A compact, high-purity source of HONO validated by Fourier transform infrared and thermal-dissociation cavity ring-down spectroscopy

. A well-characterized source of nitrous acid vapour (HONO) is essential for accurate ambient air measurements by instruments requiring external calibration. In this work, a compact HONO source is described in which gas streams containing dilute concentrations of HONO are generated by ﬂowing hydrochloric acid (HCl) vapour emanating from a permeation tube over continuously agitated dry sodium nitrite (NaNO 2 ) heated to 50 ◦ C. Mixing ratios of HONO and potential by-products including NO, NO 2 , and nitro-syl chloride (ClNO) were quantiﬁed by Fourier transform infrared (FTIR) and thermal-dissociation cavity ring-down spectroscopy (TD-CRDS). A key parameter is the concentration of HCl, which needs to be kept small ( < 4 ppmv) to avoid ClNO formation. The source produces gas streams containing HONO in air in > 95 % purity relative to other nitrogen oxides. The source output is rapidly tuneable and stabilizes within 90 min. Combined with its small size and portability, this source is highly suitable for calibration of HONO instruments in the ﬁeld.


Introduction
The generation of nitrous acid vapour (HONO (g) ) free of other nitrogen oxides has been a long-standing challenge to atmospheric chemists (Table 1).Such sources are needed in kinetic studies, for absorption cross-section measurements, and for the calibration of field instruments.Nitrous acid is not suitable for permeation devices since HONO is difficult to prepare in low concentration and in high purity and disproportionates to nitric oxide and nitrogen dioxide via equi-librium (1).
In fact, early experiments relied on the NO, NO 2 , and H 2 O vapour equilibrium to form HONO in situ (King and Moule, 1962;Cox, 1974;Stockwell and Calvert, 1978).
Subsequent refinements included a flow reactor design in solutions of sulfuric acid and sodium nitrite were dynamically mixed, producing a stable output in > 90 % purity (Taira and Kanda, 1990).Febo et al. (1995) developed a method in which gas-phase hydrochloric acid emitted from a permeation device was quantitatively reacted in a humidified gas stream with solid sodium nitrite, producing a stable and highly pure (> 99.5 %) HONO output.
Published by Copernicus Publications on behalf of the European Geosciences Union.The output of sources based on Reaction (R4) has been characterized by differential optical absorption spectroscopy (DOAS) (Febo et al., 1995;Stutz et al., 2000), Fourier transform infrared (FTIR) spectroscopy (Brust et al., 2000;Schiller et al., 2001), tuneable diode laser absorption spectroscopy (TLDAS) (Schiller et al., 2001), incoherent cavityenhanced absorption spectroscopy (IBBCEAS) (Roberts et al., 2010), and long-path optical absorption photometry (LOPAP) (Ren et al., 2010).Stutz et al. (2000) noted that concentrations of HONO should be kept low (< 10 14 molecules cm −3 ; ∼ 4 ppmv) to avoid disproportionation of HONO via Reaction (R1).Perez et al. (2007) examined a source based on the design by Febo et al. (1995) using thermal-dissociation chemiluminescence (TD-CL) detection of NO and reported that their source co-emitted nitrosyl chloride (ClNO); they opted to generate HONO from reaction of H 2 SO 4 aerosol with NaNO 2(s) instead.In contrast, Roberts et al. (2010) observed little or no production of ClNO (< 4.5 %) and quantitative conversion of HCl to HONO, at odds with Perez et al. (2007) but in agreement with the original work by Febo et al. (1995).As far as we know, this inconsistency is unexplained to date.
As part of our development of an IBBCEAS for HONO measurement, our lab recently constructed a HONO source using an aqueous solution of NaNO 2 buffered with oxalate to pH 3.74 (Jordan and Osthoff, 2020).This source generated HONO in trace amounts suitable to our needs but co-emitted NO and NO 2 in similar ratios to those reported by Braman and De la Cantera (1986).Furthermore, this type of source could not be turned off (i.e., had to remain under continuous N 2 flow) and required long times to stabilize, motivating us to develop an alternative HONO generation method.Ambient air HONO measurement techniques that need to be externally calibrated often poorly agree with each other (Crilley et al., 2019), further motivating the development of a wellcharacterized, compact, and portable HONO source and improved understanding of conditions needed to suppress formation of undesired side products such as ClNO.
In this work, we describe the implementation of a compact, high-purity HONO generation device based on R4 for field deployment and laboratory experiments and characterized its output by FTIR and thermal-dissociation cavity ringdown spectroscopy (TD-CRDS).Conditions to avoid generation of impurities such as ClNO are identified.The performance of this source in comparison to existing methods is discussed.

