Abstract
The dissolved silica structures in quartz-saturated 0.50 and 1.50 m [mol kg H2O–1] Na2CO3 and 0.47 m NaOH solutions at up to 750 °C and 1.5 GPa were investigated by in-situ Raman spectroscopy using a Bassett-type hydrothermal diamond anvil cell. The solubility of quartz in the solutions was determined by in-situ observations of the complete dissolution of the grain. The Raman spectra of the quartz-saturated Na2CO3 and NaOH solutions at high pressures and temperatures exhibited the tetrahedral symmetric stretching band of silica monomers. The lower frequency and broader width of the band than those in pure H2O indicated the presence of both neutral and deprotonated monomers. In addition, we newly confirmed the intense bridging oxygen band and the tetrahedral symmetric stretching band of Q1 (silicate center having a single bridging oxygen atom) in the spectra of the Na2CO3 solutions. The integrated intensity ratios of the bridging oxygen band to the monomer band increased with the addition of Na2CO3 and NaOH to fluids, corresponding to an elevation of the measured quartz solubilities. These observations indicate that the formation of silica oligomers in addition to neutral and deprotonated monomers explains the high dissolved silica concentrations in the solutions. The presence of deprotonated monomers under the experimental conditions suggests that deprotonated oligomers exist in the solutions, because the production of the latter more significantly reduces the Gibbs free energy. The anionic silica species and oligomers formed in alkaline silicate fluids may act as effective ligands for certain metal ions or complexes in deep subduction zones.
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Introduction
Aqueous fluids facilitate the mass transport of elements for the deep hydrothermal processes involved in metamorphism, metasomatism, and ore formation in the crust and upper mantle of the Earth. Silica is a major constituent of rock-forming minerals and is abundantly dissolved in the deep aqueous fluids. The mobilization of silica by the aqueous fluids has been observed as quartz veins and silica metasomatic zones of exhumed subduction zone rocks (Bebout and Barton 1989; Yardley and Bottrell 1992; Breeding and Ague 2002) and quartz-rich regions in the lower forearc crust with low Poisson’s ratios (Audet and Bürgmann 2014; Hyndman et al. 2015). Understanding the efficiency of silica transportation in the deep crust and upper mantle requires detailed knowledge of silica solubility and speciation in aqueous fluids under high pressure (P) and temperature (T) conditions. Because of such importance, a significant number of experimental studies have been conducted on quartz solubility in pure H2O (e.g., Anderson and Burnham 1965; Manning 1994), H2O–CO2 (e.g., Newton and Manning 2000; Shmulovich et al. 2001), and H2O–NaCl fluids (e.g., Newton and Manning 2000; Shmulovich et al. 2006).
For SiO2–H2O systems, the solubility of quartz in pure H2O increases with higher P and T (e.g., Anderson and Burnham 1965; Manning 1994), and this increase in the solubility is associated with the polymerization of aqueous silica monomers to form dimers or more polymerized species (e.g., Newton and Manning 2002, 2008; Zotov and Keppler 2002; Mysen 2010; Mysen et al. 2013). These experiments were conducted at near-neutral pH conditions, whereas the solubility behavior of quartz in high pH fluids could provide some insights into the nature of alkaline fluids in subducting lithologies such as crustal pelite (Galvez et al. 2015, 2016), crustal basalt (Galvez et al. 2016), and sediments (Connolly and Galvez 2018). The enhanced silica solubility in high pH fluids has been confirmed by early and recent studies on supercritical Na2CO3 or NaOH solutions (Friedman 1948; Anderson and Burnham 1967; Schmidt 2014; Aranovich et al. 2020). Aranovich et al. (2020) have systematically investigated quartz solubility in Na2CO3 and NaOH solutions at 500–700 °C and 0.4 and 0.5 GPa using an internally heated pressure vessel and a phase assemblage bracketing method. The results showed the quartz solubility systematically increased with greater salt concentrations, reaching 4.1 m [mol kg H2O–1] of silica in 3.5 m Na2CO3 and 2.4 m silica in 2.2 m NaOH. To describe the high solubility of quartz based on the equilibration between aqueous species, those authors considered the presence of deprotonated silica dimers [Si2O(OH)5O−], in addition to the known silica monomeric and oligomeric species [Si(OH)4, Si(OH)3O−, Si2O(OH)6, and Si3O2(OH)8] in the solutions. Till date, there is a Raman spectroscopic study on quartz + 1.6 m Na2CO3 solution up to 600 °C and 1.5 GPa by Schmidt (2014). The Raman spectra revealed the presence of neutral monomers Si(OH)4 and deprotonated monomers Si(OH)3O− in the solutions, but lacked evidence of silica oligomers in the spectral region of interest (> ~ 700 cm−1 for the observation of carbon species). On the other hand, a Raman spectroscopy study with SiO2–NaOH–H2O systems by Mysen (2018) showed the Q1-species band under high P–T conditions, but the presence of anionic silica species in the solution is still uncertain. Thus, the information available on the Raman observations is insufficient to understand silica solubility and speciation in Na2CO3 and NaOH solutions under high P–T conditions.
In the present study, we report the dissolved silica structures in quartz-saturated 0.50 and 1.50 m Na2CO3 and 0.47 m NaOH solutions up to 750 °C and 1.5 GPa by in-situ Raman spectroscopy in the silicate network vibration frequency range. In addition, we measured the solubility of quartz by in-situ observations of the complete dissolution of the quartz grain, which allowed for comparison with the Raman spectroscopy results. This information provides insights into silicate speciation and fluid–rock interactions for deep geological environments with the presence of alkaline hydrothermal fluids.
Experimental methods
Hydrothermal diamond anvil cell experiment
The experiments were performed using a Bassett-type hydrothermal diamond anvil cell (HDAC-V; Anderson et al. 2010). The cell utilized low-fluorescence-grade natural diamond anvils with a culet diameter of 800 μm. Gaskets with an initial thickness of 125 μm and an initial hole diameter of 400 μm, with pure water in the hole, were preheated to approximately 600–700 °C to avoid substantial deformation of the gasket at elevated P–T. An Ar + 2% H2 mixture was introduced into the gas chamber during the experiments to prevent oxidation of the molybdenum heating wires and anvils at high T. The temperature was measured using K-type thermocouples, with each junction close to the upper and lower anvils. The temperature of the sample chamber was calibrated by direct observation of the melting of Sn (231.9 °C) and NaCl (800.7 °C), and the disappearance of the Raman 355 cm−1 band from the α-quartz at the α–β transition (574 °C) at ambient pressure. The pressure was calculated from the Raman frequency shift of the ~ 464 cm−1 quartz peak (Schmidt and Ziemann 2000) at T < 560 °C, and the ~ 1008 cm−1 zircon peak at T > 560 °C (Schmidt et al. 2013). The positions of the Raman peaks were normalized to the simultaneously obtained neon emission lines. The estimated pressure uncertainties of the reproducibility and random error for the quartz and zircon sensors are approximately 25 and 50 MPa, respectively (Schmidt and Ziemann 2000; Schmidt et al. 2013). For one experiment with a quartz-undersaturated system, the pressure was approximated from the isochore corresponding to the liquid–vapor homogenization temperature obtained during heating, based on the equation of state (EoS) of H2O (Wagner and Pruβ 2002).
