1 Introduction

Mineral dust aerosol mainly comes from arid and semiarid areas (Ginoux et al., 2012), such as the Sahara, the Taklimakan Desert, etc. Its annual flux and atmospheric loadings are estimated to be $\sim$ 2000 Tg yr${}^{-\mathrm{1}}$ and $\sim$ 19.2 Tg (Textor et al., 2006; Huneeus et al., 2011), making mineral dust one of the most important aerosols in the troposphere. Mineral dust aerosol has significant impacts on atmospheric chemistry, climate and biogeochemical cycles (Knippertz and Stuut, 2014). It can alter the radiative forcing of the earth both directly (Balkanski et al., 2007; Huang et al., 2014; Di Biagio et al., 2017) and indirectly (Cziczo et al., 2013; Karydis et al., 2017). Mineral dust can also change the abundance of reactive trace gases as well as aerosol compositions via heterogeneous reactions (Usher et al., 2003; Dupart et al., 2012; He et al., 2014; Tang et al., 2017; Yu and Jang, 2019). Furthermore, the deposition of mineral dust will bring substantial amounts of nutrients (e.g., Fe and P) into some marine and terrestrial ecosystems, thereby largely affecting biogeochemistry in these regions (Jickells et al., 2005; Okin et al., 2011; Schulz et al., 2012; Li et al., 2017; Tagliabue et al., 2017; Meskhidze et al., 2019). Hygroscopicity largely determines the impacts of mineral dust aerosol on atmospheric chemistry and climate. For example, many studies found that relative humidity (RH) and thus the amount of water associated with mineral dust have profound effects on the rates, mechanisms and products of heterogeneous reactions (Vlasenko et al., 2009; Rubasinghege and Grassian, 2013; Tang et al., 2014; Tang et al., 2017; Lasne et al., 2018; Wang et al., 2018; Yu and Jang, 2018; Mitroo et al., 2019). In addition, hygroscopicity of mineral dust aerosol plays important role in its optical properties (and thus the direct radiative effect) and its ability to act as cloud condensation nuclei and ice-nucleating particles (and thus the indirect radiative effect) (Sorjamaa and Laaksonen, 2007; Kumar et al., 2009; Garimella et al., 2014; Kreidenweis and Asa-Awuku, 2014; Laaksonen et al., 2016; Tang et al., 2016; Tang et al., 2019a). Therefore, a number of previous studies have investigated water adsorption and hygroscopic properties of mineral dust aerosol at $<$ 100 % RH, as reviewed by Tang et al. (2016). However, different studies displayed considerable discrepancies as large as a few orders of magnitude (Tang et al., 2016), thus precluding a good understanding of the role mineral dust aerosol plays in atmospheric chemistry and climate.

As pointed out by Tang et al. (2016), such discrepancies are largely due to the non-sphericity and low hygroscopicity of mineral dust particles, making it difficult to quantify the amount of water associated with them at elevated RH. Instruments which measure mobility or optical diameters of aerosol particles often found that the diameters of mineral dust particles did not increase significantly (or even showed considerable decrease due to particle restructuring during humidification) with increasing RH (Gustafsson et al., 2005; Vlasenko et al., 2005; Herich et al., 2009; Koehler et al., 2009; Attwood and Greenslade, 2011). Fourier transform infrared (FTIR) spectroscopy is a sensitive method to detect adsorbed water on mineral dust (Goodman et al., 2001; Ma et al., 2010a; Joshi et al., 2017); however, it is not a trivial task to convert the intensity of its infrared absorption to the amount of adsorbed water (Schuttlefield et al., 2007b; Ma et al., 2010b; Tang et al., 2016). Quartz crystal microbalance (QCM) is another sensitive technique to examine water adsorption and absorption (Schuttlefield et al., 2007b; Navea et al., 2010; Yeşilbaş and Boily, 2016); however, it is in doubt that the underlying assumptions required to convert the change in resonance frequency of the quartz crystal to the change in sample mass are always fulfilled (Tang et al., 2016; Tang et al., 2019a).

In our previous work (Gu et al., 2017), we developed a new method to investigate hygroscopic properties of atmospherically relevant particles using a vapor sorption analyzer, which utilized a very sensitive balance to measure the mass of a sample (typically with a dry mass of tenths of a milligram or a few milligrams) as different RH under isotherm conditions. Comprehensive validation carried out confirmed the robustness of this method (Gu et al., 2017), and this instrument has been employed to study hygroscopic properties of various particles, including nonspherical particles such as saline mineral dust and pollen grains (Chen et al., 2019; Tang et al., 2019b; Tang et al., 2019c). This instrument was used in the present work to quantitatively investigate hygroscopic properties of a number of mineral dust particles, including several authentic mineral dust samples from different regions in the world and individual minerals commonly found in mineral dust aerosol. We also attempted to figure out which theoretical models could describe hygroscopic properties of mineral dust particles, and we examined the dependence of mineral dust hygroscopicity on several parameters (such as particle diameter, surface area and the mass fraction of soluble materials).

