Abstract
Crystallisation-driven differentiation is one fundamental mechanism proposed to control the compositional evolution of magmas. In this experimental study, we simulated polybaric fractional crystallisation of mantle-derived arc magmas. Various pressure–temperature trajectories were explored to cover a range of potential magma ascent paths and to investigate the role of decompression on phase equilibria and liquid lines of descent (LLD). Fractional crystallisation was approached in a step-wise manner by repetitively synthesising new starting materials chemically corresponding to liquids formed in previous runs. Experiments were performed at temperatures ranging from 1140 to 870 °C with 30 °C steps, and pressure was varied between 0.8 and 0.2 GPa with 0.2 GPa steps. For most fractionation paths, oxygen fugacity (fO2) was buffered close to the Ni-NiO equilibrium (NNO). An additional fractionation series was conducted at fO2 corresponding to the Re-ReO2 buffer (RRO ≈ NNO+2). High-pressure experiments (0.4–0.8 GPa) were run in piston cylinder apparatus while 0.2 GPa runs were conducted in externally heated pressure vessels. Resulting liquid lines of descent follow calc-alkaline differentiation trends where the onset of pronounced silica enrichment coincides with the saturation of amphibole and/or Fe–Ti–oxide. Both pressure and fO2 exert crucial control on the stability fields of olivine, pyroxene, amphibole, plagioclase, and Fe–Ti–oxide phases and on the differentiation behaviour of arc magmas. Key observations are a shift of the olivine–clinopyroxene cotectic towards more clinopyroxene-rich liquid composition, an expansion of the plagioclase stability field and a decrease of amphibole stability with decreasing pressure. Decompression-dominated ascent trajectories result in liquid lines of descent approaching the metaluminous compositional range observed for typical arc volcanic rocks, while differentiation trends obtained for cooling-dominated trajectories evolve to peraluminous compositions, similar to isobaric liquid lines of descent at elevated pressures. Experiments buffered at RRO provide a closer match with natural calc-alkaline differentiation trends compared to fO2 conditions close to NNO. We conclude that decompression-dominated fractionation at oxidising conditions represents one possible scenario for arc magma differentiation.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Calc-alkaline magmatism is characteristic for active convergent plate margins and is related to the formation and evolution of continental and island arc crust. Calc-alkaline volcanic and plutonic rocks range from basalt/gabbro to intermediate andesite/tonalite to highly differentiated silica-rich rhyolite or granite. Consequently, the calc-alkaline differentiation trend is characterised by a strong enrichment in SiO2 and alkalis and a depletion in MgO and FeO (e.g. Osborn 1962; Miyashiro 1974; Grove and Baker 1984). Despite decades of research, this compositional spread is still a matter of active debate (e.g. Clemens et al. 2011; Keller et al. 2015; Ulmer et al. 2018; Collins et al. 2020). Major, not mutually exclusive, mechanisms controlling arc magma differentiation include (1) mixing of magmas of various compositions (e.g. Tatsumi and Takahashi 2006; Reubi and Blundy 2009; Blatter et al. 2013), (2) assimilation of crustal lithologies by mafic magmas (e.g. DePaolo 1981; Hildreth and Moorbath 1988; Thompson et al. 2002), or (3) crystallisation-driven differentiation of primitive mantle-derived basaltic magmas (e.g. Bowen 1915, 1928; Grove et al. 2003; Nandedkar et al. 2014; Ulmer et al. 2018). Since the fundamental work of Bowen (1928), a large number of studies have been conducted supporting as well as objecting the dominant control of fractional crystallisation on calc-alkaline differentiation trends (e.g. Green and Ringwood 1968; Grove et al. 2003; Ulmer 2007; Turner and Langmuir 2015; Clemens et al. 2021). In detail, the most commonly invoked fractionating mineral phases controlling calc-alkaline differentiation include magnetite (e.g. Osborn 1959), amphibole (e.g. Cawthorn and O'Hara 1976; Foden and Green 1992; Sisson and Grove 1993a; Davidson et al. 2007; Dessimoz et al. 2012; Blatter et al. 2013; Nandedkar et al. 2014; Goltz et al. 2020), or garnet (e.g. Macpherson et al. 2006; Müntener and Ulmer 2006; Tang et al. 2018).
During the last decades, deep and shallow differentiation of parental mafic magmas via crystallisation has been investigated experimentally. A crucial observation of experimental high-pressure liquid lines of descent (0.7–1.2 GPa) established for fractional (Nandedkar et al. 2014; Ulmer et al. 2018) or equilibrium crystallisation (Müntener et al. 2001; Alonso-Perez et al. 2009; Blatter et al. 2013) is the rapid increase of the alumina saturation index ASI (= Al2O3/(CaO + Na2O + K2O)) with ongoing differentiation resulting in peraluminous (ASI > 1) intermediate (andesitic) melt compositions. This general behaviour is the result of extensive clinopyroxene and amphibole crystallisation at high pressures depleting residual liquids efficiently in calcium but to a much lesser extent in alumina. However, the majority of intermediate volcanic and plutonic arc rocks are metaluminous and only highly evolved silica-rich lithologies become weakly peraluminous. On the contrary, liquid lines of descent defined at low pressure (0.2–0.4 GPa) via equilibrium crystallisation (Sisson and Grove 1993a, 1993b; Grove et al. 2003; Blatter et al. 2013) provide a closer match with the compositional trend exhibited by natural rocks and remain metaluminous upon progressive differentiation.
