AbstractThe neutron is a cornerstone in our depiction of the visible universe. Despite the neutron zero-net electric charge, the asymmetric distribution of the positively- (up) and negatively-charged (down) quarks, a result of the complex quark-gluon dynamics, lead to a negative value for its squared charge radius, $$\langle {r}_{{\rm{n}}}^{2}\rangle$$
⟨
r
n
2
⟩
. The precise measurement of the neutron’s charge radius thus emerges as an essential part of unraveling its structure. Here we report on a $$\langle {r}_{{\rm{n}}}^{2}\rangle$$
⟨
r
n
2
⟩
measurement, based on the extraction of the neutron electric form factor, $${G}_{{\rm{E}}}^{{\rm{n}}}$$
G
E
n
, at low four-momentum transfer squared (Q2) by exploiting the long known connection between the N → Δ quadrupole transitions and the neutron electric form factor. Our result, $$\langle {r}_{{\rm{n}}}^{2}\rangle =-0.110\pm 0.008\,({{\rm{fm}}}^{2})$$
⟨
r
n
2
⟩
=
−
0.110
±
0.008
(
fm
2
)
, addresses long standing unresolved discrepancies in the $$\langle {r}_{{\rm{n}}}^{2}\rangle$$
⟨
r
n
2
⟩
determination. The dynamics of the strong nuclear force can be viewed through the precise picture of the neutron’s constituent distributions that result into the non-zero $$\langle {r}_{{\rm{n}}}^{2}\rangle$$
⟨
r
n
2
⟩
value.