The helion charge radius from laser spectroscopy of muonic helium-3 ions

Abstract

Hydrogen-like light muonic ions, in which one negative muon replaces all the electrons, are extremely sensitive probes of nuclear structure, because the large muon mass increases tremendously the wave function overlap with the nucleus. Using pulsed laser spectroscopy we have measured three 2S-2P transitions in the muonic helium-3 ion (μ3He+), an ion formed by a negative muon and bare helium-3 nucleus. This allowed us to extract the Lamb shift E(2P1/2-2S1/2)= 1258.598(48) exp(3) theo meV, the 2P fine structure splitting E FS exp = 144.958(114) meV, and the 2S-hyperfine splitting (HFS) E HFS exp = -166.495(104) exp(3) theo meV in μ3He+. Comparing these measurements to theory we determine the rms charge radius of the helion (3He nucleus) to be rh = 1.97007(94) fm. This radius represents a benchmark for few nucleon theories and opens the way for precision tests in 3He atoms and 3He-ions. This radius is in good agreement with the value from elastic electron scattering, but a factor 15 more accurate. Combining our Lamb shift measurement with our earlier one in μ4He+ we obtain rh2-rα2 = 1.0636(6) exp(30) theo fm2 to be compared to results from the isotope shift measurements in regular He atoms, which are however affected by long-standing tensions. By comparing E HFS exp with theory we also obtain the two-photon-exchange contribution (including higher orders) which is another important benchmark for ab-initio few-nucleon theories aiming at understanding the magnetic and current structure of light nuclei.