To resolve the open question of the predominant pressure level or crustal depth of crystallisation differentiation, we experimentally investigated the process of polybaric fractional crystallisation, where hydrous basaltic liquids extracted from the mantle differentiate at various levels in the crust (e.g. Grove et al. 2003; Almeev et al. 2013; Melekhova et al. 2015). Primary mantle-derived basaltic magmas buoyantly rise through the upper mantle and initiate differentiation via fractional crystallisation close to the crust–mantle boundary. Derivative evolved basaltic or andesitic liquids subsequently rise to the middle and upper crust and simultaneously continue to fractionate. Here we envisage that crystallisation differentiation occurs over a range of crustal pressures and temperatures generating different residual melt compositions. Since Clapeyron slopes of mineral reactions in calc-alkaline systems are rather different from near-adiabatic ascent trajectories (e.g. Blundy and Cashman 2001), different mineral boundaries are crossed during decompression. Most prominent and crucial for this study is a destabilisation of clinopyroxene at the expense of olivine with decreasing pressure via a displacement of the olivine–clinopyroxene cotectic curve towards melt compositions with higher normative clinopyroxene contents (e.g. Grove and Baker 1984; Grove et al. 1992; Stamper et al. 2014). In addition, decreasing pressure expands the stability field of plagioclase with respect to clinopyroxene and olivine preventing a pronounced enrichment of residual melts in alumina (e.g. Sisson and Grove 1993a; Grove et al. 2003; Alonso-Perez et al. 2009). Water solubility in silicate liquids diminishes with decreasing pressure (e.g. Hamilton et al. 1964) inferring that water activities (aH2O) continuously increase for H2O-undersaturated hydrous arc magmas during decompression. Such a change in aH2O has an additional effect on plagioclase composition favouring the crystallisation of anorthite-rich plagioclase (e.g. Sisson and Grove 1993a). As a consequence of the combined effect of pressure-sensitive changes on phase equilibria, polybaric fractional crystallisation is expected to prevent calc-alkaline liquids to evolve towards peraluminous compositions at low SiO2, closer approaching the natural rock record.
Here we report the results of a set of polybaric fractional crystallisation experiments conducted on hydrous calc-alkaline basalts by varying pressure and temperature concomitantly along the liquid line of descent (LLD). We explored different polybaric fractionation ascent trajectories and conducted a limited number of additional experiments to evaluate the effect of oxygen fugacity (fO2) and initial starting material composition on the resultant liquid lines of descent. We discuss the effect of polybaric fractionation on calc-alkaline magmas and propose a general petrological model for arc magma differentiation.
Methods
General strategy
Fractional crystallisation (FC) was simulated in a stepwise manner following established techniques (Villiger et al. 2004; Nandedkar et al. 2014; Ulmer et al. 2018): for each fractionation step, the chemical composition of the residual liquid (quenched to a homogeneous glass) of the respective experiment is determined by EPMA and a new, chemically corresponding starting material is synthesised employing pure chemicals. This starting material is then used for the subsequent experiment at different pressure–temperature conditions. Experiments were run between 1140 and 870 °C, at pressures ranging from 1.0 to 0.2 GPa. Temperature steps of 30 °C (in a few cases 15 °C) and pressure intervals of 0.2 GPa were employed. The polybaric approach required that pressure and temperature had to be varied simultaneously. However, P–T ascent trajectories of rising magmas through the crust are poorly constrained (e.g. Rutherford 2008; Neave and Maclennan 2020) and, therefore, three main experimental series with different P–T trajectories have been investigated: (1) a hot path where each fractionation was linked to a decompression step simulating an ascent trajectory of 22.5 °C/0.1 GPa; (2) an intermediate path with one additional fractionation step performed under isobaric conditions (30 °C/0.1 GPa), and (3) a cold path where two isobaric fractionation steps were conducted between each decompression step (45 °C/0.1 GPa). An additional fractionation series (hot rk52 path) followed a similar P–T ascent trajectory as the hot path but initiated from a different starting material to test whether the normative clinopyroxene content of the primary starting material exerts a crucial impact on the resultant liquid line of descent during polybaric fractionation. Finally, a hot oxidised path (with an ascent trajectory of 19 °C/0.1 GPa) was explored, where fO2 was buffered close to the Re-ReO2 equilibrium (RRO), while fO2 was constrained close to the Ni-NiO buffer (NNO) for all other series. The P–T ascent trajectories given above were calculated by fitting a line through the first and last experiment of each fractionation series. Assuming an average crustal density of 2800 kg/m3, the hot trajectories (hot, hot rk52, and hot oxidised path) simulate cooling rates of approx. 6–7 °C/km during magma ascent, the intermediate path corresponds to 8 °C/km and the cold path simulates 12 °C/km. Explored P–T trajectories are illustrated in Fig. 1, where fractionation steps are highlighted by an arrow and equilibrium steps are indicated by simple lines. Intermediate equilibrium crystallisation steps were required when less than 10 wt.% of minerals crystallised in the fractionation experiments to promote more extensive crystallisation prior to the execution of the next fractionation step.