2 Experimental section

2.1 Sample information

In total 21 different types of mineral dust were investigated, including 14 major minerals commonly found in mineral dust aerosol (Formenti et al., 2011; Nickovic et al., 2012; Journet et al., 2014; Scanza et al., 2015; Engelbrecht et al., 2016) and seven authentic mineral dust samples, and their information can be found in Table 1. The 14 major minerals examined included four oxides (SiO${}_{\mathrm{2}}$, TiO${}_{\mathrm{2}}$, magnetite and hematite), one oxyhydroxide (goethite), three feldspars (potassium feldspar, albite and microcline), two carbonates (CaCO${}_{\mathrm{3}}$ and dolomite) and four clay minerals (montmorillonite, illite, kaolinite and chlorite). As shown in Table 1, SiO${}_{\mathrm{2}}$, montmorillonite and kaolinite were supplied by Sigma Aldrich; TiO${}_{\mathrm{2}}$ (P25) was supplied by Degussa; hematite and magnetite were supplied by Strem Chemicals; goethite was provided by Santa Cruz; and microcline, CaCO${}_{\mathrm{3}}$ and dolomite were provided by Alfa Aesar. Potassium feldspar and albite were obtained from the National Research Center of Testing Techniques for Building Materials (NRCTTBM, Beijing, China), and illite (IMt-1) was obtained from the Clay Mineral Society at Purdue University, Indiana, USA (Schuttlefield et al., 2007b; Tang et al., 2014). In addition, chlorite was collected by one co-author from Liaoning Province, China.

Table 1

Measured BET surface areas (BET), average particle diameters ($d_{\mathrm{p}}$) and sources of mineral dust samples examined in this work.

The seven authentic mineral dust samples were obtained from Africa, Asia and North America. As shown in Fig. 1, three authentic mineral dust samples (M'Bour dust, Bordj dust and Saharan dust) were collected from topsoil in Senegal, Algeria and Cabo Verde (Tang et al., 2012; Joshi et al., 2017). QH dust (which is brown desert soil) and China loess, collected from topsoil in Qinghai and Shaanxi, were supplied by the Chinese Academy of Geological Science as certificated materials (GBW07448 and GBW07454) (Tang et al., 2019c). TLF dust as airborne dust particles collected on 23 April 2010 at an urban site in Turpan (Xinjiang, China) during a major dust storm. In addition, Arizona Test Dust (ATD, nominal 0–3 $\mathrm{\mu }\mathrm{m}$ fraction), an authentic mineral dust sample commercially available from Powder Technology Inc. (Minnesota, USA) and widely used in atmospheric aerosol research (Vlasenko et al., 2005; Sullivan et al., 2010a; Tang et al., 2016), was also investigated in our work.

Figure 1

Locations where (a) African and (b) Asian authentic mineral dust samples examined in this work were collected.

[Figure omitted. See PDF]

When received, three feldspars, dolomite, illite, chlorite and TLF dust contained significant amounts of rock chips or giant particles; as a result, they were pretreated using the procedure described in our previous work (Tang et al., 2019c). In brief, these samples were dried at 120 ${}^{\circ }$C for 24 h using an oven; after that, they were ground manually and then using a ball mill so that most particles were $<$ 74 $\mathrm{\mu }\mathrm{m}$ in diameter; finally, these samples were dried again at 120 ${}^{\circ }$C for 24 h and then cooled down. All the samples were stored in plastic bottles which were tightly sealed to prevent contamination by lab air.

Dynamic light scattering (JL-1177, Jingxin Powder Technologies Inc., Chengdu, Sichuan, China) was employed to measure size distributions of mineral dust samples examined in our work. In addition, Brunauer–Emmett–Teller (BET) surface areas of these samples were determined using an accelerated surface area and porosimetry analyzer (ASAP 2020 PLUS, Micromeritics, Georgia, USA), and N${}_{\mathrm{2}}$ was used as the adsorbate. Details on particle size and BET surface area measurements can be found elsewhere (Li et al., 2020).

To measure their inorganic soluble compositions, each mineral dust sample ($\sim$ 10 mg) was mixed with 10 mL of ultrapure deionized water, and the mixture was stirred for 2 h using an oscillating table. After centrifugalization, the solution was filtered using a 5 mL syringe fitted with a 0.2 $\mathrm{\mu }\mathrm{m}$ PTFE membrane syringe and then analyzed using ion chromatography (Metrohm model 761 Compact IC, Metrohm, Herisau, Switzerland). More information on ion chromatography analysis can be found in our previous work (Tang et al., 2019c). We attempted to measure five cations (Na${}^{+}$, K${}^{+}$, NH${}_{\mathrm{4}}^{+}$, Mg${}^{\mathrm{2}+}$ and Ca${}^{\mathrm{2}+}$) and seven anions (NO${}_{\mathrm{3}}^{-}$, SO${}_{\mathrm{4}}^{\mathrm{2}-}$, Cl${}^{-}$, NO${}_{\mathrm{2}}$-, Br${}^{-}$, F${}^{-}$ and PO${}_{\mathrm{4}}^{\mathrm{3}-}$), and their detection limits were estimated to be around 0.02 mg/L.

2.3 Hygroscopicity measurements

Hygroscopic properties of mineral dust samples were investigated using a vapor sorption analyzer (Q5000SA, TA instruments, Delaware, USA). This instrument, described in our previous work (Gu et al., 2017; Chen et al., 2019; Tang et al., 2019b), measured sample mass as a function of RH under isotherm conditions. Measurements could be conducted in the RH range of 0 %–98 % and in the temperature range of 5–85 ${}^{\circ }$C. We routinely measured the deliquescence RH of NaCl, (NH${}_{\mathrm{4}}{)}_{\mathrm{2}}$SO${}_{\mathrm{4}}$ and KCl at 25 ${}^{\circ }$C, and the measured values differed from the actual values by $<$ 1 % RH. The sample mass could be measured with an accuracy of $\pm$0.1 $\mathrm{\mu }\mathrm{g}$, and the uncertainties for temperature and RH were $\pm$0.1 ${}^{\circ }$C and $\pm$1 %.

Figure 2

RH (black curve, left $y$ axis) and mass of mineral dust (normalized to that at $<$ 1 % RH, blue curve, right $y$ axis) as a function of experimental time: (a) hematite and (b) montmorillonite.

