Valence and Core-Level X-ray Photoelectron Spectroscopy of a Liquid Ammonia Microjet

Photoelectron spectroscopy of microjets expanded into vacuum allows access to orbital energies for solute or solvent molecules in the liquid phase. Microjets of water, acetonitrile and alcohols have previously been studied; however, it has been unclear whether jets of low temperature molecular solvents could be realized. Here we demonstrate a stable 20 μm jet of liquid ammonia (−60 °C) in a vacuum, which we use to record both valence and core-level band photoelectron spectra using soft X-ray synchrotron radiation. Significant shifts from isolated ammonia in the gas-phase are observed, as is the liquid-phase photoelectron angular anisotropy. Comparisons with spectra of ammonia in clusters and the solid phase, as well as spectra for water in various phases potentially reveal how hydrogen bonding is reflected in the condensed phase electronic structure.


* S Supporting Information
ABSTRACT: Photoelectron spectroscopy of microjets expanded into vacuum allows access to orbital energies for solute or solvent molecules in the liquid phase. Microjets of water, acetonitrile and alcohols have previously been studied; however, it has been unclear whether jets of low temperature molecular solvents could be realized. Here we demonstrate a stable 20 μm jet of liquid ammonia (−60°C ) in a vacuum, which we use to record both valence and core-level band photoelectron spectra using soft X-ray synchrotron radiation. Significant shifts from isolated ammonia in the gas-phase are observed, as is the liquidphase photoelectron angular anisotropy. Comparisons with spectra of ammonia in clusters and the solid phase, as well as spectra for water in various phases potentially reveal how hydrogen bonding is reflected in the condensed phase electronic structure. L iquid ammonia is often used as a medium for organic chemistry due its ability to support long-lived highly reducing solvated electrons, first demonstrated by Birch in 1944. 1 Solvated electrons can be generated simply by adding an alkali metal to anhydrous liquid ammonia; the solvated electrons have lifetimes on the order of months for solutions which are free from oxygen and moisture. It can be expected that photoelectron (PE) spectroscopy of these liquid solutions may reveal insights as to the binding energies of different electron motifs in ammonia. 2,3 However, in a recent review of the spectroscopy of excess electrons in ammonia 4 it is remarked that the electronic structure of neat liquid ammonia itself has not as yet been characterized through its photoelectron spectrum, although the PE spectrum of large ammonia clusters 5 and ammonia ice 6 on MoS 2 has been reported. The liquid PE spectrum would be a crucial complement to the known ammonia orbital energies in both vapor 7 and amorphous ice; 6 it is certainly a necessary prerequisite for an understanding of the band gap in liquid ammonia 8 and to provide a more rounded understanding of excess electrons 9 in liquid ammonia. A further interest in the liquid ammonia photoelectron spectrum is the comparison of the two simplest hydrogen bonded liquids: the question of how electronic structure evolves from isolated molecular H 2 O or NH 3 through molecular clusters all the way to (bulk) liquid, and the effect of hydrogen bond strength on the orbital binding energies. Shifts from the gas phase in each band in the PE spectrum of liquid water are well-known not to be uniform reflecting different solvent-induced changes to individual molecular orbitals. 10 A prerequisite to progress on the electronic structure of NH 3(aq) is to demonstrate the generation of a stable liquid jet of ammonia to enable photoelectron studies in vacuum. This paper provides proof-of-principle photoelectron spectroscopy from a liquid jet of NH 3 . The technique of forcing a room temperature liquid jet into vacuum was first used to obtain photoelectron spectra for liquid water, simple alcohols and nonane in 1997, 11 with the first photoelectron spectrum of water using synchrotron extreme ultraviolet recorded in 2004. 10 Liquid jets of cryogenic nitrogen and argon were achieved by Faubel in 2001 using a simple metal aperture, 12 with a system cooled all the way to the outlet aperture. Liquid ammonia poses a different challenge to these liquids. It is a gas until cooled below −33°C at atmospheric pressure; it was difficult for us to predict whether the liquid ammonia will immediately become a gas once a jet filament is introduced into vacuum due to ammonia's high vapor pressure (10 kPa) even at −70°C . Also, it was not clear that if a jet is formed, the length of the laminar flow region would be sufficient to collect high signal-to-noise photoelectron spectra.