Starting materials
Derivative liquids from the fractional crystallisation study at 1.0 GPa by Ulmer et al. (2018) on a primitive high-Mg basalt from the Adamello Batholith (Northern Italy) were used as initial starting materials. Four fractionation series (hot, hot oxidised, intermediate, and cold path) were run on the residual liquid of the run rk54 (1140 °C) exhibiting an xMg of 0.585, where xMg equals the molar ratio of MgO/(FeOtot + MgO), with all iron assumed to be ferrous. The hot rk52 path was performed on the melt formed in experiment rk52 (1170 °C, xMg of 0.638). Both compositions were derived from a primary high-Mg basalt (RC158c) via fractionation of the mineral phase assemblage olivine, clinopyroxene, and spinel. We slightly modified the liquid compositions reported by Ulmer et al. (2018) by adding P2O5 as a chemical component (0.16 wt.% for rk54 and 0.13 wt.% for rk52) and decreasing H2O contents to 3.50 wt.% (rk54) and 2.96 wt.% (rk52), respectively. For each fractionation step, FeO and Na2O (and in some cases also K2O and P2O5) contents of new starting materials were re-calculated from compositional data of experimental liquids and mineral phases employing phase proportions established by mass balance calculations to account for potential Fe-loss and alkali migration during EPMA analysis. Fe2+/Fe3+ ratios of starting materials were adjusted to values corresponding to the NNO or RRO oxygen buffers using the algorithm by Kress and Carmichael (1991). Water contents of starting materials were calculated by mass balance treating water as a perfectly incompatible compound in nominally anhydrous minerals and assuming an empirical H2O content of 2 wt.% for amphibole. For low-pressure experiments (0.2 and 0.4 GPa), water contents of new starting materials were compared with expected water contents at saturation for respective experimental P–T conditions calculated by MagmaSat (Ghiorso and Gualda 2015) to avoid significant amounts (several wt.%) of excess free water in the experimental charges influencing the silicate-fluid partitioning behaviour of some lithophile elements (e.g. Na and K). However, for the last starting material of the intermediate path (SM-FM160), the calculated H2O content via mass balance (8.1 wt.%) was distinctly higher than the maximum H2O solubility at target experimental run conditions (900 °C and 0.2 GPa) inferred from MagmaSat (5.4 wt.%) and, thus, the nominal water content of this starting material was lowered to 6.0 wt.%. For each fractionation step, starting materials were prepared by accurately weighing fired (1000 °C) or dried (110–220 °C) oxides (SiO2, TiO2, Al2O3, Fe2O3, MnO, and MgO), hydroxides (AlOOH and Al(OH)3), phosphates (apatite), and silicates (CaSiO3, Fe2SiO4, Na2SiO3, and K-silicate). In addition, 2 wt.% of diopside glass, doped with 27 or 31 trace elements (LILE, HFSE, REE, transition metals, U, and Th) in the concentration of 2000 ppm each (1000 ppm for U and Th), were added to the starting materials resulting in 40 ppm, respectively 20 ppm for U and Th, in the final mixture. Trace elements were added to the starting materials to explore trace element partitioning during polybaric fractional crystallisation. Weighed-in compounds were homogenised under ethanol in an agate mortar for a minimum of two hours, and final powders were stored at 110 °C before capsule preparation. Major element compositions of starting materials (in wt.%) are provided in Table 1 and in the Electronic Supplementary Material ESM 1.
Capsule design and capsule preparation
A double capsule technique representing a modification and combination of the designs by Kaegi et al. (2005) and Matjuschkin et al. (2015) was employed, where two inner capsules (outer diameter, OD of 2.3 mm) were placed in an outer capsule (OD of 4.0 mm). The first inner capsule was prepared from Au90Pd10 or Au100 (below 1000 °C) and contained the experimental charge. The second one was made of Pt and encased the solid-state buffer assemblage used to control fO2. A schematic sketch of the utilised capsule design is presented in the Electronic Supplementary Material ESM 2. NNO buffer mixtures were prepared from Ni metal and Ni(OH)2 powder in the molar proportions of 70:30, while RRO assemblages were made of Re metal and ReO2 powder with a ratio of 60:40. Higher metal proportions were used to account for potential alloying of Ni or Re metal with the Pt capsule walls and still warrant optimal fO2 buffering capability of the metal–oxide pairs. For RRO buffer capsules, an aliquot of deionised water was added to the metal–oxide powder, while for the NNO mixture H2O was introduced via nickel-hydroxide. Finally, both single welded-shut inner capsules plus the same experimental starting material acting as spacer material were placed in the outer capsule (made of the same noble metal as the inner experimental capsule), which was subsequently closed by arc welding.
Experimental procedure
Experiments at 1.0, 0.8, and 0.6 GPa were run in an end-loaded 14-mm bore Boyd and England-type piston cylinder apparatus at ETH Zürich. NaCl–Pyrex–graphite–MgO assemblies were utilised, and a friction correction of 5% was applied to the nominal pressure. Capsules were placed in the hotspot of the assembly, whose position was estimated using the numerical algorithm of Hernlund et al. (2006). Temperature was measured with a B-type thermocouple (Pt94Rh6/Pt70Rh30) with an estimated accuracy of ± 10 °C. No correction for the pressure effect on the electromotive force (e.m.f.) was applied. Numerical modelling revealed that hotspot temperatures were 7–16 °C higher than the effective thermocouple reading. Oil pressure was automatically controlled with an in-house built worm-gear-type pressure control system with a tolerance window of 0.5 bar oil pressure (≈ 40 MPa). After capsule loading, assemblies were initially pressurised to approximately 50 bar oil pressure (≈ 0.4 GPa) at ambient temperature and then heated with a continuous rate of 40 °C/min to final run temperatures. Pressure was slowly increased when temperature exceeded 500 °C (softening point of Pyrex glass), but care was taken to reach final pressure before the attainment of the run temperature. Experimental run times varied from 6 to 73 h with longer durations at lower temperatures. Finally, experiments were quenched by switching off the power supply resulting in cooling rates exceeding 100 °C/s.
