Abstract
Supersaturation of H2O during magma ascent leads to degassing of melt by formation and growth of vesicles that may power explosive volcanic eruptions. Here, we present experiments to study the effect of initially dissolved H2O concentration (cH2Oini) on vesicle formation, growth, and coalescence in phonolitic melt. Vesuvius phonolitic melts with cH2Oini ranging between 3.3 and 6.3 wt% were decompressed at rates of 1.7 and 0.17 MPa·s−1 and at temperatures ≥ 1323 K. Decompression started from 270 and 200 MPa to final pressures of 150–20 MPa, where samples were quenched isobarically. Optical microscopy and Raman spectroscopic measurements confirm that the glasses obtained were free of microcrystals and Fe-oxide nanolites, implying that the experiments were superliquidus and phase separation of the hydrous melt was homogeneous. A minimum number of the initially formed vesicles, defined by the number density normalized to vesicle-free glass volume (VND), is observed at ~ 5 wt% cH2Oini with a logVND of ~ 5 (in mm−3). The logVND increases strongly towards lower and higher cH2Oini by one order of magnitude. Furthermore, an important transition in evolution of vesiculation occurs at ~ 5.6 wt% cH2Oini. At lower cH2Oini, the initial VND is preserved during further decompression up to melt porosities of 30–50%. At higher cH2Oini, the initial vesicle population is erased at low melt porosities of 15–21% during further decompression. This observation is attributed to vesicle coalescence favored by low melt viscosity. In conclusion, cH2Oini determines the VND of initial phase separation and the evolution of vesiculation during decompression that controls the style of volcanic eruptions.
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Introduction
Explosive volcanic activity is powered by rapid melt degassing of mainly H2O, prior to and during fragmentation (e.g., Alidibirov and Dingwell 1996; Gonnermann and Manga 2007). Supersaturation of hydrous silicate melt induced e.g., by decompression drives vesicle formation and growth (e.g., Sparks 1978; Hurwitz and Navon 1994; Mourtada-Bonnefoi and Laporte 2004; Iacono-Marziano et al. 2007; Hamada et al. 2010; Gardner and Ketcham 2011; Preuss et al. 2016; Shea 2017; Hajimirza et al. 2019). The number of vesicles per unit volume of melt (VND), and thus the inter-vesicle distance, defines the degassing efficiency (e.g., Toramaru 2006; Allabar and Nowak 2018). The coupled magma density decrease amplifies ascent, volatile expansion, and fragmentation, and powers explosive volcanic eruptions (e.g., Kueppers et al. 2006; Genareau et al. 2012).
According to nucleation theory, which describes phase separation in the thermodynamically metastable state, the VND increases strongly with the decompression rate dP/dt (e.g., Hurwitz and Navon 1994; Toramaru 2006). In contrast to this dependence, a decompression rate independent VND was reported by Allabar and Nowak (2018) for hydrous phonolitic melt with white pumice composition of the Vesuvius 79AD eruption (VAD79). This composition is representative for other natural phonolitic and trachytic volcanic systems like the Campi Flegrei or Tambora that are known for violent explosive eruptions (e.g., Mastrolorenzo et al. 2001; Foden 1986). The observed independence of VND on decompression rate in the investigated range of 0.024–10 MPa·s−1 is inconsistent with the theory of vesicle nucleation as phase separation mechanism. Alternatively, phase separation may be described by the theory of spinodal decomposition in the thermodynamically unstable state, for which the VND is expected to be independent from decompression rate (Allabar and Nowak 2018). Their experimentally observed logVNDs (in mm−3) of ~ 5.2 at initial H2O concentration (cH2Oini) of ~ 5.3 wt% match the lower end of the range of logVND of 5.15–7.08 recorded in natural VAD79 pumice (Gurioli et al. 2005; Shea et al. 2010a). However, natural eruptive products of the different stages of the AD79 Vesuvius eruption have been reported to originate from melts with cH2Oini ranging between 3.0 and 6.4 wt% (Cioni 2000). So far, degassing of superliquidus phonolitic melt by homogeneous phase separation has been investigated as a function of decompression rate (Iacono-Marziano et al. 2007; Marxer et al. 2015; Preuss et al. 2016; Allabar and Nowak 2018) and slight variations in decompression temperature (1323–1373 K; Allabar and Nowak 2018). A systematic investigation of the effect of cH2Oini on homogeneous phase separation of phonolitic melt during decompression is lacking. Dissolved H2O significantly influences physicochemical parameters of silicate melt such as viscosity (e.g., Giordano et al. 2008), H2O diffusivity (e.g., Nowak and Behrens 1997; Fanara et al. 2013), and surface tension (e.g., Bagdassarov et al. 2000). It is thus expected that cH2Oini of silicate melt controls homogeneous phase separation by vesicle formation and the evolution of vesiculation during decompression. Therefore, experimental data of decompressed hydrous phonolitic VAD79 melt are compiled that fulfill the experimental protocol of Preuss et al. (2016) ensuring homogeneous phase separation (Iacono-Marziano 2007; Marxer et al. 2015; Preuss et al. 2016; Allabar and Nowak 2018). These data are extended by additional decompression experiments at temperatures (T) between 1323 and 1523 K using VAD79 melt with varying cH2Oini ranging between 3.3 and 6.3 wt% and a dP/dt of 0.17 MPa·s−1.
Experimental methods
Starting material
Crystal-free homogeneous starting glasses of the VAD79 white pumice composition (Iacono-Marziano et al. 2007) were synthesized following the procedure of Marxer et al. (2015) in combination with the cooling optimization described by Allabar and Nowak (2018). Analytical-grade oxide (SiO2-glass, TiO2, Al2O3, FeO, MgO, MnO) and carbonate (CaCO3, Na2CO3, K2CO3) powders as well as (NH4)2HPO4 as phosphorous source were used as raw materials for glass synthesis. To obtain accurate weight portions, the strongly hygroscopic SiO2, Al2O3, and MgO powders were dried at 1073 K for 18 h, and the carbonate powders were dried at 383 K for 24 h and, subsequently, cooled and stored in a desiccator. The dried powders were weighed to obtain 50 g of glass for each batch. The powders were ground and mixed in a ZrO2 ball mill for homogenization. One powder mixture used for the glass batch (VAD79_12) was ground in a corundum ball mill to minimize possible ZrO2 contamination. Enrichment of ZrO2 may lead to nanometer-sized Zr phases (Cormier et al. 2015; Dargaud et al. 2011) prior or during decompression of hydrous melt. Crystalline phases even at a nanometer scale may initiate heterogeneous H2O vesicle nucleation (e.g., Shea 2017) that has to be avoided to study homogeneous phase separation.
The powder mixtures were decarbonated and fused in a Pt90Rh10 crucible by heating to 1873 K. After 6 h heating, the melts were rapidly quenched in deionized water. The cracked glasses were crushed and ground in the respective ball mills and melted again for 1 h at 1873 K. To inhibit crystallization, the melts were then air-cooled within 1–2 min close to the glass transition temperature (Tg) of 937 K, calculated after Giordano et al. (2008) assuming an H2O content of 1000 ppm. Subsequently, the supercooled melts were transferred into a furnace preheated to 833 K. The furnace was then switched off to maintain a cooling rate of ~ 5 K·min−1. This cooling procedure was fast enough to inhibit partial crystallization, and stress-induced cracking within the glass batches was minimized when cooling to room temperature. The compositions of the VAD79 glasses measured prior to the decompression experiments are given in Table 1.
Cylinders with a diameter of 5 mm were drilled from the glass batches and cut to lengths of 5.3–6.7 mm. The sharp cylinder edges were rounded with abrasive paper to prevent capsule damage during pressurization. The porosity of the glass cylinders, caused by some air vesicles trapped during melt synthesis, was determined by pycnometry to confirm porosities < 6% prior to the combined hydration and decompression experiments (Preuss et al. 2016).