[Figure omitted. See PDF]

In this work, the initial masses of mineral dust samples used typically ranged from 5 to 15 mg. As displayed in Fig. 2, the sample under investigation was first dried at $<$ 1 % RH; after that, RH was increased in a stepwise manner to 90 %, and at each step RH was increased by 10 %; at last, the sample was dried again at $<$ 1 % RH. At each step we changed the RH only after the samples' mass became stable (in other words, only after an equilibrium was reached between gaseous and particulate water), and the sample mass was considered to be stable when the mass change was $<$ 0.05 % in 30 min. In some experiments the sample was considered to reach the equilibrium only when the mass change was $<$ 0.05 % in 60 min, and no significant difference in results was found for the two equilibrium criterions. All the experiments were carried out in triplicate at 25 ${}^{\circ }$C.

3.1 Sample characteristics

As shown in Table 1, the BET surface areas were found to vary between 2.17 $\pm$ 0.01 m${}^{\mathrm{2}}$/g (microcline) and 249.91 $\pm$ 0.42 m${}^{\mathrm{2}}$/g (montmorillonite), spanning over 2 orders of magnitude. Except for montmorillonite, the BET surface areas were in the range of a few to tens of square meters per gram. In addition, the average particle diameters ($d_{\mathrm{p}}$) were determined to range from 0.80 $\mathrm{\mu }\mathrm{m}$ (hematite) to 54.41 $\mathrm{\mu }\mathrm{m}$ (M'Bour dust), and their size distributions can be found in Figs. S1–S7 in the Supplement.

Tables S1–S2 show mass fractions of water-soluble inorganic ions for the 21 mineral dust samples considered in this study. Na${}^{+}$, K${}^{+}$, Ca${}^{\mathrm{2}+}$, Mg${}^{\mathrm{2}+}$, F${}^{-}$, Cl${}^{-}$ and SO${}_{\mathrm{4}}^{\mathrm{2}-}$ were detected in most of the samples, while NH${}_{\mathrm{4}}^{+}$ was above its detection limit only for two samples. The total mass fractions of all the soluble inorganic ions were found to be quite low, ranging from 0.16 mg/g for SiO${}_{\mathrm{2}}$ to 12.55 mg/g for Bordj dust.

3.2 Water uptake by different mineral dust

As described in Sect. 2.3, sample mass of mineral dust was measured at different RH values in our work; therefore, the mass ratio of adsorbed water to the dry mineral, $m_{\mathrm{w}}/m_{\mathrm{0}}$, could then be determined as a function of RH. Furthermore, $m_{\mathrm{w}}/m_{\mathrm{0}}$ could be converted to fractional surface coverage (abbreviated as surface coverage) of adsorbed water ($\mathit{\theta }$), using Eq. (1) (Tang et al., 2016):

1$$\mathit{\theta }={\displaystyle \frac{m_{\mathrm{w}}}{m_{\mathrm{0}}}}\cdot {\displaystyle \frac{N_{\mathrm{A}}\cdot A_{\mathrm{w}}}{M_{\mathrm{w}}\cdot A_{\mathrm{BET}}}},$$ where $N_{\mathrm{A}}$ is Avogadro's constant ($\mathrm{6.02}\times {\mathrm{10}}^{\mathrm{23}}$ mol${}^{-\mathrm{1}}$), $M_{\mathrm{w}}$ is the molar mass of water (18 g mol${}^{-\mathrm{1}}$), $A_{\mathrm{w}}$ is the surface area each adsorbed water molecule would occupy (assumed to be 1 $\times$ 10${}^{-\mathrm{15}}$ cm${}^{\mathrm{2}}$) (Schuttlefield et al., 2007a; Hatch et al., 2014; Tang et al., 2016) and $A_{\mathrm{BET}}$ is the BET surface (in cm${}^{\mathrm{2}}$ g${}^{-\mathrm{1}}$) of the mineral dust under consideration. Tables 2–5 summarize $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ as a function of RH for all the mineral dust examined in our work. Please note that our previous work (Tang et al., 2019c) discussed water uptake by China loess and QH dust, and these results are included here to compare with the other 19 mineral dust samples.

Mass ratios of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$) and surface coverages of adsorbed water ($\mathit{\theta }$) as a function of RH (%) for SiO${}_{\mathrm{2}}$, TiO${}_{\mathrm{2}}$, magnetite, hematite, goethite and potassium feldspar.

Below we discuss hygroscopicity of mineral dust investigated, and we compare our measured $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ with those reported in previous work. As our work directly measured mass change of mineral dust due to water uptake, we prefer to compare $m_{\mathrm{w}}/m_{\mathrm{0}}$ when such values were also reported in previous studies; otherwise, we then choose to compare $\mathit{\theta }$. As aerosol-based measurements are usually not sensitive enough and also need the particle sphericity assumption (Tang et al., 2016), we do not compare our results with those measurements.