Experiments at 0.4 GPa were performed in a 22-mm bore non-end-loaded Johannes-type piston cylinder at ETH Zürich, which was specifically calibrated for low-pressure conditions employing the NaCl melting curve (Clark 1959) in combination with the falling sphere technique (e.g. Baker 2004). Run protocol and control of pressure and temperature were identical to experiments run at higher pressures in the 14-mm bore Boyd and England-type piston cylinder, with the exception that a slightly different NaCl–Pyrex–graphite–MgO assembly was utilised (see Electronic Supplementary Material ESM 2). Thereby, capsules were additionally embedded in Pyrex glass powder to ensure homogenous pressure distribution. After loading, experiments were pressurised to approximately 0.15 GPa, and subsequent heating procedure was identical to the end-loaded piston cylinder approach. Cooling rates during quenching were slightly lower (50–100 °C/s) compared to the 14-mm assembly used for the experiments at higher pressures due to the larger volume of the 22-mm assembly.
Experiments at 0.2 GPa were run in externally heated Molybdenum–Hafnium–Carbide (MHC) pressure vessels at ETH Zürich. A gas mixture of Ar-CH4 was used as pressurising medium, where methane acted as a reactant component buffering hydrogen fugacity and, thus, fO2 in the run charges. Methane contents of the gas mixture were adjusted to maintain fO2 conditions close to the NNO or RRO buffer. General run procedure was as follows: after capsule loading, vessels were first filled with appropriate amounts of methane and subsequently pressurised with argon to levels corresponding to roughly half of the final run pressure. Then heating was started, and gas pressure increased simultaneously with temperature due to thermal expansion. After run temperature was reached, pressure was adjusted manually to the final target level of 200 MPa. During experiments, pressure was monitored using a pressure sensor with an uncertainty of 0.5% and manually controlled at 200 MPa with a maximum deviation of ± 2 MPa. Temperature was controlled with a K-type thermocouple, which was positioned outside of the MHC vessel above the approximate capsule position. Temperature recorded with this external thermocouple was calibrated against effective experimental temperature inside the bomb every time a new vessel was installed. Generally, internal and external temperature readings exhibit a linear relationship, and 2σ errors on established temperature calibrations were below 10 °C. During experiments, vessels were oriented with an inclination of 10° to ensure the development of a stable temperature profile. All experiments run in the MHC pressure vessels were equilibrated at run conditions for 72 h. Quenching was attained by tilting the furnace by 90° into a vertical position forcing the capsule to fall to the cold end of the vessel, resulting in quenching rates exceeding 100 °C/s. For one experiment (FM146), temperature cycling (e.g. Mills and Glazner 2013) was performed to promote the formation of melt pools large enough for reliable analysis. Thereby, temperature was cycled with ± 10 °C around the target equilibrium temperature (960 °C) for half of the intended run duration. Employed heating and cooling rates during temperature cycling were 0.5 °C/min and temperature plateaus were hold for 40 min. After this initial cycling phase, temperature was adjusted to 960 °C and kept for the remaining time of the experiment.
Sample preparation and analytical techniques
Recovered capsules were embedded in epoxy-resin, opened with grinding paper to expose a longitudinal cross section, and subsequently polished using diamond suspensions with finest grades of 1 μm. Polished charges were inspected under an optical microscope for capsule coherence and any peculiar textures. In addition, buffer capsules were checked for the presence of metal and oxide phases to verify the fO2 buffering capability of the buffer assemblage mixture throughout the entire run duration. Subsequently, specimens were coated with 20 nm of carbon and analysed with a JEOL JSM-6390 Scanning Electron Microscope at ETH Zürich. Runs were checked for general appearance, and high-quality back-scatter electron (BSE) images were acquired. First quantitative compositional data of glasses and minerals were obtained with a standardised Thermo Fisher NORAN NSS7 Energy-Dispersive Spectroscopic system with a 30 mm2 Silicon-drift detector (SDD) (SEM-EDS). Acceleration voltage for imaging and measurements was set to 15 kV. In a final step, major phases (glass, olivine, hercynitic spinel, plagioclase, ortho- and clinopyroxene, amphibole, biotite, magnetite, ilmenite, and apatite) were analysed with two JEOL Electron Probe Micro Analysers (EPMA) at ETH Zürich. Approximately half of the experiments presented in this project were measured with a JEOL JXA 8200 Superprobe, while a JEOL JXA 8230 Superprobe was used for the second half. The same set of oxide and silicate standards was utilised for both devices, and a comparison of analytical results revealed no significant differences. An acceleration voltage of 15 kV was utilised for analysis. Sodium and potassium were measured first to avoid extensive alkali migration. Hydrous glasses were analysed with a beam current of 7 nA and a beam diameter of 20 μm. In case residual melt pools were too small, beam currents were reduced to 4 or 2 nA and spot sizes to 10 or 5 μm. Plagioclase, biotite, and apatite were analysed with a focussed beam and a current of 10 nA, while the other phases (pyroxenes, amphibole, olivine, spinel, magnetite, and ilmenite) were measured with a focussed beam and a current of 20 nA. For fO2 reconstruction, iron contents of AuPd capsule material pieces were measured with a beam current of 20 nA and pure metal standards for Au and Pd and wustite for Fe.
Results
An overview of experimental run conditions is given in Table 2, including employed starting materials, capsule materials, stable phase assemblages, phase proportions, relative Fe-losses, estimated melt water contents, and calculated minimum fO2 conditions based on water activity. These data are also supplied in an electronic form in the Electronic Supplementary Material ESM 3.
