Chemical probing spectroscopy of H3+ above the barrier to linearity

Abstract: We have performed chemical probing spectroscopy of H + 3 ions trapped in a cryogenic 22-pole ion trap. The ions were buffer-gas cooled to ∼ 55 K by collisions with helium and argon. Excitation to states above the barrier to linearity was achieved by a Ti:Sa laser operated between 11 300 and 13 300 cm −1 . Subsequent collisions of the excited H + 3 ions with argon lead to the formation of ArH + ions that were detected by a quadrupole mass spectrometer with high sensitivity. We report the observation of 17 previ… Show more

“…Multipole radiofrequency ion traps [1], in particular the 22-pole ion trap [2], are versatile devices used in laser spectroscopy [3,4,5,6,7,8,9,10] and investigations of chemical reaction processes [2,11,12,13] of atomic and molecular ions. High order multipole traps offer a large field free region in the trap center, and therefore provide a reduced interaction time of the ions with the oscillating electric field compared to a quadrupole trap [14].…”

How can a 22-pole ion trap exhibit ten local minima in the effective potential?

“…Multipole radiofrequency ion traps [1], in particular the 22-pole ion trap [2], are versatile devices used in laser spectroscopy [3,4,5,6,7,8,9,10] and investigations of chemical reaction processes [2,11,12,13] of atomic and molecular ions. High order multipole traps offer a large field free region in the trap center, and therefore provide a reduced interaction time of the ions with the oscillating electric field compared to a quadrupole trap [14].…”

How can a 22-pole ion trap exhibit ten local minima in the effective potential?

“…The reason for this decrease is not understood at present but could have an impact on Ar-H 3 + action spectroscopy schemes. [23][24][25] Despite this, there was an increase in the para-H 3 + fraction when H 2 was diluted to ϳ1% in argon.…”

Communications: Development and characterization of a source of rotationally cold, enriched para-H3+

“…The development of action spectroscopy in a cryogenic radiofrequency (RF) ion trap provided measurements in the near-IR range 19 and showed great promise for attaining much higher sensitivity than absorption spectroscopy. We have recently extended the range of this method up to almost 17 000 cm −1 .…”

“…9 The measurement of line intensities in the VIS region has, however, been out of reach until now. As described previously, 9,19,20 H + 3 ions were stored in a multipole RF ion trap and buffer-gas cooled with He (2×10 14 cm −3 ) to ∼ 85 K. About 85% of the H + 3 ions thus populated the two lowest rotational (J = 1) levels of the vibrational ground state, having ortho and para symmetries. The near-VIS to VIS transitions were measured by chemical probing with Ar (1 × 10 12 cm −3 ).…”

“…After irradiation, the ion cloud was released into a mass spectrometer (MS) that could be set to either ArH + or H + 3 detection from one 300 ms storage cycle to the next. The ions were counted on a Daly stamp with a scintillator and a photomultiplier detection system 19,21 that is sensitive enough to single-ion count the low ArH + and the high H + 3 (normalization) ion numbers.…”

Communication: Visible line intensities of the triatomic hydrogen ion from experiment and theory