Capsule preparation
A sufficiently large capsule volume has to be ensured, which is capable of containing the melt with equilibrium porosity (Φequ) without bursting during decompression to the relevant final pressure (Pfinal). Therefore, the Φequ at each Pfinal was calculated using the expected porosity equation of Gardner (1999) (Eq. 5 therein). The H2O solubility dependence from solubility experiments of Iacono-Marziano et al. (2007) and Marxer et al. (2015), the equation of state (EOS) for H2O of Duan and Zhang (2006), and the melt density calculation of Ochs and Lange (1999) were used for calculation. The resulting sample volumes were considered for the relationship of capsule to glass cylinder length. Cleaned and annealed Au80Pd20 tubes (13 mm length, 5 mm inner diameter) were closed with an electric arc-welded lid at the bottom. Glass cylinders were inserted into the capsules together with the desired amount of water. The top of each capsule was crimped to a three-sided star and welded shut while cooling with liquid nitrogen to prevent H2O loss by vaporization. A typical weight loss by welding-induced capsule metal loss is ~ 0.3 mg for the used design. If the weight loss of glass and water filled capsules mwl was determined to be > 0.3 mg after welding, mwl-0.3 mg was attributed to H2O loss as expressed in the negative errors given in Table 2 for the gravimetrically determined initial H2O concentration (cH2Ograv). However, it may be possible that more than 0.3 mg Au80Pd20 is lost instead of H2O during welding. This would result in an overestimation of the negative error of cH2Ograv. To check for possible leakage, the capsules were stored in a compartment dryer at 383 K, pressurized to 100 MPa at ambient T in a cold seal pressure vessel and again stored in a compartment dryer. After each step, the weight of the capsule was checked to exclude leakage prior to the decompression experiments.
Decompression experiments
Experimental technique
The combined hydration and decompression experiments were performed in an internally heated argon pressure vessel (IHPV) equipped with a rapid quench setup and a piezo-actuator driven high-pressure valve for continuous decompression (Berndt et al. 2002; Nowak et al. 2011). The intrinsic redox condition of the IHPV is 3.5 log units above the quartz fayalite magnetite (QFM) buffer at H2O saturated run conditions (Berndt et al. 2002). All samples were hydrated for at least 94 h at T ranging between 1500 and 1550 K at a starting pressure (Pstart) of 200 MPa, except of CD83 and the samples with cH2Oini > 5.6 wt%, which were hydrated at 198 and 270 MPa, respectively. After hydration, T was decreased to superliquidus decompression temperatures (Td) ranging between 1323 and 1523 K (Table 2) and thermally equilibrated for at least 0.5 h before isothermal decompression was initiated. Two control thermocouples recorded sample temperature gradients of < 20 K over a distance of ~ 12 mm. Because the sample length is lower (< 6.7 mm) than the distance of the two thermocouples, the T gradient within the samples is < 10 K.
For the decompression rates ≥ 0.17 MPa·s−1, the micrometer screw of the decompression valve was used to release pressure manually. During decompression, T decreased by ~ 5–10 K due to adiabatic cooling that could not fully be compensated by the digitally controlled furnace power. Only during decompression of sample CD95, which was decompressed to the lowest Pfinal of 20 MPa, the maximum T drop was ~ 50 K at Pfinal. At Pfinal, the decompression valve was closed and the capsules were isobarically quenched using an electrical power supply to melt the quench platinum wire, at which the capsules were suspended in the sample holder. Successful capsule drop was confirmed by a monitored T decrease ranging between 2 and 10 K in the hot zone of the furnace. The maximum achievable cooling rate of the IHPV is about 150 K·s−1 (Berndt et al. 2002). However, this cooling rate induces stress-induced cracks within the quenched glass samples. This leads to disintegration of the samples during further preparation. Therefore, a 35 mm brass cylinder was mounted at the bottom of the sample holder to reduce the cooling rate and thus crack formation during quench. The medium quench rate (MQ) of 44 ± 11 K·s−1 (Allabar et al. 2020) inhibited disintegration of the samples during preparation.
Experimental decompression conditions
The data for published decompression experiments using VAD79 white pumice composition (Iacono-Marziano et al. 2007; Marxer et al. 2015; Preuss et al. 2016; Allabar and Nowak 2018) that fulfill the experimental protocol given in Preuss et al. (2016) are compiled in Table 2. The experimental protocol ensures homogeneous phase separation by vesicle formation in the central part of the sample without effects of the experimental design or capsule size. Therefore, only data of experiments using glass cylinders were considered to exclude VND data influenced by pre-existing vesicles induced by the use of glass powder as starting material (Preuss et al. 2016). Additionally, the limitation of decompression rate defined by the sample diameter is considered, ensuring a central sample volume that is unaffected by diffusional H2O loss into early-formed fringe vesicles at the capsule wall and by vesicles ascending from the capsule bottom into the central melt volume (Iacono-Marziano et al. 2007; Marxer et al. 2015; Preuss et al. 2016; Allabar and Nowak 2018). At a decompression rate of 0.024 MPa·s−1, homogeneous phase separation is facilitated only in a small central melt volume that is already affected by diffusional H2O loss into fringe vesicles using 5 mm diameter samples with 5.3 wt% cH2Oini (Allabar and Nowak 2018). This defines the decompression rate limit for capsules with 5 mm diameter at the given H2O concentration. With decreasing cH2Oini, the H2O diffusivity and, consequently, the H2O-depleted drainage zone width decrease. This expands the feasible decompression rate towards lower values, at which homogeneous phase separation can still be observed in the central sample volume.
The compiled published VAD79 superliquidus decompression experiments were extended during this study by additional experiments to obtain four experimental series and an un-decompressed reference sample (Table 2): (1) To investigate the influence of cH2Oini on the degassing behavior of phonolitic melt, the C-Series was performed with fixed T of 1323 K and a dP/dt of 0.17 MPa·s−1, while the cH2Oini was changed. Therefore, the experimental set given in Allabar and Nowak (2018) with a cH2Oini of 5.3 wt% H2O was extended by experiments with higher (~ 6.3 wt%) and lower cH2Oini (~ 3.3 and ~ 4.3 wt%; Table 2; Fig. 1). These samples were decompressed to Pfinal ranging between 20 and 150 MPa. The 5.3 wt% cH2Oini data set of Allabar and Nowak (2018) at a dP/dt of 0.17 MPa·s−1 was extended by an experiment with a Pfinal of 60 MPa (CD73). The sample CD83 was hydrated with excess H2O to prove that there is no difference in VND after decompression from H2O supersaturated (CD73 of this study and experiments by Iacono-Marziano et al. 2007 and Marxer et al. 2015) and H2O undersaturated conditions (Preuss et al. 2016, Allabar and Nowak 2018, this study). To obtain a similar cH2Oini, CD83 was hydrated at 198 MPa, where H2O solubility is 5.34 wt% (Iacono-Marziano et al. 2007; Marxer et al. 2015). In this case, the homogenization time after T decrease from hydration T to Td was 1.5 h to ensure re-equilibration and homogenization of H2O concentration due to increasing solubility with decreasing T (Schmidt and Behrens 2008). The experiment CD-C-23 of Preuss et al. (2016) also fulfills the experimental parameters of the C-Series. (2) Experiments of the D-Series were performed with a cH2Oini of ~ 5.3 wt%. This series is a compilation of experiments performed at 1323 K with variable decompression rates. The experiments from Allabar and Nowak (2018), and experiments listed therein, were extended by the experiment CD28 decompressed with 1.7 MPa·s−1. (3) To ensure Td being well above the liquidus, experiments at 1373 K were performed (Allabar and Nowak 2018) at decompression rates of 1.7 MPa·s−1 (TD-Series) and (4) 0.17 MPa·s−1 (T-Series). The experiment CD44 was decompressed at 1523 K with the latter rate.