A liquid ammonia sampling system, submerged in a cold ethanol bath held at −60°C, was employed. A 50 mM KBr solution was used to diminish the streaming potential, in analogy with water liquid jets. 13 High-purity argon was introduced into the head space of the sample cylinder to force the liquid ammonia through 6 mm dimeter steel tubing to a 20 μm diameter nozzle by pressurization (5 bar), keeping the line at the same temperature until reaching the beginning of the glass jet nozzle.
PE experiments were carried out with the SOL 3 PES experimental setup 14 at the variable polarization UE52-SGM-1 beamline at the synchrotron radiation facility BESSY II. 15 Valence PE spectra were recorded using a photon energy of 310 eV and core PE spectra were recorded with a photon energy of 640 eV; polarization with respect to the lab frame was varied relative to the facility floor. The energy resolution of the UE52-SGM1 beamline was better than 90 meV for 310 eV photon energy and 260 meV for 640 eV, respectively. The electron analyzer offered a resolution of 125 meV at the pass energy of 100 eV used in our experiments. The rectangular Xray spot size was 60 μm × 100 μm (exit slit) with the liquid ammonia microjet ∼20 cm behind the focus, such that the spot size at the liquid jet was roughly 400 μm.
A liquid jet of ammonia is formed with an argon backing pressure of 5 bar. After priming, a laminar flow region is formed 1−5 cm long; a stable liquid jet can be maintained for hours with a base chamber pressure of ∼4 × 10 −3 mbar until the exhaustion of the reservoir (flow rate of about 0.5 mL/min; jet velocity ∼30 m/s). Unlike with water, evaporative cooling does not lead to ice formation as part of the flow.
The recorded photoelectron spectra are shown in Figure 1. Calibration of the absolute binding energies in the photoelectron spectrum of liquid ammonia was carried out by measuring the lowest binding energy 3a 1 PE band at consecutively lowered photon fluxes until both gas and liquid phase peaks no longer shifted due to the charging of the jet caused by ionized ammonia molecules (see Figure S1). Then the valence spectrum is calibrated against the literature gasphase lowest vertical ionization potential of 10.93 eV. 7 We find a gas−liquid shift of 1.84 eV, giving the liquid 3a 1 peak at 9.1 ± 0.1 eV. The calibrated valence photoelectron (Figure 1, top) spectrum shows, as expected, three bands for the gas and three bands that can be assigned to the liquid. The large gas-phase contribution is due to the high vapor pressure around the liquid ammonia jet as well as the large X-ray illuminated volume.
By subtracting the appropriately normalized gas phase spectrum, the PE peaks due to the liquid can be obtained (Figure 1 middle, Figure S2) and fit by three Gaussians ( Figure  S2, red line). A discernible shift to lower binding energies for all features arising from the liquid-phase is evident (see Table  1). A similar lowering of binding energies of the valence orbitals is also seen for the valence peaks in liquid water, but the shifts here are greater than for water. 10 Furthermore, as for water, the shifts for the different bands are not the same. In ammonia, the shift is smallest for the lone pair 3a 1 , which is the orbital affected most by H-bond donation. A subtlety here is that the 1e band is split already in the gas phase due to degeneracy breaking in the resultant 2 E cation state (see Supporting Information). The binding energies for the 2s dominated orbitals (labeled 2a 1 in both water and ammonia) are shifted the most in both liquids.
The liquid PE spectrum resembles that observed for large ammonia clusters. 5 Compared to amorphous ammonia ice, the PE features are shifted to a greater extent from the gas phase. The solid phase 3a 1 band peak at 9.5 eV is almost 2 eV wide and is distinctly asymmetric unlike the liquid phase peak, which is shifted to 9.1 eV and more or less Gaussian. The 1e band in ammonia ice peaks at 15.1 eV (and is also ∼2 eV broad shading to the low BE side), whereas in liquid we see a further decrease in BE to 14.3 eV for the band peak.
The angular anisotropy of the valence PE spectrum has been recorded but for a different photon energy, 265 eV ( Figure  S3). For the 3a 1 and 1e bands, which are well separated from their vapor counterparts, the electron angular distributions are characterized by β(3a 1 ) = 1.5/1.0 (gas/liquid) and β(1e) = 1.3/0.9 (gas/liquid), respectively.
