Abstract
The leading finite-volume and thermal effects, arising in numerical lattice QCD calculations of {a}_{mu}^{mathrm{HVP},mathrm{LO}}equiv {left(g-2right)}_{mu}^{mathrm{HVP},mathrm{LO}}/2 , are determined to all orders with respect to the interactions of a generic, relativistic effective field theory of pions. In contrast to earlier work [1] based in the finite-volume Hamiltonian, the results presented here are derived by formally summing all Feynman diagrams contributing to the Euclidean electromagnetic-current two-point function, with any number of internal pion loops and interaction vertices. As was already found in ref. [1], the leading finite-volume corrections to {a}_{mu}^{mathrm{HVP},mathrm{LO}} scale as exp[−mL] where m is the pion mass and L is the length of the three periodic spatial directions. In this work we additionally control the two sub-leading exponentials, scaling as exp[− sqrt{2} mL] and exp[− sqrt{3} mL]. As with the leading term, the coefficient of these is given by the forward Compton amplitude of the pion, meaning that all details of the effective theory drop out of the final result. Thermal effects are additionally considered, and found to be sub-percent-level for typical lattice calculations. All finite-volume corrections are presented both for {a}_{mu}^{mathrm{HVP},mathrm{LO}} and for each time slice of the two-point function, with the latter expected to be particularly useful in correcting small to intermediate current separations, for which the series of exponentials exhibits good convergence.
Highlights
The anomalous magnetic moment of the muon, (g − 2)μ, has become a central focus in the broader particle physics community, due to significant tension between the best experimental [2, 3] and theoretical determinations [4,5,6,7]
In contrast to earlier work [1] based in the finite-volume Hamiltonian, the results presented here are derived by formally summing all Feynman diagrams contributing to the Euclidean electromagneticcurrent two-point function, with any number of internal pion loops and interaction vertices
If x0 is kept constant while T and L are sent to infinity, the two-point function has the following expansion
Summary
Before describing the skeleton expansion required to bring the preceding decompositions into a useful form, we comment here on the differences between finite-volume corrections of the electromagnetic-current two-point function, G(x0|T, L), and the integral defining aHμ VP,LO(T, L). This is because values of x0 that scale proportionally to T contribute to the integral so that for any given diagram, D, and gauge orbit, n, the two contributions, IT,L(D, n) and FT,L(x0|D, n), can have different asymptotic behavior To identify corrections to G(x0|T, L) directly, one can repeat the entire analysis as described for aHμ VP,LO but with a Dirac delta function in place of K(x0) This does modify the location of the saddle point, such that some terms that survive with a power-like kernel turn out to be subleading in this special case. The only leading finite-T scaling comes from the wrapped-pion contribution of eq (3.69)
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