The sample Ref_A2 was hydrated with 5.3 wt% H2O at 1523 K and 200 MPa. The sample was quenched with MQ without decompression after the T decrease to 1323 K and a homogenization time of 0.5 h. Therefore, this sample represents the initial state of the samples with cH2Oini of 5.3 wt% prior to decompression.
Sample preparation
Pieces from the starting glass batches were embedded in epoxy resin and ground and polished for electron microprobe analysis (EMPA). The decompressed samples and the hydrated sample REF_A2 were cut along the cylinder axis. One half was embedded in epoxy resin and ground and polished for EMPA, scanning electron microscopy (SEM), laser scanning microscopy (LSM), and Raman micro-spectroscopy (RMS). The other halves were unwrapped from the capsule material, embedded with epoxy resin in glass–ceramic rings, and ground to a thickness of 100–320 µm. These samples were polished on both sides to obtain thin sections for Fourier transform infrared micro-spectroscopy (FTIR) and transmitted light microscopy analysis (TLM). Sample thickness was measured with a Mitutoyo digital micrometer (± 3 µm).
Analytical methods
Electron microprobe analysis
After glass synthesis, pieces of each glass batch were analyzed with a JEOL JXA 8900 R electron microprobe to confirm chemical composition and homogeneity (Table 1). EMPA WDS measurements were conducted with an acceleration voltage of 15 kV, 3 nA beam current, and a defocused beam of 20 µm to optimize for Na analysis (Devine et al. 1995). Peak counting times were set to 10 s (Na), 16 s (Si, Al, Fe, Mg, Ca, K), and 30 s (Ti, Mn, P) according to Preuss et al. (2016). Zr was additionally analyzed in glasses VAD79_07, 08, and 12 with a peak counting time of 60 s. 15–20 randomly distributed points were measured for each glass. The results (Table 1) agree within error with the VAD79 white pumice composition given in Iacono-Marziano et al. (2007).
Quantitative determination of VND and porosity
VND and glass porosity (Φglass) were determined in the central part of the samples where they are texturally homogeneous. Thus, convection-like patterns and effects of the capsule–melt contact, such as heterogeneously formed fringe vesicles and H2O-depleted drainage zones, were excluded from quantitative analysis (see results for further textural features). Sample vesicle textures with average vesicle diameters of > 5 µm were analyzed with backscattered electron (BSE) or LSM images. VNDs of samples containing smaller vesicles were quantified in thin sections with transmitted light microscopy. In some samples, several areas (BSE) and volumes (TLM) were analyzed (Table 2). Analysis of up to three areas within one sample resulted within error (± 0.13 log units, see description below) in similar VND and Φglass. Mean values are, therefore, given in Table 2.
Quantitative SEM and LSM image analysis
BSE images of the intersected samples were recorded with a LEO 1450 VP SEM or a Hitachi TM2020plus tabletop SEM, using individual magnifications of 150–2000 × to resolve the smallest detectable vesicle intersections on a µm scale. Several adjacent images were recorded and stitched for analysis. Surfaces of the intersected samples were imaged with a Keyence VK-X100 confocal laser scanning microscope. These images with contrast-rich surface information were treated similarly as the BSE images for quantitative image analysis. Both methods yielded similar VND within error, as tested with the sample CD73 for reference. BSE or LSM images were quantitatively analyzed with ImageJ combined with a stereological 2D to 3D transformation, using CSDCorrections (Higgins 2000) as described in detail by Marxer et al. (2015) and Preuss et al. (2016). An analytical error in VND determination of ± 0.13 log units was estimated considering all steps that are prone to errors, such as the choice of different analyzed areas within a sample, different operators for counting vesicles, or filling of vesicle intersections by blackening, to obtain sufficient contrast between glass and intersected vesicles for image analysis. Errors in porosity from image analysis were provided by CSDCorrections.
Transmitted light microscopy
Vesicles were quantified in the thin sections by marking the vesicles, while focusing through the samples with a Zeiss Axio Image M2M microscope, using the Fission Track Studio software “Trackworks”. The sizes of the analyzed areas were chosen individually for each measurement ranging between 2.3·10–2 and 8.5·10–5 mm2. Together with the sample thickness, this defines the size of the analyzed volume used to normalize the counted number of vesicles to the number of vesicles per mm3. Mean vesicle diameters were determined with the software-provided measurement tool to calculate Φglass and VND. Furthermore, inspection with TLM ensured microlite-free experimental samples. Errors from TLM analysis were calculated with an error propagation calculation using the error in sample thickness of ± 3 µm and assuming an error of 10% for vesicle size measurement, and 5% for the vesicle count.
Raman micro-spectroscopy
RMS was used to detect possible Fe-oxide nanolitization of the glasses, which is suggested to significantly affect the degassing behavior of supersaturated hydrous melt (Di Genova et al. 2017a, 2018; Shea 2017). The hydrated samples REF02 (Marxer et al. 2015), Ref_A2 (this study), and the partly degassed samples CD73 and CD95 with VAD79 composition were measured for this purpose. For comparison, hydrated glasses (IB_C_1a, IB_P2), a nominally dry glass (CI_glass), and a partly degassed sample (CD_C_5) from Preuss et al. (2016) with trachytic Campanian Ignimbrite (CI) composition, which shows similar degassing behavior to VAD79 melt (Preuss et al. 2016), were analyzed. Raman spectra were collected using a Renishaw InVia confocal Raman micro-spectrometer equipped with a 532 nm laser, a 1800 grooves·mm−1 grating and an Peltier-cooled CCD detector. Laser power was set to 10%, which corresponds to a laser power of ~ 2.5 mW on the sample. This energy is sufficiently low to avoid oxidation (Di Genova et al. 2017a) and dehydration of the samples. A 50 × objective with a numerical aperture of 0.75 was used together with the standard confocality setting. Focus depth was adjusted 6 µm below the sample surface to optimize the signal intensity (Di Genova et al. 2017a). Spectra were collected ranging between 300 and 950 cm−1, and acquisition times were 10 s for each of three accumulations.
FTIR micro-spectroscopy
Near-infrared (NIR) measurements were performed with a Hyperion 3000 IR microscope connected to a Bruker Vertex v80 FTIR spectrometer to determine total H2O contents (cH2OIR) of the decompressed samples. A tungsten light source, a CaF2 beam splitter, and an InSb single-element detector were used together with a 15 × Cassegrain objective. For each measurement, 50 scans in transmission mode were recorded with a spectral resolution of 4 cm−1 using air as reference. Following the method of Behrens et al. (1996), the total H2O contents were determined from molecular H2O (~ 5210 cm−1) and hydroxyl absorbance (4470 cm−1). To calculate total H2O contents, peak heights after linear background correction were used together with the linear molar extinction coefficients εH2O = 1.18 and εOH = 1.14 l·mol−1·cm−1 and the glass density dependence on H2O concentration ρ[g·cm−3] = 2.47–0.013·cH2O [wt%] (Iacono-Marziano et al. 2007). H2O concentration profiles were measured perpendicular and parallel to the samples cylinder axis using a motorized XYZ microscope stage and a knife-edge aperture that was set to a measurement window of 50 × 50 µm. During profile measurements and due to small inter-vesicle distances on a 10 µm scale, the H2O-filled vesicles in samples with low Φglass < 5% were measured together with H2O dissolved in the glass in the probed sample volumes. At higher glass porosities, these measurements were not possible, because samples become increasingly opaque with respect to NIR light.