The present study included three series of experiments: (1) quartz + pure H2O, (2) quartz + 0.50 and 1.50 m Na2CO3, and (3) quartz + 0.47 m NaOH. Sodium carbonate and sodium hydroxide (FUJIFILM Wako Pure Chemical Co. Japan) and deionized distilled water were used to prepare the solutions. The NaOH concentration was titrated with oxalic acid solution. Natural quartz (Minas Gerais, Brazil) and natural zircon (Mud Tank, Australia) were used as the starting crystals and the pressure sensors. After loading the quartz and zircon, the sample chamber was filled with the applicable solution and promptly sealed (within several seconds) to avoid concentration changes due to evaporation. It should be noted that the volume of air bubbles in the sample chamber was not controlled by the evaporation process under ambient conditions. We measured the volume of the quartz pieces to determine the solubility under the P–T conditions in which quartz was completely dissolved (Fig. 1). The surface areas of doubly polished sections of quartz were calculated based on the optical microscopic images. As the quartz pieces were not perfectly rectangular parallelepipeds, because the polished section of the quartz were manually broken, as shown in Fig. 1a, e, the surface areas were segmented into transparent parts and rim parts with weak transparency, using the Trainable Weka Segmentation (TWS) plugin of the Fiji ImageJ software (Schindelin et al. 2012; Arganda-Carreras et al. 2017). These processes allowed us to calculate the lower and upper limits of the surface areas of the quartz piece, resulting in the solubility ranges shown in Table 1. To measure the quartz piece thickness, the other face of the fractured surface of each broken starting piece was imaged by tilting it at 20° or 25° in a field emission scanning electron microscope (FE-SEM; JEOL JSM-7001F). The fluid mass calculation was based on the method of Audétat and Keppler (2005), and the bubble volume was calculated using optical microscopic images obtained below liquid–vapor homogenization temperatures. The densities of the studied fluids at a given T and vapor-saturated P were calculated from the EoS of H2O (Wagner and Pruβ 2002) or a model with empirical coefficients for complex aqueous solutions (Laliberté 2009). We considered that the density of the Na2CO3 and NaOH solution is within the model value plus or minus twice the average standard deviation of the solution density residual (experimental–calculated density; 0.73 and 1.50 kg m−3 for Na2CO3 and NaOH solution, respectively; Laliberté 2009). This creates uncertainty in the lower and upper limits of the solubility values (Table 1). For the experiments with Na2CO3 and NaOH solution, we considered the air bubble volume during the sample loading to attain liquid–vapor homogenization at a temperature that does not significantly exceed ~ 100 and ~ 120 °C, as per the data used in Laliberté (2009). The solubility of quartz determined in the present study is shown in units of molality m (moles of solute per kg of H2O, not of aqueous salt solution).
The sample chamber was heated at 30–40 °C min−1. The Raman spectra of the fluids were acquired at 50 or 100 °C increments after holding the sample at each temperature for a few minutes. Before the quartz dissolution was completed, the heating rate was reduced to ~ 15 °C min−1. Previous time-dependent measurements indicated that quartz and H2O in a sample chamber with a similar hole size attained equilibrium within a few minutes at 600 °C (Zotov and Keppler 2002).
Raman spectroscopy
Raman analyses were performed using a HORIBA Jobin Yvon LabRAM 300 Laser Raman microspectrometer connected to a 1024 × 256-pixel charge-coupled device (CCD) detector. Unpolarized Raman spectra of the fluids were recorded using a 632.82 nm He–Ne laser with default power and with a confocal hole of 500 μm, a slit width of 100 μm, 1800 lines mm−1 grating, and 2 or 3 accumulations of 240 s in the single spectral window (159.9–1194.8 cm−1). The laser power measured at the sample surface with an Olympus SLMPLN 50 × objective lens (numerical aperture 0.35) was approximately 7 mW. The mechanical focus position was consistently at the culet surface of the upper diamond anvil. To compare the relative integrated intensities between the Raman spectra obtained under different P–T conditions, the spectra were corrected for the temperature factor of the Boltzmann distribution and the frequency and scattering factor (Brooker et al. 1988; Schmidt 2009). The spectra were further normalized by the density of the fluid and the factor for intensity decrease due to reflection at the diamond-fluid interface, according to the procedures described by Schmidt (2009) and Steele-MacInnis and Schmidt (2014). The density of supercritical H2O fluids (Zhang and Duan 2005) was used for the supercritical Na2CO3 and NaOH solutions because of the lack of the EoS for the solutions at high P–T conditions. The corrected spectra were baseline-corrected using linear or polynomial functions and fitted by the Gaussian–Lorentzian area function using the software package PeakFit v4.12 (HULINKS Inc.).
Results
Solubility of quartz
Figure 1 shows the gradual dissolution of quartz in pure H2O and 0.50 m [mol kg H2O−1] Na2CO3 solution along the experimental heating paths. A larger crystal was dissolved in the Na2CO3 solution than in pure H2O at similar P–T values. The dissolution etch pits were characteristically observed on the crystal surface (Fig. 1f, g).
Table 1 and Fig. 2 summarize the results of quartz solubility in pure H2O and Na2CO3 and NaOH solutions. In pure H2O at 718 °C and 728 °C, and 1.0 GPa, the quartz solubilities fell in the range of 0.62–0.82 and 0.72–0.95 m, respectively. Although there was considerable uncertainty in the estimated quartz volume, the measured solubilities agreed, within the errors, with the values calculated based on the Deep Earth Water (DEW) model (0.72 and 0.77 m, respectively; Sverjensky et al. 2014; Huang and Sverjensky 2019) that used the solubility and speciation data for aqueous silica from high pressure experiments for characterizing the HKF coefficients. This agreement confirms the validity of the crystal-volume measurements in the present study.
The quartz solubilities determined for 0.50 and 1.50 m Na2CO3 solutions at 558–730 °C and 0.8–1.5 GPa were greater than those for pure H2O at similar P–T conditions (Table 1). Even using the lowest estimation, the enhancing effect of the Na2CO3 on quartz solubility in aqueous fluids was confirmed. The quartz solubility increased at greater Na2CO3 concentrations, which is consistent with previous experimental data for up to approximately 4.7 m Na2CO3 solutions obtained at 300–450 °C and an unspecified P (Friedman 1948), and for 0.3–3.5 m Na2CO3 solutions obtained at 500–700 °C, and 0.4 and 0.5 GPa (Aranovich et al. 2020). The measured solubilities were generally similar to the values for 0.50 and 1.50 m Na2CO3 solution at 0.4 or 0.5 GPa calculated by linear interpolation of the Aranovich et al.’s (2020) data, except for the slightly higher results at 648 °C (1.3 GPa) and 730 °C (1.5 GPa) (Fig. 2). The quartz solubility in 0.47 m NaOH solution at 751 °C and 1.4 GPa overlapped within the errors with the value for 0.47 m NaOH solution at 0.4 GPa calculated by linear extrapolation of the Aranovich et al.’s (2020) data (Fig. 2).