General remarks
All successful experiments consisted of residual liquid quenched to a homogenous glass and a variety of mineral phases, namely, olivine (ol), clinopyroxene (cpx), orthopyroxene (opx), plagioclase (plag), hercynitic spinel (sp), amphibole (amph), magnetite (mt), biotite (bt), ilmenite (ilm), and apatite (ap). Although most experiments were nominally H2O-undersaturated, fluid bubbles were observed in all runs, indicating that fluid-saturated conditions were met. Pure H2O-saturation was reached by a few experiments performed at low temperatures (< 1000 °C) and low pressures (0.2 or 0.4 GPa, compare Table 2). The occurrence of a free fluid phase in the H2O-undersaturated experiments is most probably the consequence of the presence of additional fluid components in the charges with low solubilities in silicate liquids. One likely candidate is CO2 which was introduced via absorption by the fine-grained synthetic starting material powders (Ulmer et al. 2018). Although starting materials were stored at 110 °C before capsule loading and attention was paid to process new starting materials quickly after synthesis, the presence of CO2 in the final charge could not be avoided. A further likely contaminant fluid component is N2 that was incorporated from the surrounding air during capsule preparation. However, results from a cross-check experiment on a pre-vitrified starting material (± free of CO2 and N2) infer that the presence of small amounts of these additional volatile compounds had no discernible impact on phase equilibria and compositions of residual melts and coexisting minerals (Marxer 2021).
A prerequisite for successful experimentation is the maintenance of a chemically closed system. Two compounds that potentially escape and/or contaminate the experimental charge at run conditions are iron and hydrogen. We quantified iron loss for each run via mass balance regression, treating all iron alloying with the capsule as an additional phase for calculations. In addition, for runs containing an Fe–Ti–oxide phase (complicating mass balance calculations), proportions of ilmenite or magnetite were independently determined via image processing on BSE images of entire charges employing the software ImageJ. First, the capsule material as well all voids and cracks were manually removed via blackening. Subsequently, oxide proportions were estimated assuming that area fractions equal volume fractions. Finally, volume proportions were converted to mass fractions employing calculated densities of all coexisting phases. Densities of residual melts were established using the algorithm of Lange and Carmichael (1987), while densities of mineral phases were derived employing a Birch–Murnaghan equation of state and an own compilation of required thermodynamic parameters. Fe-losses were finally recalculated via mass balance employing oxide fractions obtained by image processing. For two experiments (FM146 and FM121), established iron losses were negative indicative of iron gain, illustrating the general drawback of image analysis procedures as the underlying assumption of homogeneous distribution of oxide phases in the experimental charge is most probably not entirely correct. Magnetite tends to preferentially nucleate on capsule walls, and previous studies reported accumulation of magnetite crystals on volatile bubbles by floating (e.g. Knipping et al. 2019). Accounting for this uncertainty by assuming a relative error of 20% on Fe–Ti–oxide fractions results in maximum estimated Fe-loss close to zero. Consequently, we assumed that Fe-loss was negligible for these runs and report Fe–Ti–oxide proportions estimated via mass balance (Table 2). This is consistent with the relatively low temperatures of these runs (< 1000 °C) and the use of pure Au capsules, representing well-known experimental conditions to minimise iron loss (e.g. Barr and Grove 2010).
Generally, established Fe-losses were below 15.5% (relative to the FeO content of the employed starting material) for all fractionation experiments. However, especially for runs performed at high temperatures (≥ 1020 °C) in Au90Pd10 capsules, loss of iron was significant due to an increasing maximum solubility of iron in AuPd alloys with increasing temperature and palladium content (Barr and Grove 2010). Furthermore, noble metal capsules are permeable for hydrogen under experimental P–T conditions leading to either H-gain or H-loss via diffusion during run conduction (e.g. Eugster 1957; Eugster and Wones 1962). The solid buffer assemblage (NNO or RRO) imposes an intrinsic hydrogen fugacity (fH2) which equilibrates throughout the entire outer capsule thereby constraining a specific fO2 in the second inner capsule containing the experimental charge. Consequently, hydrogen loss is expected to be negligible for this study as long as the solid-state buffer was capable of maintaining a roughly constant fH2 throughout the entire outer capsule. Generally, Fe-loss to the inner capsule results in the formation of free oxygen which either oxidises ferrous iron to ferric iron or reacts with the hydrogen supplied from the fO2 buffer to H2O. Consequently, pronounced iron loss can lead to an increase of water contents of experimental charges as long as fH2 is buffered. However, we infer that due to the elevated water contents of the employed starting materials of this study (> 3.5 wt.%) the amount of additional H2O formed is generally negligible, since the highest estimated iron loss (15.5%) could only have supplied a maximum of 0.35 wt.% of additional water.
Water contents of residual melts were quantified for few selected runs via Raman spectroscopy. Analytical procedures and results are presented in the Electronic Supplementary Material ESM 2. However, consistent phase assemblages and chemical trends of experimental runs indicate that H2O contents evolve systematically along the LLD as inferred by mass balance considerations. This is supported by a continuous increase of glass water contents estimated via the EPMA "by-difference" method (e.g. Anderson 1973; Blundy and Cashman 2008; Hughes et al. 2019) with decreasing temperature. However, H2O contents established via the "by-difference" approach are approximately 2 wt.% higher compared to mass balance calculations, which we assign to a matrix effect during EPMA analysis due to the standardisation on mineral phases. For experiments containing plagioclase we utilised the Waters and Lange (2015) plagioclase-melt hygrometer to calculate melt water contents that match mass balance results at concentrations below 6.0 wt.% H2O to within 10%. At higher nominal H2O contents, this disparity increases to 1.0–3.0 wt.% pointing towards limitations of the Waters and Lange (2015) algorithm at elevated melt water contents (and pressures).
