assistant

We identify the big N limits of four-dimensional supersymmetric gauge theories with simple gauge teams that move to superconformal taken care of points. We locate a standard on the matter content for the fixed point theory to have either a dense or sparse spectrum. This is the second in a two-part paper devoted to studying complication worsening and edge settings in the A model topological string theory. We reveal that under the Gopakumar-Vafa duality, the mass complexity branes are mapped to an arrangement of topological D-branes, and the non-local complexity limit condition in the bulk is mapped to a local limit problem in the gauge theory dual. We present a new, basic approach to gauge theory on principal G -spectral triples, where G is a compact connected Lie team. We introduce an idea of vertical Riemannian geometry for G-C^* C ∗ -algebras and show that the resulting noncommutative orbitwise family of Kostant’s cubic Dirac operators defines an all-natural unbounded KK^G K G -cycle when it comes to a principal G -action. We recommend a fascinating BPS/CFT document play ground: the correlation function of two converging half-BPS surface area flaws in four-dimensional N 𝒩 = 2 supersymmetric SU gauge theory with 2 N basic hypermultiplets. Its Fourier change is the 5-point conformal block of the sl ̂ N 𝔰̂𝔩̂_N present algebra with among the vertex operators representing the N -dimensional sl N 𝔰𝔩_N representation, which we demonstrate with the help of the Knizhnik-Zamolodchikov formula. We suggest a brittle damage model based on linearized kinematic measures obtained utilizing a gauge theory. Utilizing linearization of the completely nonlinear kinematic actions, we get an energy useful which is square in the field variables and such an energy is stable relative to the neighborhood gauge changes. We researched fixed magnetic sensitivity χ χ in SU lattice gauge theory with N_f = 2 N f = 2 light flavours of dynamical fermions at limited chemical prospective μ μ. Making use of linear response theory, we find that SU gauge theory displays paramagnetic habits in both the high-temperature deconfined program and the low-temperature confining regime.

*Please keep in mind that the text is machine-generated by the Brevi Technologies’ Natural language Generation model, and we do not bear any responsibility. The text above has not been edited and/or modified in any way.*

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