Generation of gas streams containing HONO
A practical challenge is the generation of stable and dilute gas streams containing HCl. Calibration gas cylinders are the most straightforward method to use for this purpose but may require periods of up to 10 d to stabilize (Roberts et al., 2010).Furthermore, low-concentration HCl gas cylinders are expensive to source, such that we chose to generate HCl gas through the use of relatively inexpensive permeation devices.
In the setup by Febo et al. (1995), which was also implemented by Brust et al. (2000), Stutz et al. (2000), and Ren et al. (2010), a gas stream of N 2 is passed through Teflon tubing immersed in an HCl bath.This setup involved a rather large 1 L vessel containing liquid HCl, which is somewhat impractical and potentially hazardous in a field setting.With portability in mind, we decided to construct a permeation tube containing HCl(l).The literature does not inform as to suitable tube dimensions, which were determined through trial and error.
Three HONO sources were constructed and evaluated.In the first ("source 1"), a 24 cm long, polytetrafluoroethylene (PTFE) permeation tube (Chromatographic Specialties C111LE; wall thickness 1.5 mm; outer diameter (o.d.) 7.8 mm) was filled with 2.5 mL of 37 % HCl (Sigma-Aldrich) and sealed at both ends with PTFE plugs held in place by stainless steel compression rings.The permeation tube was placed inside a glass chamber (VICI Dynacalibrator Model 120) whose temperature was controlled at 25.0 • C and which was continuously flushed at a flow rate of ∼ 0.15 L min −1 with room air scrubbed using activated charcoal for a period of several days into a fume hood.The use of scrubbed air ensured that the gas stream contained water to maintain efficient HONO production (Schiller et al., 2001).
For the experiments shown in this paper, the relative humidity of the diluent gas stream was in the range of 15 % to 35 %.
The HCl output was diluted in a gas stream of O 2 (∼ 20 mL min −1 ); this gas stream also served to continuously flush the connecting tubing when not in use.Roughly 1.5 g of solid NaNO 2 was placed inside a 50 cm long loop of 3/16 (0.476 cm) inner diameter (i.d.) and 1/4 (0.635 cm) o.d.fluorinated ethylene propylene (FEP) Teflon tubing downstream from the HCl addition point.This section could be manually bypassed with a pair of three-way valves (Entegris) to turn HONO production on or off.A Teflon filter (Pall, 2 µm pore size and 47 mm diameter) inside a Teflon filter holder (Cole-Parmer) was placed downstream of the NaNO 2 powder.
In the second source ("source 2"), the NaNO 2 was placed in a two-neck, 50 mL Pyrex round bottom flask which was covered in aluminium foil to prevent photolysis of nitrite and nitrous acid and was externally heated to a temperature of 50 • C using a water bath and mechanically agitated using a magnetic stir bar as described by Febo et al. (1995).Heating this vessel promotes dissociation of molecular clusters such as N 2 O 4 and partitioning of wall-adsorbed molecules to the gas phase, which, if present, can drive HONO decomposition on borosilicate glass surfaces (Syomin and Finlayson-Pitts, 2003).
The third source ("optimized source") used the same setup as source 2, except that a shorter permeation tube (length 6 cm) containing 0.35 mL of HCl was used.This setup is depicted in Fig. 1.The overall dimensions are 28 cm × 28 cm × 36 cm and its modular design ensures easy transport to and from the field.
To deliver HONO in atmospheric concentrations (i.e., < 10 ppbv), a portion of the source output was directed towards waste with the aid of a pump and a needle valve.The output concentration could be rapidly changed (typically by factors between 5 and 200) by adjusting the position of the needle valve.The remaining output was diluted using scrubbed air and directed towards the instruments at a final flow rate slightly larger than the sampling requirement of the instruments.