Oxygen fugacity
Most runs were H2O-undersaturated and, thus, the fO2 conditions in the run capsules were displaced to lower values compared to the nominal buffer equilibria (NNO or RRO) by the factor 2*log(aH2O) (where aH2O corresponds to the activity of water in the experimental charge). Only, when experimental runs reached water-saturation (aH2O = 1), which was the case for some low-temperature and low-pressure runs, buffered redox conditions corresponded to NNO or RRO. Consequently, we estimated minimum fO2 of our experiments employing the Burnham water solubility and activity model (e.g. Burnham and Davis 1974; Burnham 1994) following the procedure described in Holloway and Blank (1994). For each run, water contents of recovered residual glasses were calculated via mass balance using mineral phase proportions and H2O concentrations of employed starting materials. Water activities were subsequently calculated employing the Burnham algorithm. Melt compositional parameters and derived water activities are summarised in the Electronic Supplementary Material ESM 4. However, the Burnham algorithm tends to underestimate H2O solubility at higher pressures (e.g. Holtz et al. 1995; Botcharnikov et al. 2005) resulting in a slight overestimation of aH2O. The water activities were then used to estimate experimental redox conditions. Calculated fO2 values are reported relative to NNO (Table 2). They represent minimum conditions since failure of the inner buffer capsule would result in a slight increase in fO2.
The attainment of targeted experimental redox conditions was verified with several different, independent approaches. Figure 2 summarises fO2 conditions expressed relative to the NNO equilibrium. For a limited number of experiments, fO2 conditions were reconstructed via the solubility of Fe in AuPd alloys employing the solution model of Barr and Grove (2010). For this purpose, iron contents of small noble metal pieces (Au90Pd10) dispersed in the experimental charges were measured by EPMA. For some runs, a rather large variability of alloy compositions (and resultant redox conditions) was observed. Therefore, we only report ranges of reconstructed fO2. The lowest fO2 corresponds to the highest measured iron content, and vice versa. The large spread of AuPdFe compositions is mainly related to the uncertainty on the attainment of equilibrium between silicate melt and noble capsule metal. Consequently, we infer that the lower ends of the fO2 range represent the most realistic values for experimental fO2 conditions. In general, fO2 conditions vary between NNO-1 and NNO+1 with a majority plotting in a narrower range of NNO±0.5. When only considering minimum values, the range of fO2 conditions narrows to NNO-1 to NNO, in agreement with minimum redox conditions of experimental charges inferred from water activities and redox buffers (Table 2). Measured alloy compositions, calculated fO2 conditions, and estimated errors are reported in the Electronic Supplementary Material ESM 5. In addition, experimental fO2 conditions were estimated for amphibole-bearing charges employing the thermobarometric algorithms of Ridolfi et al. (2010) (R10) and Ridolfi and Renzulli (2012) (RR12). The R10 model results in consistently lower fO2 than the RR12 model. Results from the R10 formulation vary between NNO-0.1 and NNO+1.1, while values calculated with RR12 range from NNO+1.0 to NNO+2.4. No consistent trends of calculated fO2 with experimental temperature or pressure were observed and, thus, only ranges of established fO2 are reported (Fig. 2). In agreement with Erdmann et al. (2014), we infer that the RR12 algorithm tends to overestimate fO2 conditions and conclude that redox conditions determined with the R10 model are more realistic. Finally, in one experiment (FM116, 960 °C and 0.6 GPa), magnetite and ilmenite coexist and, thus, Fe–Ti–oxide oxybarometry was applied. The algorithm of Ghiorso and Evans (2008) resulted an Fe–Ti exchange temperature of 954 °C and a logfO2 of NNO-0.25. Both values agree within error with experimental conditions, confirming that the experiments were buffered at redox conditions close to NNO.
Run appearance
The step-wise experimental approach to fractional crystallisation generated high residual melt fractions exceeding 40–50 wt.% (in most cases > 70 wt.%) facilitating the analysis of hydrous glasses. For most experiments, mineral phases were homogeneously distributed over exposed capsule sections. In few cases, weak gradients in phase abundances (e.g. zones with higher melt fractions) were observed and attributed to small temperature gradients (< 10 °C over the length of entire outer capsules). Additionally, glasses and mineral phases were analysed throughout, and no systematic compositional variations were observed. The employment of different experimental techniques and apparatus for the polybaric fractionation approach resulted in a distinct textural variability of recovered charges, which is described in detail in the following paragraphs and illustrated in Fig. 3.