SiO${}_{\mathrm{2}}$ and TiO${}_{\mathrm{2}}$

In our work $m_{\mathrm{w}}/m_{\mathrm{0}}$ was determined to be 0.0011, 0.0020 and 0.0058 for SiO${}_{\mathrm{2}}$ at 30 %, 60 % and 90 % RH, corresponding to $\mathit{\theta }$ of 0.55, 1.04 and 2.95, respectively. Figure 3a compares our work with previous studies in which FTIR (Goodman et al., 2001; Ma et al., 2010a; Joshi et al., 2017) and QCM (Schuttlefield et al., 2007a; Yeşilbaş and Boily, 2016) were used to measure water uptake by SiO${}_{\mathrm{2}}$. At a given RH, $\mathit{\theta }$ values reported by the four previous studies (Goodman et al., 2001; Schuttlefield et al., 2007a; Ma et al., 2010a; Joshi et al., 2017) were generally larger when compared to our work, and the difference usually did not exceed a factor of 3. Furthermore, the differences between our work and the four previous studies became smaller at higher RH. For example, at 80 % RH our measured $\mathit{\theta }$ was very close to those reported by Ma et al. (2010a) and Joshi et al. (2017), and at 90 % RH our measured $\mathit{\theta }$ was 20 %–30 % larger than those reported by the two studies (Ma et al., 2010a; Joshi et al., 2017). Yeşilbaş and Boily (2016) employed a QCM to investigate water adsorption on quartz (0.3–14 $\mathrm{\mu }\mathrm{m}$), and $\mathit{\theta }$ was determined to be $\sim$ 2300 at $\sim$ 70 % RH, almost 3 orders of magnitude larger than those reported in our work and other previous studies (Goodman et al., 2001; Schuttlefield et al., 2007a; Ma et al., 2010a; Joshi et al., 2017); therefore, the results reported by Yeşilbaş and Boily (2016) are not displayed in Fig. 3a.

Figure 3

Comparison of surface coverages of adsorbed water ($\mathit{\theta }$) measured in our work with those reported in previous studies for  (a) SiO${}_{\mathrm{2}}$ and (b) TiO${}_{\mathrm{2}}$. G01: Goodman et al. (2001); S07: Schuttlefield et al. (2007a); M10: Ma et al. (2010a); J17: Joshi et al. (2017); K07: Ketteler et al. (2007).

[Figure omitted. See PDF]

For TiO${}_{\mathrm{2}}$, $m_{\mathrm{w}}/m_{\mathrm{0}}$ was determined to be 0.0072, 0.0135 and 0.0355 at 30 %, 60 % and 90 % RH, corresponding to $\mathit{\theta }$ of 0.44, 0.82 and 2.17, respectively. Water adsorption on P25 TiO${}_{\mathrm{2}}$ was studied previously using FTIR (Goodman et al., 2001; Ma et al., 2010a), and another study (Ketteler et al., 2007) employed atmospheric pressure X-ray photoelectron spectroscopy to explore interactions of water vapor with the rutile single crystal surface (110). As shown in Fig. 3b, when compared with our work, $\mathit{\theta }$ values reported by Ma et al. (2010a) were higher across the entire RH range, and the relative differences between our work and Ma et al. (2010a) were around a factor of 2 or smaller. The relative differences between our work and the other two studies (Goodman et al., 2001; Ketteler et al., 2007) were larger, being a factor of $\sim$ 5 at lower RH and becoming smaller at higher RH.

At 30 %, 60 % and 90 % RH, $m_{\mathrm{w}}/m_{\mathrm{0}}$ was measured to be 0.0029, 0.0047 and 0.0101 for hematite, corresponding to $\mathit{\theta }$ of 1.03, 1.72 and 3.68, respectively. Water adsorption on hematite was studied previously using FTIR (Goodman et al., 2001; Ma et al., 2010a) and QCM (Yeşilbaş and Boily, 2016). Figure 4a reveals that our results agreed reasonably well with those reported by Goodman et al. (2001) and Ma et al. (2010a), and the relative differences were found to be within a factor of 2. In addition, our results agreed fairly well with those reported for 10 nm hematite by Yeşilbaş and Boily (2016) but were significantly smaller than their results for 50 nm hematite. Yeşilbaş and Boily (2016) also studied water adsorption on 4 and 5 $\mathrm{\mu }\mathrm{m}$ hematite particles, and $\mathit{\theta }$ values were reported to be $\sim$ 300 at $\sim$ 70 % RH, almost 2 orders of magnitude larger than our results; therefore, their measured $\mathit{\theta }$ values for 4 and 5 $\mathrm{\mu }\mathrm{m}$ hematite are not shown in Fig. 4a.

In our work, $m_{\mathrm{w}}/m_{\mathrm{0}}$ was measured to be 0.0029, 0.0052 and 0.0124 at 30 %, 60 % and 90 % RH for goethite, corresponding to $\mathit{\theta }$ of 0.73, 1.30 and 3.09. Yeşilbaş and Boily (2016) employed QCM to study water adsorption on goethite, and their measured $\mathit{\theta }$ values are plotted in Fig. 4b to compare to ours. When compared to our work, on average $\mathit{\theta }$ values measured by Yeşilbaş and Boily (2016) were a factor of $\sim$ 2 larger. We also investigated water adsorption on magnetite, and the results can be found in Fig. 4b. Compared to goethite, $\mathit{\theta }$ values were generally 20 %–30 % smaller for magnetite. As far as we know, water adsorption on magnetite was not quantitatively investigated before.

Figure 4

Comparison of surface coverages of adsorbed water ($\mathit{\theta }$) measured in our work with those reported in previous studies for (a) hematite and (b) goethite ($\mathit{\theta }$ values measured in our work for magnetite are also plotted). G01: Goodman et al. (2001); M10: Ma et al. (2010a); Y16: Yeşilbaş and Boily (2016).

[Figure omitted. See PDF]

Tables 2–3 show that the mass ratios of adsorbed water to the dry mineral were determined to be 0.0056, 0.0060 and 0.0048 at 90 % RH for potassium feldspar, albite and microcline, respectively; correspondingly, $\mathit{\theta }$ values were found to be 4.73, 5.53 and 7.37. QCM was used by Yeşilbaş and Boily (2016) to study water uptake onto microcline, and $\mathit{\theta }$ was measured to be $\sim$ 300 at $\sim$ 70 % RH, about 2 orders of magnitude larger than our measurement. We are not aware of other previous studies which investigated water adsorption on feldspars in a quantitative manner.