Analysis of HONO source output by FTIR
Gas streams exiting the HONO sources (prior to dilution) were analysed using an FTIR spectrometer (Bruker Tensor 27) equipped with a liquid nitrogen cooled mercury cadhttps://doi.org/10.5194/amt-13-4159-2020Atmos.Meas.Tech., 13, 4159-4167, 2020 mium telluride (MCT) detector and a White multi-pass gas cell with a 6.4 m optical path length and an internal volume of 0.75 L (Gemini Scientific Instruments, Venus series) in a similar fashion to that described earlier (Taha et al., 2013).Room-temperature spectra were acquired continuously at a time resolution of 30 s. Background spectra were recorded with HCl inline but with the NaNO 2 bypassed, which resulted in the observed spectra showing the change in trace gas concentrations.
Mixing ratios of trace gases were determined from fits (by least squares error minimization over a selected wavelength range) of room-temperature reference spectra from the Pacific Northwest National Laboratory (Sharpe et al., 2004), multiplied by the respective mixing ratios as variables, to the observed spectra.The reference spectra are provided in units of ppmv at atmospheric pressure per meter of optical length, necessitating a correction factor of 6.4 accounting for the actual path length and a pressure correction factor for which the pressure inside the multi-pass cell (which was equal to that of the room) was monitored using a pressure transducer (Omegadyne PX419-015A5V).
The FTIR limits of detection (LODs) are specific to each molecule (due to differing absorption cross sections) and are in the 100 to 300 parts-per-billion (by volume; ppbv; 10 −9 ) range.For example, the 1σ precision of NO 2 data was ±100 ppbv, yielding a 3σ LOD of 300 ppbv.
The spectral resolution of the FTIR was ∼ 0.5 cm −1 , which does not suffice to fully resolve the absorption lines of HCl, H 2 O, and NO; their FTIR-derived mixing ratios are hence lower limits.

Analysis of HONO source output by TD-CRDS
The (diluted) HONO source output was also analysed using a four-channel TD-CRDS instrument (Odame-Ankrah, 2015).Briefly, mixing ratios of NO 2 are quantified by absorption at 405 nm.Ring-down time constants in the absence (τ 0 ) and presence (τ ) of NO 2 are converted to concentrations (N) using Eq. ( 2), where c is the speed of light, σ is the NO 2 ab-sorption cross section, and R L is a correction factor (∼ 1.2) accounting for mirror purge flows (Paul and Osthoff, 2010).
Concentrations are converted to mixing ratios using the ideal gas law.Other NO y components are converted to NO 2 in separate channels and are quantified by difference.
For this study, the instrument was operated as follows: mixing ratios of NO 2 were monitored using a room temperature, 1/4 (0.64 cm) o.d., and 1/8 (0.32 cm) i.d.FEP Teflon inlet.Mixing ratios of NO x were quantified on a second channel with a room temperature Teflon inlet and by adding O 3 (mixing ratio after addition of ∼ 3 ppmv) to titrate NO to NO 2 (Odame-Ankrah, 2015; Fuchs et al., 2009).A third channel was operated with a 1/4 (0.64 cm) o.d.quartz inlet heated to 600 • C. Ozone was added between the quartz inlet and the CRDS cell to quantify NO y , including HONO (Jordan and Osthoff, 2020;Wild et al., 2014;Perez et al., 2007).The fourth inlet was operated at 350 • C and with added O 3 .This channel quantified NO x + PAN + AN + ClNO + ClNO 2 and was used as a HONO reference channel.Each channel sampled at a flow rate of ∼ 0.8 slpm through ∼ 5 cm short, 1/16 i.d.Teflon flow restrictors placed inline after the heated quartz sections (if existing) and before a 50 mm Teflon (Pall Teflo, 2 µm pore size) housed in a Teflon filter holder (Cole Parmer).The laser pulse repetition rate was 1500 Hz, and 1500 ring-down events were averaged to produce 1 s data.