In general, the formation of quench phases (e.g. plagioclase, clinopyroxene, amphibole, or biotite) was of minor extent in runs performed in the 14-mm Boyd and England-type piston cylinder (0.8 and 0.6 GPa), slightly more extensive in the experiments run in the 22-mm non-end-loaded Johannes-type piston cylinder (due to the slower quenching rates), and completely absent for experiments conducted at 0.2 GPa in the MHC pressure vessels. Quench crystallisation was either observed as overgrowth rims on stable mineral phases (e.g. high-albite plagioclase rims or clinopyroxene/amphibole overgrowth on equilibrium clinopyroxene) or direct nucleation of new crystals from the groundmass glass (biotite laths). Relics of unreacted starting material are almost entirely absent except in run FM164 where Al2O3 relics were identified as small inclusions in plagioclase clusters. Olivine was equant and often exhibited rounded shapes (Fig. 3a, b and e), which we interpret as a result of crystallisation kinetics of olivine in magmatic experiments, where olivine generally tends to crystallise extensively during the initial phase of an experiment, while the nucleation and growth of other phases are retarded. As soon as coexisting stable mineral phases start crystallising, olivine composition and modal abundance re-adapt to changing melt composition via partial resorption to approach final equilibrium. Clinopyroxene was mostly small and equant (< 10 µm) and sometimes exhibited bright cores with low Al contents, which we interpret as metastable cores formed during nucleation (Fig. 3a). Therefore, care was taken to avoid such cores during EPMA analysis. Extending run duration resulted in successful reduction of the abundance of these low-Al cores. In two experiments (FM93 and FM146) sector zoned clinopyroxenes (Fig. 3f), were identified, a feature that has previously been reported in experimental studies (e.g. Sisson and Grove 1993a; Ulmer et al. 2018) and natural rocks (e.g. Hurlimann et al. 2016). We infer that the formation of sector zoning is a result of rapid crystal growth close to the upper stability limit of clinopyroxene favouring crystallisation over nucleation (Schwandt and Mckay 2006). For run FM146, clinopyroxene sector zoning was likely promoted by temperature cycling during the experiment. Plagioclase generally formed small subhedral equant or lath-shaped crystals (< 10 µm). Zoning of single crystals could not be observed. At 0.2 GPa, plagioclase was distinctively smaller (< 5 µm) than at higher pressures, resulting in finely dispersed plagioclase in the groundmass glass (Fig. 3e, f). One reason for these specific textures is the pronounced oversaturation in plagioclase at low pressures resulting in rapid nucleation when equilibration P–T conditions are reached. Hercynitic spinel formed small, euhedral crystals (< 5 µm), which were sometimes difficult to identify in BSE images due to grey-scale levels overlapping with clinopyroxene. Amphibole was idiomorphic (Fig. 3c, d), and a decrease of grain sizes with decreasing temperature (from around 100 to 10 µm) was observed. This variation in crystal size can be explained by a change of the nucleation vs crystallisation rates. At high temperatures, close to its stability limit, growth of amphibole is favoured, while at lower temperatures nucleation dominates. This interpretation is supported by the presence of melt and mineral inclusions in amphibole of run FM129, indicating rapid crystal growth. Magnetite varied in size (< 5–30 µm) and revealed near-perfect cubic crystal habit for most runs, sometimes accompanied by slightly rounded shapes. In run FM146, magnetite contained some melt and mineral inclusions pointing towards delayed nucleation followed by rapid crystallisation (Fig. 3f). Ilmenite was typically rather small (< 5–10 µm) and of elongated shape, occasionally forming crystal clusters. Orthopyroxene was only observed in a single experiment (FM164) and crystallised as relatively large idiomorphic prisms (up to 200 µm length) containing numerous inclusions. Weak sector zonation could be observed on BSE images, which was confirmed by compositional data established by SEM-EDS and EPMA. Biotite crystallised in run FM145 (Fig. 3d) formed idiomorphic platelets (~ 20 µm), while apatite morphology differed between the two runs where it was present (short prismatic in FM145 and tiny needles in FM164).
Approach to equilibrium
The following considerations imply that chemical equilibrium was approached to a sufficient level in the polybaric fractional crystallisation experiments: (1) High residual melt fractions of individual experiments (> 50–70 wt.%) facilitated the attainment of chemical equilibrium between different mineral phases and silicate liquid. (2) Run textures do not exhibit signs of disequilibrium. Mineral phases were predominantly idiomorphic and devoid of significant chemical zonation. The general absence of relics from unreacted starting material further supports attainment of equilibrium. (3) Quenched experimental liquids were homogenous. Minor variations of reported melt compositions can be related to analytical difficulties (alkali migration) or overlap of WDS signals of adjacent crystals due to the formation of small residual melt pools. Similarly, mineral phases show minor chemical variability in experimental charges and both melt and mineral compositions define smooth and consistent trends along the liquid lines of descent. (4) Fe–Mg distribution coefficients between mafic minerals (olivine, clinopyroxene, amphibole) and silicate melt describe systematic variations upon differentiation. Fe/Mg ratios of experimental olivine exhibit a non-linear increase with increasing (Fe/Mg)melt (Fig. 4a). The non-linear trend between olivine and melt compositions indicates that distribution coefficients vary with changing experimental conditions. A general decrease of equilibration temperature can be observed along the curved trend with steeper slopes (= higher individual Fe–Mg KD’s) at lower temperatures. Blundy et al. (2020) showed that olivine Fe–Mg KD’s vary as a function of forsterite contents, with a maximum KD at Fo50. Consequently, the observed non-linear trend of decreasing Fe/Mg ratios is consistent with the decrease of olivine forsterite contents of our experiments with decreasing temperature (Fig. 8). Only the 990 °C run of the hot oxidised path falls off this general trend with a KD of 0.16, which is a result of the oxidising fO2 conditions of this experiment (≈ RRO) and the significantly higher Fe3+ content in the melt phase. Amphibole-liquid Fe–Mg distribution is illustrated in Fig. 4b. Except for the 930 °C run of the cold path (FM121), (Fe/Mg) ratios of amphiboles and residual melt display a linear trend with a fitted mean Fe–Mg KD of 0.334 ± 0.005. This distribution coefficient is in good accordance with the value of 0.32 from Grove et al. (2003), falls in the range of 0.30–0.38 established by Sisson and Grove (1993a), and agrees with values between 0.35 and 0.40 observed by Martel et al. (1999). The calculated KD of run FM121 (0.629 ± 0.037) is almost twice the fitted Fe–Mg KD of 0.334 ± 0.005. This run crystallised high proportions of magnetite, which could be an indication that fO2 might have been significantly higher than expected (>> NNO), although no indications of fO2 buffer failure were noticed. Enhanced incorporation of ferric iron in amphibole combined with abundant magnetite crystallisation could explain the distinctly higher Fe–Mg KD. Alternatively, the early saturation of amphibole and the delayed onset of magnetite crystallisation in the experiment circumvented a final equilibration in Fe–Mg exchange between amphibole and residual liquid. Thus, the (Fe/Mg) ratio of amphibole rather represents the equilibrium state prior to magnetite saturation, where the melt contained significantly higher amounts of iron and the remaining run duration after the onset of magnetite crystallisation was apparently too short to enable a final re-equilibration in Fe–Mg between already crystallised amphibole and residual melt. For clinopyroxene, a mean Fe–Mg KD of 0.276 ± 0.005 was established by weighted linear fitting of data points of experiments where fO2 was buffered between NNO-1 and NNO. This value broadly coincides with 0.23 for a hydrous basalt (Sisson and Grove 1993a), 0.24 for a high-Mg andesite (Grove et al. 2003), and 0.25 for andesites (Martel et al. 1999). Clinopyroxenes from the hot oxidised path exhibit higher Fe–Mg KD’s ranging from 0.32 to 0.51 consistent with higher fO2 (~ RRO) and an enhanced incorporation of ferric iron into clinopyroxene via ferri-tschermaks and acmite components.
