Direct measurement of the 3He+ magnetic moments

Abstract

Helium-3 has nowadays become one of the most important candidates for studies in fundamental physics [1, 2, 3], nuclear and atomic structure [4, 5], magnetometry and metrology [6] as well as chemistry and medicine [7, 8]. In particular, 3He nuclear magnetic resonance (NMR) probes have been proposed as a new standard for absolute magnetometry [6, 9]. This requires a high-accuracy value for the 3He nuclear magnetic moment, which, however, has so far been determined only indirectly and with a relative precision of 12 parts per billon (p.p.b.) [10,11]. Here we investigate the 3He+ ground-state hyperfine structure in a Penning trap to directly measure the nuclear g-factor of 3He+ g'I=-4.255\, 099\, 606\, 9(30)stat(17)sys, the zero-field hyperfine splitting E HFS exp=-8\, 665\, 649\, 865.77(26)stat(1)sys Hz and the bound electron g-factor geexp=-2.002\, 177\, 415\, 79(34)stat(30)sys. The latter is consistent with our theoretical value getheo=-2.002\, 177\, 416\, 252\, 23(39) based on parameters and fundamental constants from [12]. Our measured value for the 3He+ nuclear g-factor allows for the determination of the g-factor of the bare nucleus gI=-4.255\, 250\, 699\, 7(30)stat(17)sys(1)theo via our accurate calculation of the diamagnetic shielding constant [13] σ3He+=0.000\,035\,507\,38(3). This constitutes the first direct calibration for 3He NMR probes and an improvement of the precision by one order of magnitude compared to previous indirect results. The measured zero-field hyperfine splitting improves the precision by two orders of magnitude compared to the previous most precise value [14] and enables us to determine the Zemach radius [15] to rZ=2.608(24) fm.