Field deployment
The HONO source was utilized during the "Study of nitrogen oxides in winter downwind from oil and gas sands" (SNOW-DOGS) field campaign in Fort McKay, Alberta, Canada, in January 2020.Its output was quantified in parallel by TD-CRDS and a Thermo 42i-Y NO-NOy CL instrument equipped with a Mo converter heated to 325 • C.This converter and the TD-CRDS quartz inlets were mounted on the roof of a trailer which housed the instruments and the HONO source.The TD-CRDS sampled at a flow rate of ∼ 1.2 slpm per channel through ∼ 5 cm short, 300 µm i.d.stainless steel flow restrictors placed inline after the heated quartz sections and before the Teflon filter assembly.The HONO source output was delivered via a 5 m long, 1/4 (0.64 cm) o.d. and 3/16 (0.48 cm) i.d.FEP Teflon tube to both instruments.

Development of a compact, high-purity HONO source
The first design tested (source 1) produced an output of ∼ 38 ppmv of HONO from a similar amount (> 38 ppmv) of HCl (Fig. S1a in the Supplement).This HONO mixing ratio is a factor of ∼ 10 larger than the maximum recommended by Stutz et al. (2000) to avoid partial conversion of HONO to NO 2 and NO via Reaction (R1).Consistently, the source output contained ∼ 4.0 ppmv of NO 2 (Fig. S1a) and an analogous amount of NO (Fig. S1b).Furthermore, the spectrum contained an absorption feature around 1808 cm −1 , reproduced by ∼ 15.5 ppmv of ClNO.Nitrosyl chloride can be produced by reaction of HONO with gas-phase or wall-adsorbed HCl (Zhang et al., 1996;Wingen et al., 2000) or by reaction of two equivalents of NO 2 with particulate-phase Cl − (Weis and Ewing, 1999), though the relatively low mixing ratios of NO 2 in this system make this reaction less likely.
The FTIR spectrum contained ∼ 50 ppmv more H 2 O than the reference spectrum, i.e., more moisture than emitted by the permeation tube with NaNO 2 bypassed.While this is consistent with ClNO production via R5, the H 2 O data are likely not meaningful since the H 2 O mixing ratios changed slowly over time (data not shown), possibly because of slow equilibration with the inner walls of the tubing and multi-pass cell and perhaps also because of water's presence in the FTIR optical path outside the multi-pass cell at a concentration that may have drifted.Febo et al. (1995) reported lower production of NO x by mechanically agitating the NaNO 2 using a stir bar (to break up pockets of high [HONO]) and by heating the reaction vessel to 50 • C; these steps were incorporated into the second design (source 2).The FTIR spectrum of its output showed a consumption of >∼ 42 ppmv HCl and production of ∼ 48 ppmv of HONO, ∼ 8.0 ppmv of NO 2 , ∼ 6.5 ppmv of ClNO, ∼ 8 ppmv of NO, and ∼ 50 ppmv of H 2 O (Fig. S2), an improvement over source 1 in terms of unwanted ClNO production, but still inadequate.
A shorter HCl permeation tube was used in the third design, with the expectation that the lower HCl concentrations result in reduced generation of side products via R5 and R6.A sample FTIR spectrum of this source's output is shown in Fig. 2. With a freshly prepared HCl permeation tube and an estimated relative humidity in the round bottom flask of ∼ 25 %, >∼ 2.5 ppmv HCl was consumed and ∼ 3.0 ppmv of HONO was produced.The mixing ratios of undesired side products (i.e., NO, NO 2 , ClNO, and HNO 3 ) were below their respective FTIR detection limits (Figs. 2, S3, and S4).