Raman spectra and band assignments
Table 2 summarizes the results of Raman spectroscopic measurements. Figure 3 shows the unprocessed Raman spectra of the quartz-saturated and -undersaturated 1.50 m Na2CO3 solutions, and Fig. 4 presents those of the quartz-saturated 0.50 m Na2CO3 and 0.47 m NaOH solutions. The spectra, corrected for the frequency and temperature factors (Brooker et al. 1988; Schmidt 2009), were baseline-corrected by polynomial functions using the ~ 450–500 cm−1, ~ 730 cm−1, and ~ 900 or ~ 950 cm−1 regions as anchors. We did not include the higher frequency regions, in which the intensity increased due to the strong fluorescence of the diamond. In the spectra of the Na2CO3 solution, a simple linear baseline correction was applied to remove the background in the range of ~ 950–1150 cm−1 to obtain the relative intensities of the vibrational modes of the carbon species. Figure 5 shows the representative baseline-corrected Raman spectra fitted by the Gaussian–Lorentzian area function and the assignment of the vibrations of silicate species. In the following sections, we use the Qn terminology, which represents the tetrahedral silicate center connected to n bridging oxygen atoms.
The ~ 600 cm−1 band region
In the ~ 500–700 cm−1 region, we observed an intense broad band in the Raman spectra of quartz-saturated 0.50 and 1.50 m Na2CO3 solutions (Figs. 3a and 4a), as well as in the quartz-undersaturated 1.50 m Na2CO3 solution (Fig. 3b). The observation of this band in the NaOH solution (Fig. 4b) was consistent with that reported by Mysen (2018). The band was detected above ~ 300–400 °C in the Na2CO3 solution, ~ 500 °C in the NaOH solution, and ~ 600 °C in pure H2O. The band showed increased intensities and broadening to a lower frequency of ~ 500 cm−1 with increasing P and T. In some spectra, the band could be separated into at least two components, with a main band at ~ 600 cm−1 and a weaker band at ~ 650 cm−1 in the Na2CO3 solution (Fig. 5). Experimental and ab initio molecular dynamics studies have shown that the band near 600 cm−1 represents the vibrations of bridging oxygen Si–O–Si of weakly polymerized silica species such as dimers and trimers (e.g., Lasaga and Gibbs 1988; Zotov and Keppler 2000; Hunt et al. 2011; Spiekermann et al. 2012a, b). Spiekermann et al. (2012a) showed that the bridging oxygen symmetric stretching appeared as a major band at ~ 620 cm−1 and a shoulder band at ~ 680 cm−1 for dimers, and a major band at ~ 680 cm−1 for linear trimers. The ring trimer displays a band at ~ 500–600 cm−1 from the ring breathing mode, in addition to the prominent bridging oxygen band at ~ 600 cm−1 (Dutta and Shieh 1985; Hunt et al. 2011; Spiekermann et al. 2012b). These frequency ranges can cover the observed band in the 500–700 cm−1 region, which is interpreted as resulting from a dimer ± trimer formation. However, it may be challenging to assign the separated bands to individual oligomeric species, as the Si–O–Si vibrational frequencies may show a significant variability owing to the structural degree of freedom of the Si–O–Si bending angle (Kubicki and Sykes 1993; Hunt et al. 2011).
The ~ 770 cm−1 band region
The Raman spectra of quartz-saturated 0.50 and 1.50 m Na2CO3 and 0.47 m NaOH solutions showed prominent bands at ~ 770 cm−1 (Figs. 3a and 4). The intensities of the band increased with increasing P–T conditions in the quartz-saturated systems and were greater than those observed with pure H2O (Fig. 5). This band can be readily assigned to the tetrahedral symmetric Si–O stretching of monomeric silica species (Lasaga and Gibbs 1988; Zotov and Keppler 2000; Spiekermann et al. 2012a, b). Figure 6 shows the frequency and full width at half maximum (FWHM) of the band in the quartz-saturated H2O, Na2CO3, and NaOH solutions as a function of T (and P). The frequency in the Na2CO3 and NaOH solutions was lower than that in H2O at similar P–T conditions (Fig. 6a). The FWHM of the band in H2O increased with increasing P and T up to ~ 23 cm−1. In contrast, the FWHM in the Na2CO3 and NaOH solutions exhibited greater values than ~ 25 cm−1 with all experimental conditions (Fig. 6b). The overall trends were similar for the Na2CO3 and NaOH solutions. Hunt et al. (2011) showed that the frequency of the tetrahedral symmetric stretching of deprotonated monomers [Si(OH)3O−] and doubly deprotonated monomers [Si(OH)2O22−] shifted to the lower frequency regions. The second deprotonation requires extremely high pH (> 13) under ambient conditions (Bergna and Roberts 2005); therefore, the observed low frequency and broad FWHM features of the band can be an indication of deprotonated monomers in addition to the presence of neutral monomers [Si(OH)4]. Schmidt (2014) similarly assigned the two separated peaks of the broad band at ~ 770 cm−1 to the tetrahedral symmetric stretching of neutral and deprotonated monomers for quartz + 1.6 m Na2CO3 experiments up to 600 °C and 1.5 GPa. The present study indicated the prevalence of the deprotonated species in 0.50 and 1.50 m Na2CO3 and 0.47 m NaOH solutions equilibrated with quartz up to 750 °C and 1.5 GPa.
The ~ 800–900 cm−1 band regions
The Raman spectra of quartz-saturated 0.50 and 1.50 m Na2CO3 and 0.47 m NaOH solutions showed very weak band centered at ~ 830 cm−1 as a shoulder of the 770 cm−1 band (Figs. 3a and 4). This band can be attributed to the tetrahedral Si–O symmetric stretching of Q1 units, i.e., dimeric silicates or chain silicate species, and the asymmetric stretching of the ethane-like dimer Si2O(OH)6, which appeared at 793 cm−1 and 783 cm−1, respectively (Spiekermann et al. 2012a). The previous work by Schmidt (2014) did not separate the band at ~ 830 cm−1, possibly because of its low intensity.