Results
ZrO2 concentration of synthesized glasses
The two glasses VAD79_07 and 08 synthesized using a ZrO2 ball mill reveal ZrO2 concentrations of 1200 and 1000 ppm, respectively (Table 1). These values are higher than for the glass that was synthesized using a corundum mill (VAD79_12) with a ZrO2 concentration of 600 ppm. Note that the given concentrations are mean values of those measurements for which the ZrO2 concentration was above the detection limit of 350 ppm. For VAD79_07, this was the case in 19 out of 20 measurements, for VAD79_08 in 13 out of 15 analyses, and only 9 out of 20 measurements for VAD79_12. The results indicate that a contamination by 400–600 ppm ZrO2 by mechanical erosion during milling occurred in glass batches using a ZrO2 ball mill as compared to the glass using a corundum ball mill for synthesis.
Fe-oxide nanolites
Following the method of Di Genova et al. (2017a, 2018), RMS measurements confirm the absence of a distinct Raman scattering band at 670–690 cm−1 (Fig. 2a), indicative of Fe-oxide nanolites, for un-decompressed and decompressed VAD79 samples (2.7 wt% FeOtot, 1.37–5.26 wt% H2O). In contrast, experimental un-degassed and partially degassed hydrous CI samples (4.41 wt% FeOtot, Preuss et al. 2016) with cH2O > 3 wt% show a distinct Raman band at 680 cm−1. This is consistent with the nanolite occurrence field of hydrous Fe-bearing silicate glasses (Fig. 2b) defined by Di Genova et al (2017a).
Vesicle textures
In all decompressed samples, at the capsule–glass interface, strongly deformed 50–350 µm sized fringe vesicles are present, which increase in size with decreasing Pfinal (Fig. 3). In the central sample volume, vesicles are not observed at 60, 80, and 110 MPa in experiments with cH2Oini of 3.28 (CD93), 4.47 (CD86), and 5.32 wt% (CD48), respectively. In all other samples, the central volume is vesiculated and surrounded by a vesicle-free zone (drainage zone) close to the capsule walls. In samples decompressed with 0.17 MPa·s− 1, the drainage zone width increases with cH2Oini from ~ 250 µm at 3.3 wt% to ~ 500 µm at 4.3 and 5.3 wt% and ~ 650 µm at 6.5 wt% (Fig. 3), due to increased H2O diffusivity. These values were determined for samples with low Φglass, because the drainage zone thins out, as the porosity in the vesiculated sample volume and the fringe vesicles increase the total sample volume. Furthermore, the drainage zone becomes thinner in case of a second phase separation event, located close to the main population (see description below). On the other hand, the drainage zone width increases with decreasing decompression rate due to increased time for H2O diffusion as shown in Allabar and Nowak (2018).
The central vesiculated volumes in samples with cH2Oini < 5.6 wt% contain a high number density of homogeneously dispersed small vesicles, which are similarly sized within each sample (further referred to as main vesicle population). In the experiments with the lowest Pfinal (CD85, CD95, CD73), some vesicles of the main population are observed to be connected to each other. Additionally, in these samples, larger vesicles are observed within the main vesicle population (Fig. 3). Some of the large vesicles are connected to vesicle-free streaks underneath (e.g. CD73, Fig. 3) and are surrounded completely by a vesicle-free drainage zone ~ 50 µm in width.
In addition to the main vesicle population, which fills most of the central sample volume, in CD87, CD85, CD91, and CD73, a population of smaller vesicles (second population) is observed. Vesicles of the second population are located between the central vesiculated volume and the drainage zone of the capsule wall or in the drainage zone of large vesicles in CD85 and CD73 (Fig. 4), but always close to the main vesicle population.
At 6.3 wt% cH2Oini and a Pfinal of 150 MPa (CD102), vesicles are observable only in the top half of the sample volume at the limit of optical resolution. During further decompression, a pervasive vesiculation throughout the central capsule volume is observable in sample CD101, which was decompressed to a Pfinal of 145 MPa (bright area in the center of the sample in Fig. 3). Eventually, at 120 MPa, less but significantly larger vesicles remain (CD 97). The same pattern is observed in samples with slightly lower cH2Oini of 5.96–5.77 wt%, with half of the sample vesiculated at a Pfinal of 140 MPa. At a Pfinal of 100 MPa (CD100), only small vesicle clouds with finely dispersed vesicles are observed, while the remaining central sample volume contains a low number of large vesicles. In CD44, decompressed at high Td of 1523 K, half of the sample volume shows finely dispersed vesicles, while the other half contains some large vesicles.
VND and glass porosity
A systematic dependence of VND with decompression rate is lacking for hydrous VAD79 melt with cH2Oini of ~ 5.3 wt%, as already shown by Allabar and Nowak et al. (2018) for the dP/dt range of 0.024–10 MPa·s−1. The additional experiment CD28 of this study, with a logVND of 5.05, matches with their range of logVND from 4.83–5.39, irrespective of decompression rate. The logVNDs of the additional experiments performed at 1373 K ranging between 4.60 and 4.98 are lower (TD and T-series; Fig. 5) except for one experiment with a logVND of 5.48 (CD59). At 1523 K (CD44), logVND increased to 5.87, however at slightly lower cH2Oini of 4.96 wt%. The standard deviation of logVND is 0.26, as derived from data of the experiments performed at 1373 K and similar cH2Oini of ~ 5.3 wt%. For experiments of the C-Series with cH2Oini ~ 5.3 wt% and different Pfinal, the standard deviation of logVND is 0.34. This defines an experimental error in logVND of ~ 0.3 log units that is larger than the estimated analytical error of ± 0.13 (error bars in Fig. 5).
Significant changes in VND result from experiments with varying cH2Oini. The highest logVNDs of 5.96 and 6.37 are observed in samples with cH2Oini of ~ 3.3 wt% (Fig. 5). The logVND decreases to ~ 5 at cH2Oini of 5 wt%. Towards cH2Oini of ~ 6.3 wt%, the logVND increases again to ~ 5.8. In contrast, the VND keeps constant within error with decreasing Pfinal for experiments with constant cH2Oini (see online resource “Supplementary information”). Thus, the VND is dependent only on cH2Oini and slightly on Td. In the experimentally investigated Pfinal range, Φglass of the main population increases with decreasing Pfinal from < 0.1 to a maximum of 15.4, 24.4, and 18.5% at ~ 3.3, ~ 4.4, and ~ 5.3 wt% cH2Oini, respectively (Table 2).
The logVNDs of the second population of vesicles (Table 2) ranging between 5.66 and 6.14 are significantly higher than the logVND of the respective main populations of 5.41–5.45. The Φglass within the volume of the second vesicle population ranging between 0.2 and 9.0% are lower than the values of the respective main population ranging between 9.0 and 24.4%. In sample CD73, the second population shows a higher Φglass in the drainage zone of the large vesicle (9.0%, Fig. 4) compared to the second population located in the capsule wall drainage zone (1.0%).
H2O concentrations
The H2O concentrations as measured by FTIR (cH2OIR) of the central sample volumes without observable vesicles resemble the initial cH2Ograv. The same holds for the samples with Φglass < 5%, where the probed volume contained glass together with vesicles (e.g., CD-C-23, CD40). In three experiments, considerable weight loss occurred during welding. For two of these samples (CD102 and CD101), cH2OIR is similar to cH2Ograv, whereas CD98 has a reduced cH2OIR of 5.96 wt% as compared to the cH2Ograv of 6.27 wt%. In CD44, the cH2OIR measured in the central vesiculated sample volume is slightly decreased to 4.96 wt% with respect to the cH2Ograv of 5.28 wt%. For CD85, which also experienced weight loss during welding, the porosity was too high for reliable cH2OIR determination. The cH2OIR measured in the volumes of the second population of vesicles are within error similar to the cH2Ograv in CD87, CD85, and CD91, but decreased considerably to 4.99 wt% in CD73 compared to the cH2Ograv of 5.46 wt%.