Analysis of source output by TD-CRDS
To better constrain the mole fractions of impurities, the source output was analysed by TD-CRDS. Figure 3 shows an example experiment.The TD-CRDS sampled scrubbed air before 21:38 UTC and after 21:58 UTC to determine the ring-down time constants in the absence of absorbers, τ 0 .In after the source was optimized.The reference spectrum was collected when NaNO 2 was bypassed, i.e., contained HCl.Literature spectra (Sharpe et al., 2004) were multiplied by the optical path length of 6.4 m and mixing ratios of the identified trace gases until they reproduced the observed spectrum.The optimized source delivered 3.0 ppmv of HONO from > 2.5 ppmv of HCl.The spectrum also contained ∼ 4.0 ppmv of H 2 O.The HCl and H 2 O concentrations are underestimates of their true concentrations since their absorption lines are narrower than the resolution of the FTIR of 0.5 cm −1 .the time periods in between, varying amounts of the HONO output were sampled.There was little response other than in the NO y channel, the only channel sensitive to HONO.Scatter plots of NO 2 , NO x , and NO x + PAN + AN + ClNO + ClNO 2 ("HONO ref") against NO y (Fig. 3, inserts) have slopes of (1.29 ± 0.06) %, (1.54 ± 0.06) %, and (2.28 ± 0.04) %, respectively, from which a source purity of > 97.3 % was deduced.
When concentrations changed, the 90 %-10 % rise (and fall) times of the TD-CRDS were < 3 s, a time constant identical to changes in NO x concentration and indicating a "wellbehaved" inlet, i.e., the absence of inlet memory effects and fast equilibration with the inner walls of the inlet.The fast response contrasts with the rise (and fall) times of HNO 3 of > 180 s (data not shown).Furthermore, the response in a channel sampling from an inlet heated to 600 • C without added O 3 was the same as that of the NO 2 channel (data not shown), consistent with the absence of HNO 3 observed by FTIR spectroscopy (Fig. S4).
A quartz inlet temperature scan when the TD-CRDS was sampling a constant concentration of HONO is shown in Fig. 4. The experimental TD curve was reproduced by a fit to Eq. ( 2), which is based on Eq. ( 4) by Paul et al. (2009).
In our experience, the TD inflection points vary between TD-CRDS channels (and depend on sample flow rates), captured by the t res parameter that is specific to each channel.For the data shown in Fig. 4, HONO fully dissociates at a temperature of ∼ 570 • C, and the inflection point is at ∼ 500 • C. Nitrosyl chloride is predicted to fully dissociate at ∼ 330 • C (inflection point at ∼ 288 • C), such that the temperature of 350 • C chosen for the HONO ref channel (Fig. 3) is justified.The blue, dashed line superimposed in Fig. 4 shows a simulation of 5 ppbv ClNO and 45 ppbv HONO to demonstrate the relative positions of the TD of ClNO and HONO.We attempted to verify the ClNO TD profile experimentally, but the unoptimized source's ClNO outputs were not sufficiently stable, and those attempts were abandoned.Regardless, it is clear from Fig. 4 that the contribution of ClNO to the total source output is negligible.
As can be seen from the insert in Fig. 4, HONO contributes a tiny amount to the TD-CRDS signal at 350 • C (∼ 4 pptv in the simulation of 50 ppbv HONO).This contribution may differ between quartz heaters and channels and could have been impacted by TD-CRDS using multiple parallel channels presented at the beginning of this section and in Fig. 3, leading to an overestimation of the total amount of impurities present in that experiment.The temperature scan data shown in Fig. 4, on the other hand, were collected using a single quartz heater and are thus more accurate.