Table 3

Mass ratios of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$) and surface coverages of adsorbed water ($\mathit{\theta }$) as a function of RH (%) for albite, microcline, CaCO${}_{\mathrm{3}}$, dolomite, illite and kaolinite.

The mass ratio of adsorbed water to the dry mineral, $m_{\mathrm{w}}/m_{\mathrm{0}}$, was measured in our work to be 0.0011 at 90 % RH for CaCO${}_{\mathrm{3}}$, giving a $\mathit{\theta }$ value of 1.73. Water adsorption on CaCO${}_{\mathrm{3}}$ was investigated previously, using thermogravimetric analysis (Gustafsson et al., 2005), physisorption analysis (Ma et al., 2012a) and QCM (Hatch et al., 2008; Schuttlefield, 2008; Yeşilbaş and Boily, 2016). Hatch et al. (2008) and Ma et al. (2012a) reported $m_{\mathrm{w}}/m_{\mathrm{0}}$ as a function of RH. Figure 5a shows that when compared to our work, $m_{\mathrm{w}}/m_{\mathrm{0}}$ values determined by Hatch et al. (2008) were significantly larger (by a factor of 10 or more), whereas the results reported by Ma et al. (2012a) were only smaller by a factor of $\sim$ 2. We further compare our measured $\mathit{\theta }$ values with those reported by another two studies (Gustafsson et al., 2005; Schuttlefield, 2008). As shown in Fig. 5b, the results reported by Gustafsson et al. (2005) and Schuttlefield (2008) were found to be larger than ours, by a factor of 2–3. In addition, $\mathit{\theta }$ was measured to be $>$ 100 at $\sim$ 70 % RH for CaCO${}_{\mathrm{3}}$ (Yeşilbaş and Boily, 2016), approximately 2 orders of magnitude larger than our work.

As shown in Table 3, our work suggested that around 1.26 monolayers of adsorbed water were formed on dolomite at 90 % RH, similar to that for CaCO${}_{\mathrm{3}}$. To our knowledge, water adsorption on dolomite has not been quantitatively explored by previous work.

Figure 5

Comparison of water adsorption on CaCO${}_{\mathrm{3}}$ examined in different studies: (a) mass ratios of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$); (b) surface coverages of adsorbed water ($\mathit{\theta }$). G05, Gustafsson et al. (2005); H08, Hatch et al. (2008); S08, Schuttlefield (2008); M12, Ma et al. (2012a).

[Figure omitted. See PDF]

For illite, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were determined to be 0.0333 and 4.63 at 90 % RH in our study (Table 3). QCM was employed to study water adsorption on illite, and $m_{\mathrm{w}}/m_{\mathrm{0}}$ was reported to be 0.28 at $\sim$ 90 % RH (Hatch et al., 2011) and $\sim$ 0.27 at 75 % RH (Schuttlefield et al., 2007b), around 1 order of magnitude larger than our results. A recent study (Yeşilbaş and Boily, 2016) also investigated water uptake onto illite using QCM, and their reported $\mathit{\theta }$ values are compared with our results in Fig. 6a. The relative differences between our and their (Yeşilbaş and Boily, 2016) work were usually smaller than a factor of 2 and became even smaller at higher RH.

Figure 6

Comparison of surface coverages of adsorbed water ($\mathit{\theta }$) measured by different studies for (a) illite and (b) kaolinite. H15, Hung et al. (2015); Y16, Yeşilbaş and Boily (2016).

[Figure omitted. See PDF]

For kaolinite, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were determined in our work to be 0.0093 and 3.22 at 80 % RH and 0.0146 and 5.08 at 90 % RH, respectively. A few previous studies investigated water adsorption on kaolinite using QCM (Schuttlefield et al., 2007b; Hatch et al., 2011; Yeşilbaş and Boily, 2016) and physisorption analysis (Hung et al., 2015). Comparison of our measured $\mathit{\theta }$ values with those reported by Hung et al. (2015) is displayed in Fig. 6b for kaolinite, suggesting that the two studies were in good agreement, and the relative differences were usually within 30 %. At $\sim$ 80 % RH, $m_{\mathrm{w}}/m_{\mathrm{0}}$ values were determined to be $\sim$ 0.03 for kaolinite provided by Alfa and $\sim$ 0.1 for kaolinite (KGa-1b) obtained from the Clay Mineral Society (Schuttlefield et al., 2007b), around 3 and 10 times larger than our work. In the work by Hatch et al. (2011), $m_{\mathrm{w}}/m_{\mathrm{0}}$ was determined to be $\sim$ 0.1 at $\sim$ 80 % RH for kaolinite (KGa-1b), about 1 order of magnitude larger than our result. Yeşilbaş and Boily (2016) examined water adsorption on two different kaolinite samples (kaolinite provided by Fluka and KGa-1), and $\mathit{\theta }$ values were found to be up to 100 at $\sim$ 70 % RH, $>$ 30 times larger than our work.

Figure 7

Comparison of water adsorption on montmorillonite examined in different studies: (a) surface coverages of adsorbed water ($\mathit{\theta }$); (b) the mass ratio of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$). F05, Frinak et al. (2005); S07, Schuttlefield et al. (2007b); H11, Hatch et al. (2011); H15, Hung et al. (2015); Y16, Yeşilbaş and Boily (2016).

