Proton and neutron electromagnetic form factors from lattice QCD in the continuum limit

TL;DR

This study calculates proton and neutron electromagnetic form factors using lattice QCD with physical quark masses, multiple lattice spacings, and advanced noise reduction techniques to accurately extract physical observables in the continuum limit.

Contribution

It provides the first continuum-limit lattice QCD results for nucleon electromagnetic form factors at physical quark masses, including detailed analysis of excited states and disconnected contributions.

Findings

Proton electric radius: 0.860(38)(23) fm

Neutron magnetic moment: -1.819(76)(29)

Results agree with experimental values within errors

Abstract

We compute the electromagnetic form factors of the proton and neutron using lattice QCD. We employ $N_\mathrm{f}$=2+1+1 twisted mass clover-improved fermions with quark masses tuned to their physical values. Three ensembles with lattice spacings of $a$=0.080 fm, 0.068 fm, and 0.057 fm, and approximately the same physical volume allow us to obtain the continuum limit directly at the physical pion mass. For each ensemble, we use several values of the sink-source time separation, ranging from 0.5 fm to 1.5 fm, to allow for a thorough analysis of excited state effects via multi-state fits. The disconnected contributions are also analyzed using high statistics combined with techniques to mitigate stochastic noise in the estimation of the fermion loop. These techniques include low-mode deflation, dilution in the color and spin components, and hierarchical probing. We study the momentum transfer dependence of the form factors using the $z$-expansion and dipole Ans\"atze, thereby enabling the extraction of the electric and magnetic radii and the magnetic moments, as well as the Zemach and Friar radii in the continuum limit. Results for the proton and neutron electric and magnetic mean square radii are $\sqrt{\langle r_E^2\rangle^p} = 0.860(38)(23)$ fm, $\langle r_E^2\rangle^n = -0.147(48)$ fm$^2$, $\sqrt{\langle r_M^2\rangle^p} = 0.870(53)(15)$ fm and $\sqrt{\langle r_M^2\rangle^n} = 0.913(67)(19)$ fm, and for the proton and neutron magnetic moments $\mu^p=2.849(92)(52)$ and $\mu^n=-1.819(76)(29)$, respectively. In all cases, the first error is statistical and the second systematic, where the latter includes an estimate of the error from the fits to the momentum dependence of the form factors and from the continuum extrapolation.