Source stability
The source output gradually decreased over a timescale of weeks of continuous use, which was rationalized by the visible depletion of the HCl permeation tube.However, the source output remained stable and reproducible on shorter timescales.An example FTIR time series is shown in Fig. 5, which was acquired after 1 month of intermittent use.After a 1.5 h stabilization period, the source produced a stable output of 1.57 ppmv of HONO (from > 1.0 ppmv of HCl) with a precision of ±35 ppbv.

Source purity and day-to-day reproducibility
The optimized source routinely delivered HONO in high purity (range 96.0 %-98.7 %) as long as scrubbed, moisturecontaining room air was used as diluent gas (Table 2).When dry cylinder gas was used instead, the source output was stable but contained a larger amount of undesired side products; for example, on 25 July 2019, the output contained 4.6 % NO 2 and 8.8 % NO + ClNO (Table 2).When used in the field, the performance was similar: with scrubbed air, the HONO purity was 98.5 %, whereas with dry cylinder gas, the purity was merely 81.3 % (Table 2 and Fig. S5).The TD-CRDS quartz inlet temperature was ramped between 300 and 600 • C; the TD-CRDS mixing ratios at an inlet temperature of 300 • C matched the NO x mixing ratios observed with the room temperature inlet, indicating the absence of ClNO.

Discussion
In this work, a small-footprint, portable, stable, rapidly tuneable, and high-purity (> 97 % on average) HONO source has been described.The source achieves compactness by using a diffusion tube containing 0.35 mL concentrated HCl rather than a 1 L HCl bath.The latter is a considerable hazard since an HCl spill can cause severe burns of skin or permanent eye damage, and hydrochloric acid vapours are toxic to inhale.Hence, smaller volumes are preferred when deploying to the field.The source stabilizes within a time frame of 1.5 h (Fig. 5), which is fast compared to, for example, the 10 d stabilization period reported by Roberts et al. (2010).The source output is also rapidly tuneable (Fig. 3), which allows expedient generation of calibration plots.These properties make it a useful setup for in-field instrument calibrations.The combination of FTIR and TD-CRDS provided a unique and powerful tool set to analyse the purity of the source's output.This work has shown that HONO sources based on Reaction (R4) can generate NO, NO 2 , and ClNO as by-products via Reactions (R1) and (R5).Febo et al. (1995) and Roberts et al. (2010) have presented HONO sources based on R4 and demonstrated stoichiometric conversion of HCl to HONO.The results in this work suggest that devices relying solely on loss of HCl for calibration of HONO output should be used with caution as co-production of NO, NO 2 , and ClNO is a real possibility.In our setup, formation of ClNO could be avoided by keeping the HCl concentration low (i.e., < 4 ppmv), which puts an important constraint on sources generating HONO by Reaction (R4).With this in mind, it is instructive to scrutinize the earlier work in regard to side product formation.It has generally been noted that the presence of moisture is needed to ensure a high HONO output.We suggest that water is needed in part because ClNO is prone to hydrolysis (Karlsson and Ljungstrom, 1996), such that the product distribution is shifted towards HONO.ClNO (g) + H 2 O (g) → HONO (g) + HCl (g) (R7) Roberts et al. (2010) observed no ClNO production, likely because they kept their concentrations relatively low (< 900 ppbv) and humidified their gas streams, though they appear to be just below the threshold of possible ClNO production.Perez et al. (2007), on the other hand, observed ClNO but did not disclose details as to how they operated their source, i.e., whether they worked under trace conditions and with humidified gases, though it is likely that either or https://doi.org/10.5194/amt-13-4159-2020Atmos.Meas.Tech., 13, 4159-4167, 2020 both conditions were not met.Schiller et al. (2001) bubbled N 2 through liquid HCl and would have certainly achieved a high enough HCl concentration to generate ClNO with their setup.However, they reported achieving higher HONO output in the presence of moisture.Hydrolysis of ClNO (Reaction R7) may be a (partial) explanation why the presence of H 2 O improved the output of their HONO.The present HONO source has a large dynamic range (0-1 ppmv), well above the HONO concentrations found in ambient air.For field calibrations in future, it may be desirable to construct a permeation tube with lower HCl output, for example by lowering the HCl concentration in the permeation tube.