[Figure omitted. See PDF]

We also studied water adsorption on montmorillonite, and $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were measured to be 0.308 and 4.12 at 90 % RH. Physisorption analysis (Hung et al., 2015) and QCM (Yeşilbaş and Boily, 2016) were utilized to investigate water uptake onto montmorillonite. As shown in Fig. 7a, our work agreed well with Hung et al. (2015), and the results obtained by Yeşilbaş and Boily (2016) for Ca and Na montmorillonite were much larger (by a factor of $>$ 10), when compared with our work. Figure 7b compares our measured $m_{\mathrm{w}}/m_{\mathrm{0}}$ values with those reported in previous studies in which FTIR (Frinak et al., 2005) and QCM (Schuttlefield et al., 2007b; Hatch et al., 2011) were used. In general good agreement between our work and the three previous studies was found, except for SAz-1 montmorillonite (Schuttlefield et al., 2007b) obtained from the Clay Mineral Society. One possible explanation for the observed discrepancy is that montmorillonite samples from different sources may have different hygroscopic properties. We note that prior to 2005, a few studies (Hall and Astill, 1989; Cases et al., 1992; Xu et al., 2000; Zent et al., 2001) also investigated water uptake by montmorillonite, and it was found that these studies agreed well with Frinak et al. (2005); therefore, the four studies conducted before 2005 should also be consistent with our work.

In addition, water uptake by chlorite was explored in our work. As shown in Table 4, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were measured to be 0.012 and 4.03 at 90 % RH. To our knowledge, hygroscopic properties of chlorite have not been examined before.

Mass ratio of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$) and surface coverages of adsorbed water ($\mathit{\theta }$) as a function of RH (%) for montmorillonite, chlorite, ATD, M'Bour dust, Bordj dust and Saharan dust.

ATD. Table 4 suggests that at 90 % RH, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were measured in our work to be 0.0644 and 5.87 for ATD. Two previous studies (Navea et al., 2010; Yeşilbaş and Boily, 2016) employed QCM to investigate water adsorption on ATD. In the first study (Navea et al., 2010), $m_{\mathrm{w}}/m_{\mathrm{0}}$ was measured to be $>$ 0.1 at 70 % RH, 2–3 times larger than our result ($\sim$ 0.04 at 70 % RH); in the second study (Yeşilbaş and Boily, 2016), $\mathit{\theta }$ was measured to be $>$ 200 at $\sim$ 70 % RH, almost 2 orders of magnitude larger than our work ($\sim$ 3.6 at 70 % RH). Gustafsson et al. (2005) used a thermogravimetric analyzer to study water uptake by ATD, and as shown in Fig. 8a, their results agreed very well with ours. A recent study (Joshi et al., 2017) investigated water adsorption on ATD using FTIR; compared to our work, the values reported by Joshi et al. (2017) were $\sim$ 30 % lower, suggesting fairly good agreement between the two studies.

Figure 8

Comparison of surface coverages of adsorbed water ($\mathit{\theta }$) reported in different studies for (a) ATD and (b) Bordj dust and M'Bour dust. G05, Gustafsson et al. (2005); J17, Joshi et al. (2017).

[Figure omitted. See PDF]

African dust. In our study, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were measured to be 0.0192 and 3.91 for Bordj dust and 0.0152 and 3.51 for M'Bour dust at 90 % RH, respectively. Joshi et al. (2017) employed FTIR to investigate interaction of water vapor with Bordj dust and M'Bour dust. As suggested by Fig. 8b, the relative differences between our and their work (Joshi et al., 2017) were usually within a factor of 2 for the two dust samples, and the discrepancy also became smaller at higher RH, suggesting fair consistency between the two studies.

For Saharan dust, $m_{\mathrm{w}}/m_{\mathrm{0}}$ and $\mathit{\theta }$ were determined in our study to be 0.0793 and 5.15 at 90 % RH. Water uptake onto Saharan dust was studied using QCM (Navea et al., 2010), and their results, as shown in Fig. 9a, were 2–3 times larger than our work.

Figure 9

(a) Comparison of mass ratios of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$) measured by our work and N10 (Navea et al., 2010) for Saharan dust. (b) Comparison of surface coverages of adsorbed water ($\mathit{\theta }$) for TLF dust measured in our work with Beijing dust measured in M12 (Ma et al., 2012b).

[Figure omitted. See PDF]

Asian dust. Table 5 summarizes our results obtained for three Asian mineral dust samples, including China loess, QH dust and TLF dust. It should be pointed out that $m_{\mathrm{w}}/m_{\mathrm{0}}$ values have been reported in our previous work (Tang et al., 2019c) for China loess and QH dust, and they are included here for comparison. As shown in Table 5, the three Asian authentic dust samples exhibited very similar water uptake properties, and their $m_{\mathrm{w}}/m_{\mathrm{0}}$ values were determined to be 0.021–0.022 at 90 % RH. Navea et al. (2010) employed QCM to study the interaction of water vapor with China loess, and $m_{\mathrm{w}}/m_{\mathrm{0}}$ was reported to be $\sim$ 0.17 at 70 % RH, more than 1 order of magnitude larger than our result ($\sim$ 0.012 at 70 % RH).

As mentioned in Sect. 2.1, TLF dust examined in our work was airborne dust particles collected during a dust storm in Turpan (Xinjiang, China) which was very close to the dust source. In a previous study (Ma et al., 2012b), dust particles (termed Beijing dust here) were collected during a dust storm in Beijing (and thus these particles had undergone atmospheric aging to some extent), and their hygroscopic properties were then investigated using a physisorption analyzer. As revealed by Fig. 9b, our work agreed fairly well with Ma et al. (2012b) at high RH (70 %, 80 % and 90 %), though the differences became considerably larger at lower RH.

Mass ratios of adsorbed water to the dry mineral ($m_{\mathrm{w}}/m_{\mathrm{0}}$) and surface coverages of adsorbed water ($\mathit{\theta }$) as a function of RH (%) for QH dust, China loess and TLF dust.