In the Raman spectra of the quartz-saturated NaOH solution, the ~ 830 cm−1 band showed broadening to the frequency at ~ 950 cm−1 (Fig. 4b). The band at ~ 900 cm−1 was observed in the SiO2–H2O system (Zotov and Keppler 2002), but hardly detected in the 0.50 and 1.50 m Na2CO3 solutions, possibly because it overlapped with the stretching band of carbon species in the 1.50 m Na2CO3 solution. The ~ 900 cm−1 band has been assigned to Q2 units, i.e., the cyclic silicate or middle group in silicate chains, in several studies, but using only this explanation could cause overestimation of the degree of polymerization, because there are several potential species that could be responsible for this band. Spiekermann et al. (2012a) showed that the tetrahedral symmetric stretching of Q2 appears at 888 cm−1, coupled with 1081 cm−1. The presence of the broad band at ~ 950–1050 cm−1 in the NaOH solution is not likely to result only from the coupled features of Q2, because the bridging oxygen Si–O–Si asymmetric stretching of Qn or the Si–O− stretching of the deprotonated species appears in these regions, as described below. The ~ 900 cm−1 band may include a contribution from the symmetric stretching of the ethane-like dimer Si2O(OH)6, which shows a band at 870 cm−1 (Spiekermann et al. 2012a). In addition, the tetrahedral asymmetric stretching of Q0 and Q1 and the single non-bridging Si–OH stretching of various Qn units (n = 0–3) appear between 915 cm−1 and 936 cm−1 (Spiekermann et al. 2012a).
The ~ 1000 cm−1 band region
The Raman spectra of the quartz-saturated and -undersaturated 1.50 m Na2CO3 solutions showed prominent bands at ~ 1000 cm–1 and ~ 1060 cm−1 (Fig. 3). The ~ 1060 cm−1 bands in the quartz-saturated solution exhibited broader features than those of the quartz-undersaturated solution. These bands diminished to ~ 600–700 °C in the quartz-saturated 0.50 m Na2CO3 solution (Fig. 4a). These bands can be mainly assigned to the C–OH stretching of HCO3− and the C–O symmetric stretching of CO32−, respectively (Frantz 1998; Rudolph et al. 2008; Schmidt 2014). Figure 7 shows that the relative intensities of the ~ 1000 cm−1 band to the ~ 1060 cm−1 band (A1000/A1060) were higher in the quartz-saturated system than in the undersaturated system. At ~ 600 °C, the relative intensities in the quartz-saturated system remained constant or decreased. This is likely attributed to an intensity increase at ~ 1060 cm−1 owing to the contributions from the silicate species vibrations, as described below.
Broad, weak signals were detected in the high-frequency regions at ~ 950–1150 cm−1 in the quartz-saturated NaOH solution spectra (Fig. 4b). The ~ 1060 cm−1 region of the quartz-saturated 1.50 m Na2CO3 solution spectra also indicated the contribution from silicate species. The bands are likely attributed to the bridging oxygen Si–O–Si asymmetric stretching of Qn (n = 1–4) at ~ 1070 cm−1 (Spiekermann et al. 2012a), because of the presence of the bridging oxygen vibrations at ~ 600 cm−1. In addition, Spiekermann et al. (2012a) showed that the tetrahedral symmetric stretching of Q2 and Q3 units displays bands at 1081 cm−1 and 1103 cm−1, respectively. Moreover, the tetrahedral asymmetric stretching of Q2, Q3, and Q4 units exhibits bands centered at 970, 1015, and 1062 cm−1, respectively. However, we may exclude contributions from the vibrations of Q4 units, because those species were not detected in aqueous solutions of up to 40 mol% SiO2 concentrations in Na2O⋅2SiO2 (NS2)–H2O and Na2O⋅3SiO2 (NS3)–H2O systems at high P–T conditions (Steele-MacInnis and Schmidt 2014). Another possibility is a contribution from the Si–O− stretching of the deprotonated species centered at ~ 1050 cm−1 (Hunt et al. 2011). Although the high-frequency bands were not as prominent as those observed in highly alkaline silicate solutions at ambient T and up to 2.0 GPa (Dutta and Shieh 1985; Gout et al. 2000; Hunt et al. 2011), the bands may include contributions from the deprotonated species, because of the presence of the deprotonated monomer Si(OH)3O−.
Discussion
Comparisons with previous solubility data in Na2CO3 solutions
Aranovich et al. (2020) determined the quartz solubility in 0.2–3.5 m Na2CO3 solutions at conditions of 500, 600, and 700 °C and 0.4 GPa, and 600 °C and 0.5 GPa, using an internally heated pressure vessel and a phase assemblage bracketing method. Those authors showed a slight increase of quartz solubility in the Na2CO3 solutions with increasing P and T. Figure 2 shows that our measured solubilities in 0.50 m Na2CO3 solutions at 579 °C (0.92 GPa), 635 °C (0.84 GPa), and 695 °C (1.42 GPa), and 1.50 m Na2CO3 solutions at 558 °C (1.20 GPa) and 629 °C (1.41 GPa) overlapped, within errors, with the calculated values from the Aranovich et al. (2020) experiments at 0.4 and 0.5 GPa. This agreement indicates that the pressure dependence of the quartz solubility is negligible at these temperature and compositional ranges. In contrast, our measured solubilities in the 0.50 m Na2CO3 solution at 730 °C (1.52 GPa) and the 1.50 m Na2CO3 solution at 648 °C (1.31 GPa) were higher than the values extrapolated from the lower temperature results. This might suggest that the solubility of quartz becomes more dependent on temperature at higher P as P–T conditions approach the critical curve.
Schmidt (2014) reported the silica solubility in 1.6 m Na2CO3 solution at 600 °C and 1.5 GPa based on the in-situ Raman spectroscopic study to be ~ 1 m, which is approximately two times lower than our lowest estimation of the solubility in 1.50 m Na2CO3 at 629 °C and 1.41 GPa (2.22 ± 0.52 m). This discrepancy likely relates to the calculation used by Schmidt (2014) being based on the integrated intensities of the monomeric silica band. In the present study, the in-situ Raman spectroscopy in the frequency regions of silicate newly revealed the strong bridging oxygen band and the tetrahedral symmetric stretching band of the Q1 unit in the quartz-saturated 1.50 m Na2CO3 solution spectra (Figs. 3 and 5), indicating the presence of silica oligomers in the solution. Therefore, basing the total silica solubility calculation solely on the integrated intensities of the monomeric silica band could lead to underestimation in this system. The present study shows the effect of the alkaline Na2CO3 solution on enhancing silica solubility at high P conditions becomes clearer.
