High-accuracy laser spectroscopy of {H}₂^{+} and the proton–electron mass ratio

Abstract The molecular hydrogen ions (MHI) are three-body systems suitable for advancing our knowledge in several domains: fundamental constants, tests of quantum physics, search for new interparticle forces, tests of the weak equivalence principle 1 and, once the anti-molecule p\, p\, e^+ p ¯ p ¯ e + becomes available, new tests of charge–parity–time-reversal invariance and local position invariance 1–3. To achieve these goals, high-accuracy laser spectroscopy of several isotopologues, in particular {H}₂^+ H 2 +, is required 4. Here we present a Doppler-free laser spectroscopy of a {H}₂^+ H 2 + rovibrational transition, achieving line resolutions as large as 2. 2 × 10 13. We accurately determine the transition frequency with 8 × 10 −12 fractional uncertainty. We also determine the spin–rotation coupling coefficient with 0. 1 kHz uncertainty and its value is consistent with the state-of-the-art theory prediction 5. The combination of our theoretical and experimental {H}₂^+ H 2 + data allows us to deduce a new value for the proton-electron mass ratio m p / m e. It is in agreement with the value obtained from mass spectrometry and has 2. 3 times lower uncertainty. From combined MHI, H/D and muonic H/D data, we determine the baryon mass ratio m d / m p with 1. 1 × 10 −10 absolute uncertainty. The value agrees with the directly measured mass ratio 6. Finally, we present a match between a theoretical prediction and an experimental result, with a fractional uncertainty of 8. 1 × 10 −12. Both results indicate a notable confirmation of the predictive power of quantum theory and the absence of beyond-the-standard-model effects at these levels.