To investigate water adsorption by mineral dust, one previous study (Gustafsson et al., 2005) employed thermogravimetric analysis which measured sample mass as a function of RH (essentially the same to vapor sorption analyzer (VSA) used in our study), and another two groups (Ma et al., 2012a, b; Hung et al., 2015) employed physisorption analysis which measured change in water vapor pressure caused by adsorption onto mineral dust (Ma et al., 2010b). Thermogravimetric analysis, physisorption analysis and the VSA technique used in our work can be considered absolutely quantitative, and as discussed in Sect. 3.2.1–3.2.6, in general our work agreed well with these four previous studies (Gustafsson et al., 2005; Ma et al., 2012a, b; Hung et al., 2015).

FTIR was widely employed in previous work (Goodman et al., 2001; Frinak et al., 2005; Ma et al., 2010a; Joshi et al., 2017; Ibrahim et al., 2018) to study water uptake onto mineral dust, although it is not straightforward to convert IR absorption intensities of adsorbed water to its absolute amounts (Schuttlefield et al., 2007a; Ma et al., 2010b; Tang et al., 2019a). The relative differences between these studies and our work were typically within a factor of 2–3; since even for dust samples with the same name, samples examined in different studies may actually differ substantially in composition and water uptake properties, the agreement between these studies and our work can be considered fairly good.

QCM is another technique widely used to investigate water uptake onto mineral dust (Schuttlefield et al., 2007b; Hatch et al., 2008; Schuttlefield, 2008; Navea et al., 2010; Hatch et al., 2011; Yeşilbaş and Boily, 2016). As shown in Sect. 3.2.1–3.2.6, though good agreement was found for some mineral dust between our work and these QCM studies, large discrepancies (up to 2–3 orders of magnitude) were frequently observed. This implies that the underlying assumptions required to convert the change in resonance frequency of the quartz crystal to the change in sample mass may not be fulfilled, and as a result the QCM results should be used with caution.

For the same dust (at least with the same name), different samples with distinctive hygroscopicity may have been used in our work and previous studies, contributing to the observed discrepancies; in addition, previous work may adopt various pretreatment procedures, and it is difficult to assess the effects of these pretreatments on dust hygroscopicity reported in different studies. To further understand and resolve the discrepancies identified, it will be very useful to distribute the same samples to different groups (in which different techniques would be applied to study their hygroscopic properties) and compare the results obtained; furthermore, these samples should be pretreated with the same or very similar protocols after being received by different groups. Similar strategies have already been adopted before to compare different instruments used for ice nucleation research and shown to be valuable (Hiranuma et al., 2015; DeMott et al., 2018).

3.3 Hygroscopicity parameterizations

It has been suggested that water adsorption and hygroscopicity of insoluble particles can be parameterized as a function of RH by several theoretical models, including (1) the Brunauer–Emmet–Teller (BET) adsorption isotherm (Goodman et al., 2001; Ma et al., 2010a; Joshi et al., 2017; Ibrahim et al., 2018), (2) the Freundlich adsorption isotherm (Hatch et al., 2011), (3) the Frenkel–Halsey–Hill (FHH) adsorption isotherm (Kumar et al., 2011b; Hatch et al., 2014; Hung et al., 2015; Hatch et al., 2019) and (4) the $\mathit{\kappa }$-Köhler equation (Chen et al., 2019; Tang et al., 2019b). In this work we attempted to use the aforementioned four models to fit our experimental data. As shown in Fig. 10 (where SiO${}_{\mathrm{2}}$, albite, kaolinite and TLF dust are used as examples), our work suggested that the FHH adsorption isotherm could describe the measured hygroscopicity of mineral dust samples as a function of RH well. In addition, we found that the other three parameterization methods could not fit our experimental data.

Figure 10

Surface coverages ($\mathit{\theta }$) of adsorbed water on (a) SiO${}_{\mathrm{2}}$, (b) albite, (c) kaolinite and (d) TLF dust as a function of RH (0 %–90 %) at 25 ${}^{\circ }$C. The experimental data were fitted with Frenkel–Halsey–Hill adsorption isotherm model (solid curves).

[Figure omitted. See PDF]

The FHH adsorption isotherm, which describes surface coverages of adsorbed water ($\mathit{\theta })$ as a function of RH, is given by Eq. (2) (Sorjamaa and Laaksonen, 2007; Tang et al., 2016): 2$$\mathit{\theta }=\sqrt[B_{\text{FHH}}]{{\displaystyle \frac{A_{\text{FHH}}}{-\ln \left(\mathrm{RH}\right)}}},$$ where $A_{\text{FHH}}$ and $B_{\text{FHH}}$ are empirical parameters. We found that Eq. (2) can fit $\mathit{\theta }$ versus RH well for all the 21 mineral dust samples examined ($R^{\mathrm{2}}$ values were found to be in the range of 0.94–0.99), and the generated $A_{\text{FHH}}$ and $B_{\text{FHH}}$ values are summarized in Table 6. As shown in Table 6, $A_{\text{FHH}}$ values spanned from 0.15 $\pm$ 0.01 (dolomite) to 4.39 $\pm$ 0.81 (ATD), while the variation in $B_{\text{FHH}}$ was much smaller, ranging from 1.10 $\pm$ 0.04 (for Bordj dust) to 1.91 $\pm$ 0.18 (for ATD). Our results were largely consistent with the theoretical work by Sorjamaa and Laaksonen (2007), who suggested from a theoretical view that typical $A_{\text{FHH}}$ and $B_{\text{FHH}}$ values should be in the range of 0.1–3.0 and 0.5–3.0.

Comparison of $A_{\text{FHH}}$ and $B_{\text{FHH}}$ values determined in our work for mineral dust with those reported in previous studies (${}^{\mathrm{a}}$ Kumar et al., 2011a; ${}^{\mathrm{b}}$ Hung et al., 2015; ${}^{\mathrm{c}}$ Hatch et al., 2019).