Comparison with thermodynamic modeling
We compared the measured quartz solubilities in 0.50 and 1.50 m Na2CO3 with thermodynamically predicted solubilities at similar P and T conditions based on the equilibration between aqueous silica species, using an equilibrium constant database for aqueous species from the DEW model (Sverjensky et al. 2014; Huang and Sverjensky 2019) and the EQ3NR code (Wolery 1992). In this calculation, we assumed that the oxygen fugacity was near the fayalite–magnetite–quartz (FMQ) buffer, because Schmidt (2014) reported no CH4 formation in Na2CO3 solutions in equilibrium with quartz using an experimental setup similar to ours. We also confirmed that the calculated solubilities were not significantly changed by carbon speciation under more oxidized conditions than that of the FMQ buffer. It should be noted that carbon species were predicted to be mainly electrically neutral under these conditions, which is not consistent with the observed Raman band. In Fig. 2, we showed the thermodynamically predicted silica solubility curves in 0.5 and 1.5 m Na2CO3 solutions at 1.0 and 1.5 GPa, where the aqueous silica species were Si(OH)4, Si(OH)3O−, Si2O(OH)6, and Si3O2(OH)8. These curves were lower than our lowest estimation of quartz solubility. Aranovich et al. (2020) also reported that the quartz solubility in Na2CO3 solutions based only on the above species underestimated the values at lower pressure ranges (0.4 and 0.5 GPa). Our solubility data, together with those of Aranovich et al. (2020), indicated that the available speciation modeling was insufficient to explain the high quartz solubilities and aqueous speciation in the Na2CO3 solution at high P–T conditions.
High quartz solubility associated with the formation of oligomers
The solubility of silica in aqueous solutions rapidly increases at levels of pH > 9 under ambient conditions (Iler 1979). The studied Na2CO3 and NaOH solutions were alkaline, involving the hydrolysis reaction of aqueous carbonate species (CO32− + H2O = HCO3− + OH−) or the dissociation of NaOH (NaOH = Na+ + OH−). The present study showed the favorable formation of HCO3− in Na2CO3 solutions in the quartz-saturated condition compared to the quartz-undersaturated condition (Fig. 7), which can readily be explained by the consumption of OH− through the reaction with quartz. Schmidt (2014) demonstrated that the formation of the deprotonated silica monomers in the solutions (SiO2(s) + H2O + OH− = SiO(OH)3−) reflected the higher quartz solubility in Na2CO3 solutions than that in pure H2O. Our Raman spectroscopic studies confirmed the higher intensities of the monomer bands in the Na2CO3 and NaOH solutions than those in pure H2O (Fig. 5), with the presence of deprotonated monomers up to our highest experimental conditions of 750 °C and 1.5 GPa. Together with the results of Schmidt (2014), we have verified that the formation of deprotonated monomers contributed to the high quartz solubility in the Na2CO3 solutions.
Furthermore, the present study newly observed the bridging oxygen band in the Raman spectra of the Na2CO3 solutions, which indicates the formation of silica oligomers (Figs. 3, 4, and 5). In particular, the Raman band regions of the tetrahedral symmetric Si–O stretching of structural Qn units indicate that at least dimeric silicates or chain silicate species, including Q1 units, are present in the solutions (Fig. 5). To quantify the relative concentrations of species in aqueous solutions and melts, the previous studies considered the ratios of the tetrahedral symmetric stretching band of Qn species, which are assumed to have the same Raman scattering cross-sectional area (e.g., Mysen 2010; Mysen et al. 2013; Steele-MacInnis and Schmidt 2014). However, the intensities of the detected tetrahedral symmetric stretching bands of Q1 units in our Na2CO3 and NaOH solutions were too low to detect differences in the Q1/Q0 ratios between the solutions. Instead, we used the ratio of the intense bridging oxygen Si–O–Si symmetric stretching band to the tetrahedral symmetric stretching band of Q0 (A600/A770) in a similar manner to Hunt et al. (2011). Comparison of the A600/A770 obtained under different P–T conditions requires the assumption that the ratios of the relative Raman scattering cross-sectional factors are independent of P and T. Steele-MacInnis and Schmidt (2014) reported no detectable change in the silicate band intensities with increasing P at constant T and SiO2 concentrations. Thus, we compared the ratios among spectra of different solutions under similar T conditions. Figure 8a shows the integrated intensity ratios, A600/A770, in the quartz-saturated Na2CO3, NaOH, and H2O solutions at P = 0.8–1.5 GPa as a function of T. The ratios generally increased in the following order: H2O < 0.47 m NaOH < 0.50 m Na2CO3 < 1.50 m Na2CO3. In addtion, the increase in the ratios corresponded to the elevation of silica solubility determined by the in-situ observations of the complete dissolution of quartz (Fig. 8b). If the ratios were simply proportional to the concentration ratios of oligomeric species to monomers, the increase in silica oligomers in the solutions would account for the observed high quartz solubilities in the Na2CO3 and NaOH solutions. The ratios could also be increased by the formation of silica oligomers with different Raman scattering cross-sectional factors with increasing silica concentration. Therefore, the observed high solubility of quartz in the Na2CO3 and NaOH solutions is assumed to have resulted from the formation of silica oligomers in addition to the neutral and deprotonated monomers.
Silica speciation in alkaline high P–T solutions
Based on our solubility data and Raman observations, the oligomeric silica species contribute to the high quartz solubility in alkaline Na2CO3 and NaOH solutions under high P–T conditions. In particular, the Raman band regions of the tetrahedral symmetric Si–O stretching of structural units Qn indicate that at least dimeric silicates or chain silicate species, including Q1 units, are present in the solutions. This suggests that the deprotonated dimer, Si2O(OH)5O−, could be present in quartz-saturated alkaline solutions at high P–T conditions, as proposed by Aranovich et al. (2020). However, we could not infer the presence of the deprotonated dimers from the Si–O− stretching Raman band, which appears at ~ 1050 cm−1 in the alkaline silicate solutions under ambient conditions and up to 2 GPa (e.g., Hunt et al. 2011). On the other hand, our experiments confirmed the presence of deprotonated monomers in the quartz-saturated Na2CO3 and NaOH solutions under all experimental conditions. As the deprotonation of silica dimers and trimers lowers the Gibbs free energy more efficiently than that of the silica monomers in aqueous solutions at room temperature to 450 K (Tossell and Sahai 2000; Mora-Fonz et al. 2007), the deprotonated oligomers could be favorably present in the solutions even at elevated P–T conditions. Other possible stable silica oligomers are ion pairs between sodium cations and deprotonated silica oligomers or sodium–silicate complexes, as observed in alkali–silicate solutions under ambient conditions by NMR spectroscopy (Kinrade and Swaddle 1986; McCormick et al. 1989) and fast atom bombardment mass spectroscopy (FAB-MS; Tanaka and Takahashi 1999). Manning et al. (2010) and Wohlers et al. (2011) demonstrated the presence of polymerized Na–Al–Si complexes in aqueous fluids in equilibrium with albite + paragonite + quartz or jadeite + paragonite + quartz at 350–600 °C and 1–2.25 GPa. Although evidence for oligomers involving alkali metals was not directly inferred from the in-situ Raman spectroscopic studies, the effect of alkali metal cations on aqueous silicate equilibria is indicated by the differences in the Raman spectra and integrated intensity ratios between the quartz-saturated 0.50 m Na2CO3 and 0.47 m NaOH solutions. The equilibria involving such oligomers at elevated P–T conditions will accurately describe silicate solubility in alkaline fluids.
