1. Introduction

Anthropogenic and natural sulfur are emitted into the atmos­phere in various chemical forms: SO₂, H₂S, CS₂, OCS, CH₃SH, CH₃SCH₃ and CH₃SSCH₃, to name a few. Roughly, on a global basis, sulfur from natural origins and that from anthropogenic origins contribute equally to the atmosphere. Most of this sulfur returns to the oceans (90%) and the land (10%) as a sulfate in precipitation. The oxidation of anthropogenic SO₂ to H₂SO₄ is the major cause of acid rain. Also, the oxidation of naturally occurring sulfur compounds leads to sulfuric acid particles, which act as condensation nuclei for water to generate clouds and thus change the albedo of the Earth. Therefore, atmospheric sulfur chemistry has immense significance to the biosphere in general and man in particular. Substantial efforts have been directed towards the study of the atmospheric chemistry of these sulfur species (Tyndall & Ravishankara, 1991).

Photoionization mass spectrometry is currently used to study the kinetics and mechanisms of atmospheric reactions of sulfur species (Dominé et al., 1990, 1992). However, photoionization spectra are lacking for most sulfur radicals and their reaction intermediates. Thus, it is important to measure photoionization spectra of sulfur radicals and their reaction products. From such measurements, an optimal wavelength for the ionization of sulfur species in kinetic experiments can be established. Ionization energies (IEs) of these sulfur compounds can also be derived from the thresholds of their photoionization spectra. We can expect to learn about their thermochemistry from the IE data obtained.

2. Experimental and results

We use a discharge flow–photoionization mass spectrometer (DF–PIMS) to measure the photoionization spectra of sulfur radicals and their reaction products (Cheng & Hung, 1996). Sulfur radicals are generated from reactions of oxygen or chlorine atoms with sulfur compounds (see Table 1), in a flow tube by using a discharge flow technique. The flow reactor is a Pyrex tube (with inner diameter 24 mm and length 600 mm) fitted with a movable injector (outer diameter 8 mm). The gas effluents of the reaction system are sampled into an ionization chamber via a three-stage differential pumping scheme. Then, photoionization spectra and ionization energies of mass-selected ions are measured by using a synchrotron as the photoionization source. The detection system is a standard PIMS system with a quadrupole mass filter operated in the pulse-counting mode.

We measured the photoionization spectra of various sulfur compounds. Ionization energies of these compounds were determined from the thresholds of their photoionization spectra near the onset. Three methods were employed to determine the threshold of ionization; the choice of method depends on the characteristics of each spectrum. When the photoion yield curve shows an abrupt rise near the onset, the maximum of its first derivative is well defined and is therefore taken as the threshold. When the spectrum appears as a distinct step but rises less rapidly than in the former case, the midrise point of the onset is taken as the threshold. The thresholds obtained by these two methods typically agree with each other. In some cases, the photoion yield curve has a gradually rising edge, presumably due to poor Franck–Condon overlap between the neutral and the ionic species. In these cases, the threshold is derived from the intersection of the background baseline with the rising edge fitted to a line by a least-squares method. The IEs obtained for various sulfur compounds are listed in Table 2; the results are in agreement with literature values. Thus, it demonstrates that our DF–PIMS system operates properly.

Table 2 Ionization energies (eV) of various sulfur compounds determined in this work Species This work Previous work CS2 10.078 (7) 10.0782 (6)a H2S 10.460 (11) 10.4682 (2)b OCS 11.171 (7) 11.1736 (15)c CH3SH 9.46 (2) 9.455 (5)d C2H5SH 9.280 (7) 9.285 (5)e 2-C3H7SH 9.143 (7) 9.14f HSC2H4SH 9.280 (14) – CH3SCH3 8.69 (2) 8.710 (5)g C2H5SCH3 8.55 (2) 8.54 (1)h C2H5SC2H5 8.40 (1) 8.41 (1)i CH3SSCH3 8.34 (3) 8.18 (3)j C2H5SSC2H5 8.05 (1) <8.27 (3)h References: (a) Fischer et al. (1993a); (b) Fischer et al. (1993b); (c) Ono et al. (1981); (d) Morgan, Puyuelo et al. (1995); (e) Watanabe et al. (1962); (f) Ogata et al. (1973); (g) Morgan, Orr-Ewing et al. (1995); (h) Lias et al. (1988); (i) Ma et al. (1993); (j) Li et al. (1993).

We have successfully studied photoionization spectra of several sulfur radicals using this DF–PIMS technique. Up to now, we have focused on some interesting radicals: HS, HSO, CH₃S, CH₃SO and C₂H₅SO. The IE of the HS radical was determined to be 10.45 (4) eV, consistent with the value of 10.4219 (4) eV measured with a nonresonant two-photon pulsed field ionization technique (Hsu et al., 1994). The IE of CH₃S was determined to be 9.27 (3) eV, in good agreement with the value of 9.2647 (10) eV measured with a nonresonant two-photon pulsed field ionization technique (Hsu & Ng, 1994). For HSO, CH₃SO and C₂H₅SO radicals, photoionization spectra were measured for the first time by our group and their IEs were obtained as 9.918 (16) (Cheng, Eberhard et al., 1997a), 8.99 (2) (Hung et al., 1996) and 8.71 (2) eV (Cheng, Hung et al., 1997), respectively. Fig. 1 shows the photoionization spectrum near the threshold region of HSO; the IE was derived from the distinct step shown at the onset, either from the midrise point or the first derivative of the onset, as indicated by the arrow.

Figure 1 The photoionization threshold region of HSO at a nominal resolution of 0.2 nm and with 0.1 nm steps. The arrow indicates the ionization energy of HSO.

In our studies of sulfur radicals, sometimes secondary reactions could not be avoided. For example, in the case of the CH₃SO radical, we also obtained photoionization spectra of CH₃SOH, CH₃SS and CH₃SS(O)CH₃; the IEs determined were 8.67 (3), 8.62 (5) and 8.82 (5) eV, respectively. In the reaction system Cl/Cl₂/H₂S, photoionization spectra of products HSCl, HSSH, HSSSH, SSCl and HSSCl were measured for the first time; the IEs were 9.887 (16), 9.06 (2) (Cheng, Eberhard et al., 1997b), ≤9.01, 9.01 (3) and 9.266 (14) eV, respectively (Eberhard et al., 1997). Other products observed in this reaction system include S₂, S₃ and SCl₂; their photoionization spectra and IEs were also measured (see Table 3).

Table 3 Ionization energies (eV) of sulfur species produced from reactions in this work Species This work Previous work HS 10.45 (4) 10.4219 (4)a SO 10.34 (4) 10.294 (4)b S2 9.350 (14) 9.356 (2)c HSO 9.918 (16) – HSCl 9.887 (16) – SCl2 9.57 (3) 9.45 (3)d S2O 10.60 (4) 10.584 (5)b SSCl 9.04 (3) – S3 9.63 (3) 9.68 (3)e HSSH 9.06 (2) 9.41f HSSCl 9.266 (14) – HSSSH ≤9.09 – CH3S 9.27 (3) 9.2647 (10)g CH3SS 8.62 (5) 8.67 (2)h CH3SO 8.99 (2) – CH3SOH 8.67 (3) – C2H5SO 8.71 (2) – CH3SS(O)CH3 8.82 (5) – References: (a) Hsu et al. (1994); (b) Norwood & Ng (1989); (c) Liao & Ng (1986); (d) Kaufel et al. (1981); (e) Berkowitz & Lifshitz (1968); (f) Frost et al. (1977); (g) Hsu & Ng (1994); (h) Ma et al. (1994).