A few previous studies investigated hygroscopic properties (Hung et al., 2015; Hatch et al., 2019) and cloud condensation nuclei (CCN) activities (Kumar et al., 2011b) of mineral dust and reported $A_{\text{FHH}}$ and $B_{\text{FHH}}$ values for samples they examined. Their results are also compiled in Table 6. As revealed by Table 6, $B_{\text{FHH}}$ values reported in our work were reasonably consistent with previous studies, while larger differences were observed for $A_{\text{FHH}}$ values, especially between our study and the work by Kumar et al. (2011a) for SiO${}_{\mathrm{2}}$ and CaCO${}_{\mathrm{3}}$. One reason for such a large difference is that Kumar et al. (2011a) carried out their CCN activity measurements at $>$ 100 % RH whereas our work on hygroscopic growth was conducted at $<$ 100 % RH. Another study (Kumar et al., 2011a) reported $A_{\text{FHH}}$ and $B_{\text{FHH}}$ values for wet-generated mineral dust aerosols. Since the hygroscopicity of wet-generated mineral dust aerosols could be very different from dry-generated aerosols (Sullivan et al., 2010b; Kumar et al., 2011a), the results reported by Kumar et al. (2011b) for wet-generated aerosols are not further discussed.

As shown in Tables 2–5, among the 21 mineral dust samples examined, $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ (mass ratios of adsorbed water at 90 % RH to the dry sample) was found to range from 0.0011 for CaCO${}_{\mathrm{3}}$ to 0.0380 for montmorillonite, and $\mathit{\theta }$(90 %) (surface coverages of adsorbed water at 90 % RH) varied between 1.26 for dolomite and 8.63 for TLF dust. It appears that clay minerals and authentic mineral dust samples usually exhibited larger hygroscopicity on a per mass basis, when compared to other types of mineral dust. TiO${}_{\mathrm{2}}$, for which $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ was only lower than ATD, Saharan dust and montmorillonite, was an outstanding exception, probably because of its very large BET surface area (54.6 m${}^{\mathrm{2}}$ g${}^{-\mathrm{1}}$).

One may expect that on a per mass basis, mineral dust samples with larger surface area would have larger capacities to adsorb water. This was supported by our results shown in Fig. 11a, which suggests that for mineral dust samples considered in our study, overall $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ increased with the BET surface area. Nevertheless, not all the samples obeyed this overall trend, as evident from Fig. 11a, indicating that other factors would also play some roles in determining the ability of mineral dust to adsorb water on a per mass basis. We also explored whether there was any relationship between hygroscopicity of mineral dust samples and the soluble materials they contained. It was found that for the 21 mineral dust samples considered in our work, $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ did not show any general dependence on the number of soluble inorganic ions.

Figure 11

(a) The dependence of $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ (mass ratios of adsorbed water to the dry mineral at 90 % RH) on BET surface areas; (b) the dependence of $\mathit{\theta }$(90 %) (surface coverages of adsorbed water at 90 % RH) on average particle diameters.

[Figure omitted. See PDF]

Ibrahim et al. (2018) studied water adsorption on ATD particles with different particle sizes, and they found that the RH at which one monolayer of adsorbed water was formed increased with particle size; in other words, at the same RH the surface coverages of adsorbed water would be higher for smaller particles (Ibrahim et al., 2018). In contrast, Yeşilbaş and Boily (2016) investigated water adsorption on different mineral samples (21 in total) and suggested that at the same RH more monolayers of adsorbed water would be formed on larger particles. However, as shown in Fig. 11b in which our measured $\mathit{\theta }$ values at 90 % RH are plotted versus particle size, our work revealed that surface coverages of adsorbed water at 90 % RH showed no dependence on particle size for the 21 mineral dust samples examined in our work. This conclusion should be used with caution as dust samples used in our work were far from being monodisperse (see Figs. S1–S7).

Hygroscopicity largely determines environmental and climatic effects of mineral dust aerosol, one of the most abundant tropospheric aerosols. However, hygroscopic properties of mineral dust remain highly uncertain, due to relatively low hygroscopicity of mineral dust and its non-sphericity. In our work, a vapor sorption analyzer, which measured sample mass as a function of RH ($<$ 1 % to 90 %), was employed to investigate water adsorption and hygroscopic properties of 21 different mineral dust samples, including seven authentic mineral dust samples (from Africa, China and the United States) and 14 major minerals found in tropospheric mineral dust aerosol.

For all the mineral dust samples (21 in total) examined, $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ was found to range from 0.0011 (CaCO${}_{\mathrm{3}}$) to 0.3080 (montmorillonite), and $\mathit{\theta }$(90 %) varied between 1.26 (dolomite) and 8.63 (TLF dust). When compared to other types of mineral dust, clay minerals and authentic mineral dust samples usually exhibited larger hygroscopicity on a per mass basis. Our work suggested that overall $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ increased with the BET surface area, indicating that on a per mass basis, mineral dust samples with larger surface area would have larger capacities to adsorb water in general. Our results revealed no dependence of $m_{\mathrm{w}}$(90 %)$/m_{\mathrm{0}}$ on the amount of soluble materials contained or no dependence of $\mathit{\theta }$(90 %) on particle size. In addition, it was found in our work that the Frenkel–Halsey–Hill (FHH) adsorption isotherm could describe surface coverages of adsorbed water as a function of RH well for all the mineral dust investigated, and $A_{\text{FHH}}$ and $B_{\text{FHH}}$ parameters were determined to be in the range of 0.15–4.39 and 1.10–1.91, respectively.