Implications for element transfer in deep subduction zones
The present study suggests that alkaline fluids can dissolve a significant amount of silica compared to pure H2O at elevated P–T conditions, which is explained by the formation of neutral and deprotonated monomers and the subsequent formation of oligomers. The presence of deprotonated monomers under all experimental conditions suggested the presence of deprotonated and other possible oligomers such as ion pairs between sodium cations and anionic deprotonated silica oligomers. The presence of anionic silica species in alkaline fluids enhances the attractive electrostatic force between opposite ions, which acts as an effective ligand for certain metal ions or complexes. For example, the interaction energies of gold complexes with silica species depend on the pH conditions (Mohammadnejad et al. 2017). Additional examples are Zr and Ti, which are representatives of nominally insoluble high field strength elements. Only SiO2 components in aqueous fluids did not significantly enhance the solubility of Ti and Zr (Antignano and Manning 2008; Bernini et al. 2013), while the addition of NS2 or NS3 glass or albite components to pure H2O enhanced the solubility of Ti and Zr by producing alkaline silicate-rich fluids similar to our experimental system (Antignano and Manning 2008; Manning et al. 2008; Wilke et al. 2012; Louvel et al. 2013). Based on X-ray absorption spectroscopy, Louvel et al. (2013) found that Zr dissolved by forming alkali–zirconosilicate clusters via octahedral coordination with oxygen and Si(Na) second neighbors. The anionic silica species and subsequently formed silica oligomers in alkaline fluids are thus assumed to affect the solubility of these metals by forming complexes.
Conclusions
-
1.
The solubilities of quartz in 0.50 and 1.50 m Na2CO3 solutions at 558–730 °C and 0.84–1.52 GPa indicated the enhancing effect of Na2CO3 on quartz solubility at elevated P–T conditions. The present study, together with Aranovich et al. (2020), showed that the conventional aqueous silica species [Si(OH)4, Si(OH)3O−, Si2O(OH)6, and Si3O2(OH)8] alone were insufficient to describe the observed high solubility.
-
2.
The Raman spectra of the quartz-saturated Na2CO3 and NaOH solutions exhibited tetrahedral symmetric stretching bands under the experimental conditions. The low frequency and broad FWHM of the bands were interpreted to be due to the deprotonated monomer Si(OH)3O− in addition to the neutral monomer Si(OH)4.
-
3.
We newly confirmed the intense bridging oxygen band and the tetrahedral symmetric stretching band of Q1 units, suggesting the formation of silica oligomers in the solutions. The integrated intensity ratios of the bridging oxygen band area to the monomer band area increased in the following order: H2O < 0.47 m NaOH < 0.50 m Na2CO3 < 1.50 m Na2CO3. The increase in the ratios corresponded to the elevation of quartz solubilities, suggesting that oligomers contributed to the high solubility.
-
4.
Considering the presence of deprotonated monomers under all experimental conditions, we assumed that energetically favorable oligomer deprotonation occurred in the solutions. Sodium–silicate complexes or ion pairs between sodium cations and deprotonated silica oligomers were also possible, although these were not confirmed by in-situ Raman spectroscopic studies. The anionic silica species or oligomers formed in alkaline silicate fluids may act as effective ligands for certain metal ions or complexes in deep subduction zones.
Availability of data and materials
The dataset analyzed during this study is available from the corresponding author upon reasonable request.
References
Anderson GM, Burnham CW (1965) The solubility of quartz in super-critical water. Am J Sci 263:494–511. https://doi.org/10.2475/ajs.263.6.494
Anderson GM, Burnham CW (1967) Reactions of quartz and corundum with aqueous chloride and hydroxide solutions at high temperatures and pressures. Am J Sci 265:12–27. https://doi.org/10.2475/ajs.265.1.12
Anderson AJ, Meredith PR, Bassett WA, Mayanovic RA, Benmore C (2010) The design and application of a new Bassett-type diamond anvil cell for spectroscopic analysis of supercritical aqueous solutions. In: Proceedings of the CNS 2nd Canada–China joint workshop on super critical water-cooled reactors (SCWR)
Antignano A, Manning CE (2008) Rutile solubility in H2O, H2O−SiO2, and H2O−NaAlSi3O8 fluids at 0.7–2.0 GPa and 700–1000 °C: implications for mobility of nominally insoluble elements. Chem Geol 255:283–293. https://doi.org/10.1016/j.chemgeo.2008.07.001
Aranovich L, Akinfiev NN, Golunova M (2020) Quartz solubility in sodium carbonate solutions at high pressure and temperature. Chem Geol. https://doi.org/10.1016/j.chemgeo.2020.119699
Arganda-Carreras I, Kaynig V, Rueden C et al (2017) Trainable Weka Segmentation: a machine learning tool for microscopy pixel classification. Bioinformatics 33:2424–2426. https://doi.org/10.1093/bioinformatics/btx180
Audet P, Bürgmann R (2014) Possible control of subduction zone slow-earthquake periodicity by silica enrichment. Nature 510:389–392. https://doi.org/10.1038/nature13391
Audétat A, Keppler H (2005) Solubility of rutile in subduction zone fluids, as determined by experiments in the hydrothermal diamond anvil cell. Earth Planet Sci Lett 232:393–402. https://doi.org/10.1016/j.epsl.2005.01.028
Bebout GE, Barton MD (1989) Fluid flow and metasomatism in a subduction zone hydrothermal system: Catalina Schist terrane, California. Geology 17:976–980. https://doi.org/10.1130/0091-7613(1989)017%3c0976:FFAMIA%3e2.3.CO;2
Bergna HE, Roberts WO (2005) Colloidal silica: fundamentals and applications. CRC Press, Boca Raton
Bernini D, Audétat A, Dolejš D, Keppler H (2013) Zircon solubility in aqueous fluids at high temperatures and pressures. Geochim Cosmochim Acta 119:178–187. https://doi.org/10.1016/j.gca.2013.05.018
Breeding CM, Ague JJ (2002) Slab-derived fluids and quartz-vein formation in an accretionary prism, Otago Schist, New Zealand. Geology 30:499–502. https://doi.org/10.1130/0091-7613(2002)030%3c0499:SDFAQV%3e2.0.CO;2
Brooker MH, Nielsen OF, Praestgaard E (1988) Assessment of correction procedures for reduction of Raman spectra. J Raman Spectrosc 19:71–78. https://doi.org/10.1002/jrs.1250190202