Discussion
H2O concentrations
In experiments starting from slightly undersaturated conditions, the cH2Oini is defined by the gravimetrically determined cH2Ograv. However, since, for samples with Φglass < 5%, the cH2OIR equals within error cH2Ograv (e.g., CD-C-23, CD40; Table 2), cH2OIR was used as the dissolved H2O concentration in the melt prior to decompression (cH2Oini). This has the advantage that uncertainties in cH2Ograv, caused by weight loss during welding, are eliminated (e.g., CD102, CD98). The cH2OIR reveal that weight loss of CD102 and CD101 resulted from Au80Pd20 loss during welding, whereas in case of CD98, some H2O was lost. Similar to CD77 (Allabar and Nowak 2018), the cH2O prior to phase separation in CD44 was already reduced as compared to the cH2Ograv. During decompression at a higher Td of 1523 K, the H2O diffusivity is higher and viscosity is lower than at a lower Td of 1323 K. Thereby, diffusional loss of H2O into fringe vesicles, that early nucleated heterogeneously at the capsule wall during decompression, increases and ascent of fringe vesicles is facilitated. Both effects reduce H2O supersaturation within the central sample volume, similar to CD77 with a low decompression rate of 0.024 MPa·s−1 (Allabar and Nowak 2018). However, in both samples, a reduced but constant cH2OIR was measured in the central vesiculated sample volume, which was therefore used as cH2Oini.
For CD100, a mean cH2OIR of 5.43 wt% was measured in various small vesicle clouds. Because the vesicle clouds of the main vesicle population are only small (~ 0.1 mm3), it may be possible that after phase separation of the main vesicle population, H2O was lost into large vesicles which are located close to the small vesiculated melt volumes, driven by Ostwald ripening. Because CD98 with a similar cH2Oini shows that the melt was vesiculated by the main population at higher Pfinal, it is suggested that the high VND observed in the small vesicle clouds in CD100 represents the product of a phase separation at the initial cH2O. Therefore, cH2Oini of 5.77 wt% is assumed for CD100.
In decompression experiments that started from H2O supersaturated conditions after hydration (e.g., CD83 and CD73), cH2Oini is defined by the H2O solubility at Pstart and Td. Solubility data for hydrous VAD79 melt at Td and Pstart were derived from Iacono-Marziano et al. (2007) and Marxer et al. (2015). The cH2Ograv, cH2OIR, and H2O solubility data that were used as cH2Oini are highlighted in bold numbers in Table 2.
Results of cH2OIR measurements in the glass between vesicles are presented in Allabar et al. (2020). These data are not used for further discussion here, because the cH2OIR of the glass between vesicles does not represent cH2O dissolved in the melt at Pfinal prior to quench due to H2O resorption from the fluid phase back into the melt during quench (McIntosh et al. 2014; Allabar et al. 2020).
Phase separation
Verification of homogeneous phase separation
With the decompression experiments compiled and performed for this study, it is intended to investigate homogeneous phase separation of hydrous phonolitic melt. Therefore, it is necessary to verify a single-phase superliquidus system at the onset and during decompression until vesicle formation starts in the central volume of the sample.
The use of a ZrO2 ball mill for synthesis of the starting glasses VAD79_03-10 caused ZrO2 contamination of 1000–1200 ppm, while the use of a corundum ball mill for synthesis of VAD79_12 yields a lower ZrO2 contamination of 600 ppm ZrO2. ZrO2 saturation caused by ZrO2 contamination could lead to pre-existing ZrO2 or ZrSiO4 crystals or ZrO2 rich domains on a mesoscopic scale (e.g., Cormier et al. 2015; Dargaud et al. 2011). Zr phases may act as vesicle nucleation sites, favoring heterogeneous nucleation of vesicles during decompression. However, a ZrO2 solubility of 3660 ppm was calculated for dry VAD79 melt composition at 1323 K using the model of Gervasoni et al. (2016). The ZrO2 solubility increases linearly with H2O concentration up to 2 wt% and remains constant towards higher cH2O in granitic melts at high T (Watson and Harrison 1983). Assuming a similar dependence in phonolitic melt, the measured ZrO2 concentrations in the starting glasses are far below the ZrO2 saturation limit. Furthermore, pre-existing crystals in the starting glasses or crystal formation during degassing caused by ZrO2 contamination were not observed by TLM or SEM-BSE imaging. Experimental samples with high and low ZrO2 contamination with identical decompression conditions of cH2Oini ~ 5.3 wt%, dP/dt of 0.17 MPa·s−1, and Pfinal of 80 MPa reveal similar VNDs. The samples CD63 (starting glass VAD79_07) and CD91 (starting glass VAD79_12) reveal logVNDs of 5.24 and 5.41, respectively.
Aside from Zr phases, Fe-oxide crystals may form during the decompression experiments at the lowest Td of 1323 K. Surfaces of magnetite crystals reduce efficiently the energy and the supersaturation pressure required for H2O vesicle nucleation (e.g., Hurwitz and Navon 1994; Shea 2017). H2O solubility experiments of Iacono-Marziano et al. (2007) reveal that at P between 250 and 30 MPa, the phase boundary of Fe-oxides for VAD79 melt is between 1323 and 950 K. This is supported by the synthesis of hydrous reference VAD79 samples of Marxer et al. (2015) at 1323 K, 200–75 MPa and intrinsic oxygen fugacity of ∆logQFM = + 3.5. BSE images reveal that these glasses are free of µm-sized Fe-oxide crystals. Phase equilibria experiments with hydrous CI melts of similar composition, determined by Fabbrizio and Carroll (2008) at ΔlogNNO = + 0.8, reveal liquidus temperatures higher than 1143 K and 1133 K for P of 50 and 200 MPa, respectively. However, experiments at T > 1143 K that are required to bracket the phase boundary for the liquidus phase magnetite are lacking. Fanara et al (2012) performed phase equilibria experiments with hydrous CI melt in an IHPV at intrinsic ΔlogQFM = + 3.5. The liquidus temperature, defined by the phase boundary of magnetite, is between 1273 and 1323 K for H2O activities between 1 and 0.5 and a P of 200 MPa. These data show that for hydrous VAD79 melt, the phase boundary of magnetite may be close to the lowest decompression temperature of 1323 K.
Another driving mechanism for decompression-induced vesicle formation in hydrous melt might be heterogeneous nucleation at nanometer-sized Fe-oxide crystals (ultrananolites smaller than 30 nm and nanolites 30 nm to 1 µm as classified by Mujin et al. 2017), as suggested by, e.g., Di Genova et al. (2017a,b; 2018) and Shea (2017). Such nanolites are observed in natural volcanic products. The formation of Fe-oxide nanolites can be related to pre-, syn-, and post-eruptive processes. Post-eruptive Fe-oxide nanolites are observed in glass particles of welded tuff (Schlinger and Smith 1986; Schlinger et al. 1988) and in natural obsidian glasses (Sharp et al. 1996). Fe-oxide nanolites related to syn-eruptive processes are observed in dense juvenile fragments of lava derived from a 2011 sub-plinian andesitic–dacitic eruption of Shinmoedake (Mujin and Nakamura 2014 and Mujin et al. 2017). Fe-oxide nanolites at and near vesicle surfaces of Mt Etna ashes might be related to syn- and post-eruptive processes (Barone et al. 2016). Furthermore, Di Genova et al. (2017a; b; 2018) observed Fe-oxide nanolites in experimental and natural hydrous silicate glasses.
