Fermions in boundary conformal field theory: crossing symmetry and E-expansion

Christopher P. Herzog; Vladimir Schaub

doi:10.1007/JHEP02(2023)129

Fermions in boundary conformal field theory: crossing symmetry and E-expansion

Christopher P. Herzog, Vladimir Schaub^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

13 Citations (Scopus)

Abstract

We use the equations of motion in combination with crossing symmetry to constrain the properties of interacting fermionic boundary conformal field theories. This combination is an efficient way of determining operator product expansion coefficients and anomalous dimensions at the first few orders of the ϵ expansion. Two necessary ingredients for this procedure are knowledge of the boundary and bulk spinor conformal blocks. The bulk spinor conformal blocks are derived here for the first time. We then consider a number of examples. For ϕ a scalar field and ψ a fermionic field, we study the effects of a ϕψ¯ ψ coupling in 4 – ϵ dimensions, a ϕ²ψ¯ ψ coupling in 3 – ϵ dimensions, and a (ψ¯ ψ) ² coupling in 2 + ϵ dimensions. We are able to compute some new anomalous dimensions for operators in these theories. Finally, we relate the anomalous dimension of a surface operator to the behavior of the charge density near the surface.

Original language	English
Article number	129
Journal	Journal of High Energy Physics
Volume	2023
Issue number	2
DOIs	https://doi.org/10.1007/JHEP02(2023)129
Publication status	Published - Feb 2023

Keywords

Renormalization Group
Scale and Conformal Symmetries

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10.1007/JHEP02(2023)129

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abstract = "We use the equations of motion in combination with crossing symmetry to constrain the properties of interacting fermionic boundary conformal field theories. This combination is an efficient way of determining operator product expansion coefficients and anomalous dimensions at the first few orders of the ϵ expansion. Two necessary ingredients for this procedure are knowledge of the boundary and bulk spinor conformal blocks. The bulk spinor conformal blocks are derived here for the first time. We then consider a number of examples. For ϕ a scalar field and ψ a fermionic field, we study the effects of a ϕψ¯ ψ coupling in 4 – ϵ dimensions, a ϕ2ψ¯ ψ coupling in 3 – ϵ dimensions, and a (ψ¯ ψ) 2 coupling in 2 + ϵ dimensions. We are able to compute some new anomalous dimensions for operators in these theories. Finally, we relate the anomalous dimension of a surface operator to the behavior of the charge density near the surface.",

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AU - Herzog, Christopher P.

AU - Schaub, Vladimir

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AB - We use the equations of motion in combination with crossing symmetry to constrain the properties of interacting fermionic boundary conformal field theories. This combination is an efficient way of determining operator product expansion coefficients and anomalous dimensions at the first few orders of the ϵ expansion. Two necessary ingredients for this procedure are knowledge of the boundary and bulk spinor conformal blocks. The bulk spinor conformal blocks are derived here for the first time. We then consider a number of examples. For ϕ a scalar field and ψ a fermionic field, we study the effects of a ϕψ¯ ψ coupling in 4 – ϵ dimensions, a ϕ2ψ¯ ψ coupling in 3 – ϵ dimensions, and a (ψ¯ ψ) 2 coupling in 2 + ϵ dimensions. We are able to compute some new anomalous dimensions for operators in these theories. Finally, we relate the anomalous dimension of a surface operator to the behavior of the charge density near the surface.

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KW - Scale and Conformal Symmetries

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JO - Journal of High Energy Physics

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Fermions in boundary conformal field theory: crossing symmetry and E-expansion

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