Connolly JAD, Galvez ME (2018) Electrolytic fluid speciation by Gibbs energy minimization and implications for subduction zone mass transfer. Earth Planet Sci Lett 501:90–102. https://doi.org/10.1016/j.epsl.2018.08.024
Dutta PK, Shieh DC (1985) Raman spectral study of the composition of basic silicate solutions. Appl Spectrosc 39:343–346. https://doi.org/10.1366/0003702854248971
Frantz JD (1998) Raman spectra of potassium carbonate and bicarbonate aqueous fluids at elevated temperatures and pressures: comparison with theoretical simulations. Chem Geol 152:211–225. https://doi.org/10.1016/S0009-2541(98)00058-8
Friedman II (1948) The solubility of quartz in sodium carbonate solutions at high temperature. J Am Chem Soc 70:2649–2650. https://doi.org/10.1021/ja01188a010
Galvez ME, Manning CE, Connolly JAD, Rumble D (2015) The solubility of rocks in metamorphic fluids: a model for rock-dominated conditions to upper mantle pressure and temperature. Earth Planet Sci Lett 430:486–498. https://doi.org/10.1016/j.epsl.2015.06.019
Galvez ME, Connolly JAD, Manning CE (2016) Implications for metal and volatile cycles from the pH of subduction zone fluids. Nature 539:420–424. https://doi.org/10.1038/nature20103
Gout R, Pokrovski GS, Schott J, Zwick A (2000) Raman spectroscopic study of aluminum silicate complexes at 20 °C in basic solutions. J Solut Chem 29:1173–1186. https://doi.org/10.1023/A:1026428027101
Huang F, Sverjensky DA (2019) Extended Deep Earth Water Model for predicting major element mantle metasomatism. Geochim Cosmochim Acta 254:192–230. https://doi.org/10.1016/j.gca.2019.03.027
Hunt JD, Kavner A, Schauble EA, Snyder D, Manning CE (2011) Polymerization of aqueous silica in H2O–K2O solutions at 25–200 °C and 1 bar to 20 kbar. Chem Geol 283:161–170. https://doi.org/10.1016/j.chemgeo.2010.12.022
Hyndman RD, McCrory PA, Wech A, Kao H, Ague JJ (2015) Cascadia subducting plate fluids channelled to fore-arc mantle corner: ETS and silica deposition. J Geophys Res Solid Earth 120:4344–4358. https://doi.org/10.1002/2015JB011920
Iler RK (1979) The chemistry of silica: solubility, polymerization, colloid and surface properties, and biochemistry of silica. Wiley-Interscience, New York
Kinrade SD, Swaddle TW (1986) Mechanisms of longitudinal 29Si nuclear magnetic relaxation in aqueous alkali-metal silicate solutions. J Am Chem Soc 108:7159–7162. https://doi.org/10.1021/ja00283a004
Kubicki JD, Sykes D (1993) Molecular orbital calculations on H6Si2O7 with a variable Si–O–Si angle: implications for the high-pressure vibrational spectra of silicate glasses. Am Mineral 78:253–259
Laliberté M (2009) A model for calculating the heat capacity of aqueous solutions, with updated density and viscosity data. J Chem Eng Data 54:1725–1760. https://doi.org/10.1021/je8008123
Lasaga AC, Gibbs GV (1988) Quantum mechanical potential surfaces and calculations on minerals and molecular clusters. Phys Chem Miner 16:29–41. https://doi.org/10.1007/BF00201327
Louvel M, Sanchez-Valle C, Malfait WJ, Testemale D, Hazemann J-L (2013) Zr complexation in high pressure fluids and silicate melts and implications for the mobilization of HFSE in subduction zones. Geochim Cosmochim Acta 104:281–299. https://doi.org/10.1016/j.gca.2012.11.001
Manning CE (1994) The solubility of quartz in H2O in the lower crust and upper mantle. Geochim Cosmochim Acta 58:4831–4839. https://doi.org/10.1016/0016-7037(94)90214-3
Manning CE, Wilke M, Schmidt C, Cauzid J (2008) Rutile solubility in albite–H2O and Na2Si3O7–H2O at high temperatures and pressures by in-situ synchrotron radiation micro-XRF. Earth Planet Sci Lett 272:730–737. https://doi.org/10.1016/j.epsl.2008.06.004
Manning CE, Antignano A, Lin HA (2010) Premelting polymerization of crustal and mantle fluids, as indicated by the solubility of albite + paragonite + quartz in H2O at 1 GPa and 350–620 °C. Earth Planet Sci Lett 292:325–336. https://doi.org/10.1016/j.epsl.2010.01.044
McCormick AV, Bell AT, Radke CJ (1989) Evidence from alkali-metal NMR spectroscopy for ion pairing in alkaline silicate solutions. J Phys Chem 93:1733–1737. https://doi.org/10.1021/j100342a013
Mohammadnejad S, Provis JL, van Deventer JSJ (2017) Computational modelling of interactions between gold complexes and silicates. Comput Theor Chem 1101:113–121. https://doi.org/10.1016/j.comptc.2016.12.036
Mora-Fonz MJ, Catlow CRA, Lewis DW (2007) Modeling aqueous silica chemistry in alkali media. J Phys Chem C 111:18155–18158. https://doi.org/10.1021/jp077153u
Mysen BO (2010) Speciation and mixing behavior of silica-saturated aqueous fluid at high temperature and pressure. Am Mineral 95:1807–1816. https://doi.org/10.2138/am.2010.3539
Mysen BO (2018) Silicate solution, cation properties, and mass transfer by aqueous fluid in the Earth’s interior. Prog Earth Planet Sci 5:40. https://doi.org/10.1186/s40645-018-0198-1
Mysen BO, Mibe K, Chou I-M, Bassett WA (2013) Structure and equilibria among silicate species in aqueous fluids in the upper mantle: experimental SiO2-H2O and MgO-SiO2-H2O data recorded in situ to 900 °C and 5.4 GPa. J Geophys Res Solid Earth 118:6076–6085. https://doi.org/10.1002/2013JB010537
Newton RC, Manning CE (2000) Quartz solubility in H2O-NaCl and H2O-CO2 solutions at deep crust-upper mantle pressures and temperatures: 2–15 kbar and 500–900 °C. Geochim Cosmochim Acta 64:2993–3005. https://doi.org/10.1016/S0016-7037(00)00402-6
Newton RC, Manning CE (2002) Solubility of enstatite + forsterite in H2O at deep crust/upper mantle conditions: 4 to 15 kbar and 700 to 900 °C. Geochim Cosmochim Acta 66:4165–4176. https://doi.org/10.1016/S0016-7037(02)00998-5
Newton RC, Manning CE (2008) Thermodynamics of SiO2–H2O fluid near the upper critical end point from quartz solubility measurements at 10 kbar. Earth Planet Sci Lett 274:241–249. https://doi.org/10.1016/j.epsl.2008.07.028
Rudolph WW, Irmer G, Königsberger E (2008) Speciation studies in aqueous HCO3−–CO32− solutions. A combined Raman spectroscopic and thermodynamic study. Dalton Trans 7:900–908. https://doi.org/10.1039/B713254A
Schindelin J, Arganda-Carreras I, Frise E et al (2012) Fiji: an open-source platform for biological-image analysis. Nat Methods 9:676–682. https://doi.org/10.1038/nmeth.2019