Fe-oxide nanolites potentially drive heterogeneous vesicle nucleation that may have been overlooked in previous studies of Iacono-Marziano et al. (2007), Marxer et al. (2015) Preuss et al. (2016) and Allabar and Nowak (2018), because this mechanism may mimic homogeneous phase separation. Fe-oxide nanolites may form during thermal equilibration prior to decompression and during decompression and degassing of hydrous VAD79 melt. Nanolite formation might be induced by thermodynamic metastability or instability of H2O supersaturated melt and by increasing liquidus temperature with decreasing H2O content.
However, the RMS measurements (Fig. 2) prove that the selected quenched hydrous VAD79 samples are free of Fe-oxide nanolites. The minimum decompression temperature of 1323 K for our VAD79 experiments is sufficiently high to inhibit Fe-oxide nanolitization prior to and during decompression and phase separation, and during cooling the samples. This holds even for the sample CD95 with the lowest cH2Oini of 3.36 wt% cH2Oini and Pfinal of 20 MPa (Fig. 1) that experienced a T drop of 50 K at the end of decompression. Thus, the vesicle formation in hydrous VAD79 melt is not affected by Fe-oxide nanolitization.
In contrast to the VAD79 samples, the CI samples containing 4.87 and ~ 3.2 wt% H2O (Preuss et al. 2016) show distinct Raman bands at ~ 680 cm−1, indicative of Fe-oxide nanolites. However, both hydrous melt compositions reveal logVNDs in the same order of magnitude of 4.83–5.92 during decompression, independent of decompression rate (Preuss et al. 2016; Allabar and Nowak 2018) and independent of the occurrence of Fe-oxide nanolites in the quenched glasses. This suggests that (1) the Fe-oxide nanolites, detected in hydrous Campi Flegrei trachytic glass samples of Preuss et al. (2016), formed after decompression and vesicle formation during rapid isobaric quench within the metastable field of the hydrous supercooled melt or (2) that Fe-oxide nanolites in CI melts formed prior to phase separation, e.g., deep within the metastable field of supersaturated melt, and mimic homogeneous vesicle formation.
We conclude that heterogeneous vesicle nucleation at low supersaturation occurred only at the interface of capsule walls and melt as an experimental artifact (fringe vesicles) in our samples. A vesicle-free drainage zone evolved between fringe vesicles and the central sample volume by diffusional H2O loss into fringe vesicles during further decompression after their formation. If heterogeneous nucleation had also formed the observed vesicles in the central sample volume, this vesicle-free drainage zone would be smaller due to much lower supersaturation P required for heterogeneous nucleation and the shorter time available for H2O diffusion into fringe vesicles (Allabar and Nowak 2018). At a ΔPhet (difference between saturation P and pressure of heterogeneous vesicle nucleation) of ~ 5 MPa that is suggested for nucleation at magnetites (Hurwitz and Navon 1994; Shea 2017), the drainage zones would be only ~ 120 µm for 6.3 wt% cH2Oini to ~ 75 µm at 3.3 wt%. The observed drainage zone width of 650 and 250 µm, respectively, is indicative of homogeneous phase separation at larger supersaturations at the pressure at which phase separation starts (Phom). Finally, for heterogeneous nucleation, a dependence of VND on dP/dt, as predicted by nucleation theory, is still expected (Shea 2017; Allabar and Nowak 2018). However, this is not observed in hydrous phonolitic melt.
In summary, in the decompression experiments of this study and in the published experiments compiled in this study, it is ensured that homogeneous phase separation by vesicle formation occurred in the central volume of the samples as close to the terminus as possible. Therefore, only the main vesicle population was considered for characterization of homogeneous phase separation by quantitative VND analysis.
Homogeneous phase separation
Homogeneous phase separation occurred in the central volume of the samples where the cH2Oini was preserved and not affected by diffusional H2O loss towards heterogeneously nucleated vesicles at the capsule walls. Allabar and Nowak (2018) showed that an independence of VND on decompression rate cannot be explained by nucleation theory, but is consistent with the theory of spinodal decomposition.
For vesicle nucleation, a continuous increase of VND with decreasing Pfinal is expected until a sufficiently high number of vesicles is formed to decrease supersaturation below a threshold value for further nucleation. This leads to a broadening in vesicle size distribution towards low decompression rates (Shea et al. 2010b). However, the observed independence of VNDs with decreasing Pfinal at constant cH2Oini, the similarly sized vesicles in the central sample volume within each experiment (see VVD-plots in the online resource “Supplementary information”), and the independence of VND from decompression rate (Allabar and Nowak 2018) indicate that the formation of vesicles is inconsistent with nucleation theory. It is suggested that off-critical spinodal decomposition is a potential phase separation mechanism in H2O supersaturated phonolitic melt (Allabar and Nowak 2018). Spinodal decomposition is a non-activated spontaneous process at the spinode, i.e., at the thermodynamic limit of metastability (e.g., Cahn and Hillard 1959; Cahn 1965). Thermally induced spatial concentration (c) fluctuations are attenuated by downhill diffusion in the metastable state, where the second derivative of the free energy of mixing (ΔG) ∂2ΔG/∂c2 is > 0. In the unstable state, however, where ∂2ΔG/∂c2 is < 0, the concentration fluctuations are amplified by uphill diffusion until sharp phase boundaries between hydrous silicate melt and an H2O-rich fluid phase evolve (Debenedetti 2000; Tanaka et al. 1990).
A quantitative approach, based on the theory of spinodal decomposition, to explain the observed minimum of VND at a cH2Oini of ~ 5 wt% (Fig. 5) is difficult, because H2O is a reactive component in silicate melts. The volatile component H2O dissolves mainly as hydroxyl groups and as some molecular H2O, which was demonstrated by in-situ measurements of hydrous aluminosilicate melt (Nowak and Behrens 1995; Nowak and Behrens 2001). The polycondensation reaction 2(Si,Al)-OH = (Si,Al)-O-(Si,Al) + H2O produces molecular H2O during phase separation and is accompanied by an exothermic reaction enthalpy (Nowak and Behrens 2001), in addition to the enthalpy and entropy of mixing. Thus, the phase separation cannot be quantified by a simple regular solution model as conceptually presented by Allabar and Nowak (2018). However, a sound physicochemical quantification of spinodal phase separation of hydrous phonolitic melt is beyond the scope of this study. Regardless of these limitations, a qualitative justification for the observed dependence of VND on cH2Oini is possible for two different assumptions:
(1) It is possible that the observed VND is defined by the wavelength of concentration fluctuations that are amplified during spinodal decomposition. In this case, vesicles are formed one wavelength apart from each other. Such a case is described for droplet-type spinodal decomposition, which is possible when the volume fraction of the minor phase, H2O in the case of hydrous melt, is < 15% (Cahn 1965). The critical (i.e., minimum) wavelength (λc) that is amplified when a system becomes unstable is λc = 2π/βc, where the critical wavenumber βc is defined as (Cahn 1965):
where κ is a positive constant and the numerator term is the curvature of the free energy curve as a function of composition at given P and T. The wavenumber, at which amplification is maximum, is βm = βc/(20.5). Consequently, at given P and T, the wavelength of successfully amplified concentration modulations, which may be associated with the observed VND, depends on composition, i.e., on the H2O concentration. In our experiments, not only the cH2Oini is varied, but as a consequence, also the Phom. This could lead to the increase of VND towards high and low cH2Oini. The higher T of 1523 K of CD44, compared to all other experiments, could have induced a similar change in curvature of the free energy curve as the increase or decrease in cH2Oini, leading to a higher VND (Fig. 5).
(2) Alternatively, the VND observed in the experimental samples may be the result of textural coarsening of fractal ramified structures (Cahn 1965) of the two phases, into which the hydrous melt may have separated by spinodal decomposition. Since the samples that were quenched at different Pfinal show similar VNDs at constant cH2Oini, there might be a stable VND at which coarsening stops. Coarsening likely depends on melt viscosity, surface tension, and H2O diffusivity, which are all parameters that depend on H2O concentration. This could result in the varying VND with changing cH2Oini.