Figure 1 .
Figure 1.Schematics of the experimental setup.The high-purity HONO generation system is shown on the left (dotted border).MFC: mass flow controller.sccm: standard cubic centimetre per minute.

Figure 2 .
Figure 2. Infrared spectrum (shown in red colour) of a gas stream containing HONO generated by reaction of HCl (g) with NaNO 2 (s)after the source was optimized.The reference spectrum was collected when NaNO 2 was bypassed, i.e., contained HCl.Literature spectra(Sharpe et al., 2004) were multiplied by the optical path length of 6.4 m and mixing ratios of the identified trace gases until they reproduced the observed spectrum.The optimized source delivered 3.0 ppmv of HONO from > 2.5 ppmv of HCl.The spectrum also contained ∼ 4.0 ppmv of H 2 O.The HCl and H 2 O concentrations are underestimates of their true concentrations since their absorption lines are narrower than the resolution of the FTIR of 0.5 cm −1 .

Figure 3 .
Figure 3. Analysis of the HONO source output by TD-CRDS.The TD-CRDS sampled scrubbed "zero" air before 21:38 UTC and after 21:58 UTC.The HONO source output was varied by incrementally opening (or closing) the bypass valve.The HONO mixing ratio was calculated by subtracting the response of the "HONO reference" from the NO y channel.The insert shows scatter plots of NO 2 , NO x , and "HONO ref" against NO y .Slopes of (1.29 ± 0.06) % for NO 2 (points shown in green), (1.54±0.06)% for NO x (data points shown in orange), and (2.28 ± 0.04) % for "HONO ref" (points shown in grey) were determined, respectively.

Figure 4 .
Figure 4. Inlet temperature scan when the TD-CRDS was sampling a constant concentration of HONO (data points shown in red).The TD profile was reproduced by a fit to Eq. (2) with mixing ratios of (49.97 ± 0.18), (0.27 ± 0.34), and (0.03 ± 0.30) ppbv for HONO, ClNO, and NO x , respectively (black line).The blue dashed line shows the predicted TD curve of a hypothetical mixture containing 5.0 ppbv ClNO and 45.0 ppbv HONO.The insert shows a close-up of the temperature region in which TD of ClNO occurs.

Figure 5 .
Figure 5.Time series of HONO and HCl mixing ratios derived from FTIR analysis of the undiluted HONO source output.The NaNO 2 was placed in line at 10:10 UTC.Data acquired during the initial period are shown in light grey colour.The shaded areas represent the average ±2σ after the source output was judged to have stabilized (after 11:45 UTC; data points shown in black colour).The 1σ precision of the HONO data was ±35 ppbv and that of the HCl data was ±42 ppbv.The HCl mixing ratios are an underestimate because the widths of their absorption lines are less than the FTIR's resolution of 0.5 cm −1 .

Table 1 .
Selected HONO generation systems described in the literature.CAPS: cavity-attenuated phase-shift spectroscopy.n/d: not disclosed.

Table 2 .
Summary of TD-CRDS analyses of the HONO source output.The RH of the diluent gas was in the range of 15 % to 35 %, except for experiments conducted with cylinder gases which are shown below the line.The range of mixing ratios stated is for output after dilution.The stated errors are from regression analyses of plots of NO 2 , NO x , or NO x + ClNO vs. NO y and are at the 1σ level.n/d: not determined.
a Upper limit.b