Schmidt C (2009) Raman spectroscopic study of a H2O + Na2SO4 solution at 21–600 °C and 0.1 MPa to 1.1 GPa: relative differential ν1-SO42− Raman scattering cross sections and evidence of the liquid–liquid transition. Geochim Cosmochim Acta 73:425–437. https://doi.org/10.1016/j.gca.2008.10.019
Schmidt C (2014) Raman spectroscopic determination of carbon speciation and quartz solubility in H2O + Na2CO3 and H2O + NaHCO3 fluids to 600 °C and 1.53 GPa. Geochim Cosmochim Acta 145:281–296. https://doi.org/10.1016/j.gca.2014.09.009
Schmidt C, Ziemann MA (2000) In-situ Raman spectroscopy of quartz: a pressure sensor for hydrothermal diamond-anvil cell experiments at elevated temperatures. Am Mineral 85:1725–1734. https://doi.org/10.2138/am-2000-11-1216
Schmidt C, Steele-MacInnis M, Watenphul A, Wilke M (2013) Calibration of zircon as a Raman spectroscopic pressure sensor to high temperatures and application to water–silicate melt systems. Am Mineral 98:643–650. https://doi.org/10.2138/am.2013.4143
Shmulovich KI, Graham CM, Yardley BWD (2001) Quartz, albite and diopside solubilities in H2O−NaCl and H2O−CO2 fluids at 0.5–0.9 GPa. Contrib Mineral Petrol 141:95–108. https://doi.org/10.1007/s004100000224
Shmulovich KI, Yardley BWD, Graham CM (2006) Solubility of quartz in crustal fluids: experiments and general equations for salt solutions and H2O−CO2 mixtures at 400–800 °C and 0.1–0.9 GPa. Geofluids 6:154–167. https://doi.org/10.1111/j.1468-8123.2006.00140.x
Spiekermann G, Steele-MacInnis M, Kowalski PM, Schmidt C, Jahn S (2012a) Vibrational mode frequencies of H4SiO4, D4SiO4, H6Si2O7, and H6Si3O9 in aqueous environment, obtained from ab initio molecular dynamics. J Chem Phys 137:164506. https://doi.org/10.1063/1.4761824
Spiekermann G, Steele-MacInnis M, Schmidt C, Jahn S (2012b) Vibrational mode frequencies of silica species in SiO2-H2O liquids and glasses from ab initio molecular dynamics. J Chem Phys 136:154501. https://doi.org/10.1063/1.3703667
Steele-MacInnis M, Schmidt C (2014) Silicate speciation in H2O−Na2O−SiO2 fluids from 3 to 40 mol% SiO2, to 600 °C and 2 GPa. Geochim Cosmochim Acta 136:126–141. https://doi.org/10.1016/j.gca.2014.04.009
Sverjensky DA, Harrison B, Azzolini D (2014) Water in the deep Earth: the dielectric constant and the solubilities of quartz and corundum to 60 kb and 1200 °C. Geochim Cosmochim Acta 129:125–145. https://doi.org/10.1016/j.gca.2013.12.019
Tanaka M, Takahashi K (1999) The identification of chemical species of silica in sodium hydroxide, potassium hydroxide and sodium chloride solutions by FAB-MS. Anal Sci 15:1241–1250. https://doi.org/10.2116/analsci.15.1241
Tossell JA, Sahai N (2000) Calculating the acidity of silanols and related oxyacids in aqueous solution. Geochim Cosmochim Acta 64:4097–4113. https://doi.org/10.1016/S0016-7037(00)00497-X
Wagner W, Pruβ A (2002) The IAPWS formulation 1995 for the thermodynamic properties of ordinary water substance for general and scientific use. J Phys Chem Ref Data 31:387–535. https://doi.org/10.1063/1.1461829
Wilke M, Schmidt C, Dubrail J et al (2012) Zircon solubility and zirconium complexation in H2O + Na2O + SiO2 ± Al2O3 fluids at high pressure and temperature. Earth Planet Sci Lett 349–350:15–25. https://doi.org/10.1016/j.epsl.2012.06.054
Wohlers A, Manning CE, Thompson AB (2011) Experimental investigation of the solubility of albite and jadeite in H2O, with paragonite+quartz at 500 and 600 °C, and 1–2.25 GPa. Geochim Cosmochim Acta 75:2924–2939. https://doi.org/10.1016/j.gca.2011.02.028
Wolery TJ (1992) EQ3NR, A computer program for geochemical aqueous speciation-solubility calculations: Theoretical manual, user’s guide, and related documenta-tion (Version 7.0). Lawrence Livermore Natl. Lab. UCRL-MA-110662, pt III
Yardley BWD, Bottrell SH (1992) Silica mobility and fluid movement during metamorphism of the Connemara schists, Ireland. J Metamorph Geol 10:453–464. https://doi.org/10.1111/j.1525-1314.1992.tb00096.x
Zhang Z, Duan Z (2005) Prediction of the PVT properties of water over wide range of temperatures and pressures from molecular dynamics simulation. Phys Earth Planet Inter 149:335–354. https://doi.org/10.1016/j.pepi.2004.11.003
Zotov N, Keppler H (2000) In-situ Raman spectra of dissolved silica species in aqueous fluids to 900 °C and 14 kbar. Am Mineral 85:600–604. https://doi.org/10.2138/am-2000-0423
Zotov N, Keppler H (2002) Silica speciation in aqueous fluids at high pressures and high temperatures. Chem Geol 184:71–82. https://doi.org/10.1016/S0009-2541(01)00353-9
Acknowledgements
We are grateful for constructive reviews from two anonymous referees and constructive editorial evaluations from Hans Keppler. We also appreciate Hans Keppler for the advice on the pressure scale for the hydrothermal diamond anvil cell experiments; Hironobu Harada for his support of the titration analysis. In addition, N.T. and T.T. thank Yoshihide Ogasawara for donating a micro-Raman facility to CNEAS.
Funding
This research was supported by the Graduate School of Science and Center for Northeast Asian Studies, Tohoku University, in part by grants from the MEXT/JSPS KAKENHI JP19J21319 to N. Takahashi, JP18H01299 and JP21H01174 to T. Tsujimori, JSPS Japanese–German Graduate Externship, and the International Joint Graduate Program in Earth and Environmental Sciences (GP-EES) of Tohoku University.
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N.T. devised the project, conducted the experiments, analyzed and interpreted the experimental data, and drafted the manuscript. T.T. and M.N. supervised the project, interpreted the experimental data, and contributed to the writing of the manuscript. S.K. provided basic DAC methods and aided in conducting preliminary experiments. All authors read and approved the final manuscript.
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Takahashi, N., Tsujimori, T., Kamada, S. et al. In-situ Raman spectroscopic analysis of dissolved silica structures in Na2CO3 and NaOH solutions at high pressure and temperature. Contrib Mineral Petrol 177, 36 (2022). https://doi.org/10.1007/s00410-022-01892-y
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DOI: https://doi.org/10.1007/s00410-022-01892-y