Evolution of degassing
For all vesiculated samples, Φglass is smaller than the calculated Φequ at Pfinal and Td (Allabar et al. 2020). At first sight, this suggests disequilibrium degassing during decompression. However, diffusion calculations reveal that near equilibrium must have been approached in all experiments due to sufficiently high H2O diffusivity and small inter-vesicle distances at a 10 µm scale (Allabar et al. 2020). Only for the samples with ~ 3.3 wt% cH2Oini, degassing close to equilibrium is not ensured during decompression to Pfinal (Allabar et al. 2020). For all other experiments, the low Φglass compared to Φequ is suggested to be related to vesicle shrinkage during isobaric cooling caused by the decrease of the molar volume of the H2O fluid during cooling (Marxer et al. 2015), accompanied by resorption of H2O from fluid vesicles back into the melt (McIntosh et al. 2014) due to increasing H2O solubility with decreasing T (e.g., Schmidt and Behrens 2008). The suggestion of significant vesicle shrinkage is supported by the observation of strongly deformed fringe vesicles. Vesicle shrinkage during cooling of the samples from this study is in detail explained in Allabar et al. (2020). However, the cH2Oini-dependent VNDs and coalescence processes can be discussed here, without considering vesicle shrinkage.
At cH2Oini < 5.6 wt%, the initially formed VND of the vesicles of the main population remains stable during decompression to low pressure until Φmelt is sufficiently large for the onset of coalescence, as observed in the experiments with Pfinal of 20, 40, and 60 MPa with 3.36 (CD95), 4.30 (CD85), and 5.46 wt% (CD73) cH2Oini, respectively (Fig. 6). It can be excluded that the larger vesicles observed in the central part of the samples are due to pre-existing vesicles that might result from air vesicles in the glass cylinders used for the decompression experiments (Preuss et al. 2016). In this case, the vesicle-free drainage zone around these vesicles should be as wide as the drainage zone towards the capsule wall, which is not the case (Fig. 3). In CD95, the drainage zone towards fringe vesicles at the capsule wall is ~ 400 µm, while the distance between the walls of large vesicles and the main population is only ~ 50 µm. This suggests that the large vesicles in the central volume of the samples may be former fringe vesicles that detached from the capsule walls and ascended through the melt during further decompression and degassing. Vesicle-free streaks, indicating the ascent track of these vesicles, are visible, e.g., in CD73 (Fig. 3). However, in CD95 and CD85, large vesicles are isolated in the center of the samples and surrounded by small vesicles. Ascent tracks below these large vesicles are not visible. Additionally, the observation that at Pfinal > 20 and > 40 MPa large vesicles are not present in central sample volumes with cH2Oini of 3.3 and 4.3 wt%, respectively, argues for coalescence, forming the large vesicles from the main vesicle population at the lowest Pfinal. Assuming Φequ (calculated after Gardner et al. 1999, Eq. 5 therein) prior to quench (Allabar et al. 2020), it can be concluded from the experimental observations that coalescence and the linked reduction of VND of the main vesicle population starts at similar Φmelt of 30–50%, 30–40%, and 35–40%, at 3.3, 4.3, and 5.3 wt% cH2Oini, respectively. Note that the Φmelt values for 3.3 wt% cH2Oini are prone to the uncertainty whether near-equilibrium degassing occurred in CD95 (Allabar et al. 2020). In case of disequilibrium degassing, the Φmelt at the onset of coalescence would be lower.
The vesicles of the second population formed when H2O diffusion into the large vesicles or fringe vesicles and towards the opposite side into vesicles of the main population was not fast enough to effectively reduce the H2O supersaturation that had built up during further continuous decompression. This led to a secondary homogeneous phase separation event at cH2O < cH2Oini and lower Pfinal as compared to the main vesicle population, resulting in lower Φequ and consequently lower Φglass. The logVND of the second population is 0.21–0.69 log units higher than the logVND of the respective main population. This is consistent with an increase of VND towards lower cH2O of the melt just prior to phase separation (Fig. 5).
However, this observation contrasts with the measured cH2OIR of the volumes of the second population, which mostly reflects within error the cH2Oini (Table 2). The measured cH2OIR could in this case overestimate the cH2O of the melt at phase separation. As described in Allabar et al. (2020), H2O is resorbed from the fluid back into the melt during quench. As a result, the cH2Omelt at Td and Pfinal is lower than cH2Oglass between vesicles at ambient conditions. In the large volume of the main vesicle population, the H2O is resorbed rapidly into the melt from the vesicles during cooling due to short inter-vesicle distances on a 10 µm scale. Thus, the measured cH2OIR is expected to reflect the cH2Oini and thus the cH2O at phase separation. In the small volume of the second population, which is always located close to the main vesicle population, H2O may not only be resorbed from the vesicles of the second population but also from the main population into the melt volume of the second population. As a result, the measured cH2OIR in the glass is higher than the cH2O at phase separation.
At cH2Oini of 5.6 wt% a transition is observed in the degassing evolution during decompression (Fig. 6). At cH2Oini > 5.6 wt%, the initial VND of the main population is only observable for a short P interval of, e.g., ~ 20 MPa at 6.3 wt% cH2Oini. In CD102 (Pfinal = 150 MPa), only in half of the sample, vesiculation is observable at very low Φglass, which is first due to the large drainage zone at high cH2Oini, that is better visible in CD101 (Fig. 3) due to the higher Φglass. Second, vesicles in CD102 could have shrunk and H2O may have been resorbed back into the melt during cooling (Allabar et al. 2020), so that this experiment may be at the very limit of vesicle observation for the used quench rate. During decompression from 150 to 145 MPa (CD101), the initially observed logVND remains stable at ~ 5.7. During further decompression to 120 MPa, the main vesicle population is completely erased by coalescence and a low logVND of 1.92 remains (CD97) at decompression times ((Psat-Pfinal)/(dP/dt)) at which the initial VND is still observed at cH2Oini < 5.6 wt% (Fig. 6). The P range of 145–120 MPa, during which VND drastically decreases at 6.3 wt% cH2Oini, corresponds to Φmelt (= Φequ) between 15 and 21% for equilibrium degassing of the homogeneously formed vesicles of the main population. Therefore, coalescence occurs at much lower melt porosities and to a greater extent at 6.3 wt% compared to cH2Oini < 5.6 wt%. In experiments with cH2Oini < 5.6 wt%, where the onset of coalescence is observed at 20, 40, and 60 MPa with increasing cH2Oini, logη (in Pa·s) calculated for equilibrium cH2O at 1323 K is 3.7, 3.2, and 3.0 (Giordano et al. 2008), respectively (Fig. 6). Note that the first value for 3.3 wt% cH2Oini may be lower in case of possible disequilibrium degassing. Beyond the transition at cH2Oini of 5.6 wt%, the initial vesicle population is already completely erased at lower decompression time, i.e., lower logη of 2.4–2.6. The early onset of coalescence at cH2Oini > 5.6 wt% is attributed to the lower viscosity with increased cH2O. Decreasing viscosity favors coalescence (i.e., Fortelný et al. 1999). Consequently, at a decompression rate of 0.17 MPa·s−1, the initial VND cannot be preserved during further continuous decompression.
Implications for volcanic eruptions
During the 79AD Vesuvius eruption, grey (tephriphonolite) and white (phonolite) pumice were ejected and are recorded in distinct eruptive units (EU) (e.g., Cioni et al. 1995). One may assume that small differences in bulk composition between white and grey pumice do not significantly influence the degassing behavior, as shown by Preuss et al (2016) for VAD79 white pumice and trachytic CI composition.