We have modeled the valence photoelectron bands using hybrid density functional calculations employing the G 0 W 0 approach. Calculations for the gas phase spectrum originate from a set of 5000 single point G 0 W 0 calculations for geometries sampled every 10 fs from a 50 ps long ab initio molecular dynamics (AIMD) trajectory of a single ammonia molecule. For liquid phase spectra, we simulated 64 ammonia molecules in a box employing periodic boundary conditions; for 100 configurational snapshots separated by 2 ps from a 200 ps run, the 256 highest G 0 W 0 energies (i.e., four energies per NH 3 molecule) were used for obtaining the quasi-particle energy distribution to model the spectra. Full details of the computational methodology are given in the Supporting Information.
The results of our calculations are summarized in the bottom part of Figure 1. First, we reproduced well the gas Assignments are made to parent isolated molecular orbitals (shown) by closeness in binding energy to gas-phase bands. All binding energies are with respect to the vacuum level. Polarization of the radiation is parallel to the electron collection direction. (Middle) Subtraction of the intensity-normalized experimental spectra reveals the liquid-only contribution (black dots, green fit) which areanormalized is compared to photoelectron bands for gas-phase (blue) ammonia. (Bottom) Same comparison now with theoretical PE bands calculated using the G 0 W 0 method. Fitting results are summarized in Table 1; residuals to fit are shown in the Supporting Information.

Journal of the American Chemical Society
Communication phase valence ionization energies using the G 0 W 0 approach in terms of absolute peak positions. Small residual deviations are primarily due to approximations used in describing the electronic structure. Second, in the liquid phase, the absolute values of electronic orbital energies are not directly accessible due to the use of periodic boundary conditions. 17−19 Therefore, the whole spectrum was shifted such that the first peak was aligned with the experiment at −9.09 eV. After this alignment, the calculated liquid phase spectrum exhibits good agreement with experimental data in terms of peak positions but is systematically underestimating the gas-to-liquid shifts. Note that the somewhat larger widths of the experimental peaks compared to the calculated ones is likely due to combination of a neglect of nuclear quantum effects in the simulations and the possible contribution from inelastic scattering for the experiment liquid spectrum distorting peaks to the high binding energy side; the extent of inelastic scattering has so far only been determined for much slower electrons liberated in laser based spectrometers. 20 As we expect the ammonia core N 1s levels to be sensitive to local environment in highly alkali-metal doped ammonia solutions, the N 1s (1a 1 ) photoelectron band for the neat liquid was recorded with a photon energy of 640 eV, and the result is presented in Figure 2. As before, a substantial gas phase peak is observed. Note that we calibrated the N 1s liquid peak, which is at 403.49 eV, by using the position of the valence 3a 1 liquid peak and not against the N 1s gas phase peak, because we have not yet excluded charging effects due to high photon flux affecting the gas−liquid shift. This binding energy for the N 1s is very similar in clusters with ∼1600 ammonia molecules suggesting that charging is not a significant problem. 5 Using a literature value for the gas, 5 the gas−liquid shift for this band is 2.0 eV, compared to a smaller shift of 1.77 eV on the O 1s for water. The difference in the gas−liquid shifts between water and ammonia for the N 1s and O 1s may in part reflect the different optical dielectric response of the two liquids via the Born stabilization of the final state. 10 Finally, varying the X-ray polarization over six angles with respect to the detection direction for N 1s PE band at 640 eV ( Figures S4 and S5) gives β(gas/liquid) = 1.9/1.7 showing only a small diminution of the photoelectron anisotropy due to elastic scattering of the outgoing electron through the liquid. 21 In conclusion, we have presented the first measurements from a liquid ammonia microjet and demonstrated significant shifts in the photoelectron binding energies for both the valence and core orbitals of ammonia on condensation. The decrease in binding energies is more significant than those seen for amorphous ammonia ice deposited on MoS 2. However, as for PE spectra from large clusters, we can clearly identify bands that match those from the isolated molecule. The basic shifts observed in experiment are recovered by calculations based on ab initio molecular dynamics and G 0 W 0 with a hybrid functional. Evidence for the degree of delocalization of the valence orbitals can be analyzed from the PE band anisotropy and peak splitting. Experiments that probe liquid ammonia increasingly doped with excess electrons are currently underway; the issue of delocalization and anisotropy will be particularly topical in this context and will be further explored in a future publication. Author Contributions ¶ These authors contributed equally.