Abstract
QED with a large number $N$ of massless fermionic degrees of freedom has a conformal phase in a range of space-time dimensions. We use a large $N$ diagrammatic approach to calculate the leading corrections to $C_T$, the coefficient of the two-point function of the stress-energy tensor, and $C_J$, the coefficient of the two-point function of the global symmetry current. We present explicit formulae as a function of $d$ and check them versus the expectations in 2 and $4-\epsilon$ dimensions. Using our results in higher even dimensions we find a concise formula for $C_T$ of the conformal Maxwell theory with higher derivative action $F_{\mu \nu} (-\nabla^2)^{\frac{d}{2}-2} F^{\mu \nu}$. In $d=3$, QED has a topological symmetry current, and we calculate the correction to its two-point function coefficient, $C^{\textrm{top}}_{J}$. We also show that some RG flows involving QED in $d=3$ obey $C_T^{\rm UV} > C_T^{\rm IR}$ and discuss possible implications of this inequality for the symmetry breaking at small values of $N$.
Highlights
In d = 3, QED has a topological symmetry current, and we calculate the correction to its two-point function coefficient, CJtop
RG flows involving QED in d = 3 obey CTUV > CTIR and discuss possible implications of this inequality for the symmetry breaking at small values of N
In the physically interesting dimension d = 3, this corresponds to an even number 2Nf of two-component Dirac fermions
Summary
The action for Maxwell theory coupled to Nf massless charged fermions in flat Euclidean space. One may develop the 1/N expansion of the theory by integrating out the fermions [15, 23] This produces an effective action for the gauge field of the form. When d < 4, one sees that the non-local kinetic term in (2.2) is dominant in the low momentum (IR) limit compared to the two-derivative Maxwell term The latter can be dropped at low energies, and one may develop the 1/N expansion of the critical theory by using the induced quadratic term. Note that this effective action is gauge invariant as it should, due to conservation of the current.
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