For the melt that formed the natural Vesuvius white pumice, a cH2Oini of 6.0–6.4 wt% was determined in melt inclusions in samples of eruptive unit 2 (EU2) (Cioni 2000). For EU1, pre-eruptive H2O concentration data are lacking. However, chemical bulk compositions of EU1 and EU2 are similar, and a homogeneous H2O distribution in the magma that formed the white pumice is assumed (Shea et al. 2014). Therefore, the cH2Oini of EU1 is suggested to be similar to EU2. The logVND in the white pumice ranges from 6.41 to 6.89 in EU1 and 6.38–7.08 in EU2 with mean values of 6.61 and 6.74, respectively (Shea et al. 2010a; Gurioli et al. 2005; Fig. 5). However, pre-eruptive T was ~ 1100–1200 K (Shea et al. 2009), well below the experimental temperatures, which results in partial crystallization and a higher melt viscosity by one log unit (Giordano et al. 2008) at the given cH2Oini.
EU1 and EU2 reveal higher VNDs than the experimental initial VND for similar cH2Oini (Fig. 5). Furthermore, in the experiments with cH2Oini > 5.6 wt%, the initial main population is erased at relatively high P during decompression at 1323 K (Fig. 6). However, at the lower magmatic temperature, it is possible that coalescence is shifted to lower P, due to higher viscosity compared to the superliquidus decompression experiments. Thus, the high VND in EU1 and EU2 may still represent the main vesicle population. Two possible scenarios may explain the high VND in natural white pumice, both considering pre-existing vesicles prior to homogeneous phase separation (Allabar and Nowak 2018), because vesicles may heterogeneously nucleate at low supersaturation (Hurwitz and Navon 1994; Shea 2017) on crystal surfaces in a subliquidus melt. These pre-existing vesicles drive buoyant acceleration of magma ascent and decrease melt cH2O in their vicinity by H2O diffusion. The assumption of a pre-existing vesicles number density, which equals the crystal number density of up to 0.3 mm−3 (Iacono-Marziano et al. 2007; Allabar and Nowak 2018), results in a limiting decompression rate for homogeneous phase separation of 0.06 MPa·s−1 for a magma with cH2Oini of 6.3 wt% and T of 1150 K. In the first scenario, at decompression rates > 0.06 MPa·s−1, the initial cH2O is preserved in interstitial melt volumes. The observed VND of natural white pumice would represent the initial VND of homogeneous phase separation that was preserved during magma ascent to the surface. This requires that at lower T of ~ 1150 K, the initially formed VND at cH2Oini of ~ 6 wt% VND is higher than observed in experiments at 1323 K.
In the second scenario, at decompression rates < 0.06 MPa·s−1, the pre-existing VND is sufficient to reduce H2O supersaturation to prevent homogeneous phase separation at high cH2O. The VND of white pumice suggests vesicle formation at decreased cH2O values of < 3.3 wt%, at which homogeneous phase separation produced a high VND, consistent with the experimental results. In both scenarios, initial and second phase separation events occur that lead to a bimodal vesicle size distribution, as observed in natural products (e.g., Gurioli et al. 2005), and indicate two decompression and vesiculation stages.
The eruptive units EU3 and EU4 consist of grey pumice with a cH2Oini of 3–3.5 wt% (Cioni 2000; Shea et al. 2014). The logVNDs range from 5.15 to 6.57 in EU3 and 5.97–6.30 in EU4 with mean values of 5.84 and 6.18, respectively (Gurioli et al. 2005; Fig. 5). Due to a pre-eruptive magma T of ~ 1323 K (Cioni et al. 1995) for the grey pumice, the VNDs are comparable to our experimental results and are in good agreement with the experimentally derived VNDs (Fig. 5). Thus, we suggest that the high VNDs in the natural grey pumice represent the initially formed vesicle population that is preserved down to 0.1 MPa and causes porosities up to 80% (Shea et al. 2012) until open system degassing commences. In the superliquidus continuous decompression experiments of this study, the onset of coalescence in samples with cH2Oini of 3.3 wt% was already observed at 20 MPa during decompression with 0.17 MPa·s−1 (Fig. 6). However, in a natural system, decompression rate increases at the onset and during vesiculation by increasing buoyancy of the melt with decreasing density. Thus, the time available for coalescence decreases and the initial VND is likely preserved until the magma reaches the surface.
Previously, it has been shown that under the assumption of homogeneous nucleation, extreme decompression rates of 50–55 MPa·s−1 would be necessary to explain the observed high VNDs in grey pumice. Therefore, it has been suggested that heterogeneous nucleation on oxides caused the high VND observed in grey pumice, for which decompression rates of 2.35–11.53 MPa·s−1 were calculated (Shea et al. 2012). Contrary to that, an alternative explanation is phase separation by spinodal decomposition that may have formed the high VND. Micro-phenocrysts, mainly leucite, with high number densities of ~ 104 formed during degassing (Shea et al. 2012) and are, therefore, not considered as sites for heterogeneous nucleation. Furthermore, we assume that although chlorine is an additional component (~ 0.6–0.8 wt%, Shea 2014) in natural VAD79 magma, the experiments of this study, with solely H2O as volatile component, may be comparable with the natural system, because a non-volatile behavior of chlorine during the AD79 Vesuvius eruption is observed (Shea et al. 2014). Therefore, the solubility of H2O in phonolitic–trachytic melt is not largely affected by such low chlorine concentrations (Webster et al. 2014). According to our experimental data, we suggest that 0.17 MPa·s−1 is sufficient to form ~ 106 mm−3 vesicles by spinodal decomposition before the onset of an explosive eruption and ejection of the grey pumice.
Conclusion
In addition to the decompression rate independent VND (Allabar and Nowak 2018) in superliquidus phonolitic melt, the high VND and their dependence on cH2Oini found in this study are also compatible with the theory of spinodal decomposition. However, definite evidence and a quantitative description for this phase separation mechanism are still lacking.
The VND finally observed in volcanic products is, particularly for high cH2Oini, likely an obscured product of initial vesicle formation, coalescence, ripening, and secondary-phase separation processes in interstitial melt volumes. The resulting vesicle texture depends on parameters such as melt viscosity and the available timescale, i.e., decompression rate before and during fragmentation and quench. From the comparison of experimental results with natural pumices of the AD79 eruption, the high VND in natural products may be explained by homogeneous spontaneous phase separation as in the experiments of this study. However, although the high-temperature experiments of this study are not fully comparable with the VAD79 eruption, they may be similar to the recent magma conditions of Vesuvius. In the last 20 ka, the magma temperature of Vesuvius has continuously increased from ~ 1100 to > 1373 K (Scaillet et al. 2008). Therefore, the results of this study may be useful for the interpretation of future Vesuvius eruptions and eruptions of other volcanoes with phonolitic and trachytic superliquidus melt.
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Acknowledgements
Open Access funding provided by Projekt DEAL. The authors would like to thank Barbara Maier and Annette Flicker for technical support and maintenance of the IHPV and Simone Schafflick for the sample preparation. We thank Cong Nguyen for preparing experiments CD85-87 within the frame of his Bachelor thesis. We wish to thank Amy Ryan and an anonymous reviewer for their helpful comments that improved the quality of the manuscript. This manuscript is part of the PhD project of the first author and is funded by the German Science Foundation (DFG NO378/12-1).
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Allabar, A., Salis Gross, E. & Nowak, M. The effect of initial H2O concentration on decompression-induced phase separation and degassing of hydrous phonolitic melt. Contrib Mineral Petrol 175, 22 (2020). https://doi.org/10.1007/s00410-020-1659-2
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DOI: https://doi.org/10.1007/s00410-020-1659-2