Phase relations and phase proportions
Stable phase assemblages are illustrated in Fig. 5 and reported in Table 2. The hot, intermediate, and cold path are illustrated in Fig. 5a. The hot path represents the starting point where the primary starting material rk54 is saturated with clinopyroxene and spinel at 1140 °C and 1.0 GPa. A subsequent decrease in pressure to 0.8 GPa leads to the destabilisation of these two phases and appearance of olivine (1110 °C). With decreasing temperature, clinopyroxene joins olivine at 1080 °C. A next decompression step to 0.6 GPa promotes plagioclase crystallisation at 1050 °C. From 0.6 to 0.4 GPa, only olivine remains stable at 1020 °C. After 30 °C of isobaric cooling, amphibole, plagioclase, and clinopyroxene start crystallising. Finally, a decrease of pressure from 0.4 to 0.2 GPa results in the disappearance of amphibole and magnetite saturation at 960 °C. The intermediate path branches off from the hot path at 1080 °C via an isobaric cooling step to 1050 °C resulting in the crystallisation of olivine, clinopyroxene and spinel. Subsequent decompression to 0.6 GPa and 1020 °C saturates the liquid in plagioclase, while clinopyroxene and spinel disappear. At 990 °C, amphibole joins the stable phase assemblage. Upon a next decompression step to 0.4 GPa and 960 °C olivine destabilises and with further cooling magnetite starts crystallising at 930 °C. The last pressure and temperature decrease to 0.2 GPa and 900 °C stabilises olivine, orthopyroxene, and apatite at the expense of amphibole. The cold path leaves the intermediate path at 1050 °C and 0.8 GPa. Plagioclase crystallises at 1020 °C. From 0.8 to 0.6 GPa (and 1020 to 990 °C), clinopyroxene and spinel destabilise resulting in a "troctolitic" assemblage (plagioclase + olivine). With progressive cooling, magnetite and amphibole join the solid phase assemblage at 960 °C (together with trace amounts of ilmenite) while olivine and ilmenite disappear at 930 °C. The subsequent decompression step to 0.4 GPa (and 900 °C) stabilises ilmenite at the expense of magnetite. The final isobaric fractionation step to 870 °C results in the crystallisation of biotite and apatite.
The hot oxidised and hot rk52 path follow similar P–T ascent trajectories. However, due to differences in starting material composition and fO2, phase equilibria upon cooling and ascent differ (Fig. 5b). The first three experiments of the hot oxidised path (until 1080 °C and 0.8 GPa) are identical with the hot path. Upon decompression to 0.6 GPa and cooling to 1050 °C plagioclase and hercynitic spinel crystallise. At 0.4 GPa and 1020 °C, olivine disappears, but reappears at 0.2 GPa and 990 °C, where hercynitic spinel is replaced by magnetite. The initial starting material of the hot rk52 path is in equilibrium with olivine and clinopyroxene at 1170 °C and 1.0 GPa (Ulmer et al. 2018). This mineral assemblage is not changed by decompression to 0.8 GPa and a temperature decrease of 60 °C. The subsequent decrease to 0.6 GPa leads to the destabilisation of clinopyroxene at 1080 °C. Plagioclase joins the phase assemblage upon further isobaric cooling to 1050 °C. Finally, at 0.4 GPa and 1020 °C, the stable mineral assemblage (ol + cpx + plag) is identical to the previous fractionation experiment at 1050 °C. In summary, for several polybaric fractionation paths, decompression and cooling stabilised olivine at the expense of clinopyroxene, while plagioclase crystallised at higher temperatures at lower pressures, and amphibole, although present at intermediate pressures (0.4–0.6 GPa), is destabilised during final decompression to 0.2 GPa.
Phase proportions of experimental charges, calculated via mass balance regression, are reported in Table 2 and illustrated in Fig. 6. The left column (Fig. 6a, c, e, g, i) corresponds to instantaneous solid compositions (ISC) depicting the modal proportions of minerals crystallising in individual experiments. The right column (Fig. 6b, d, f, h, j) represents total solid compositions (TSC), where phase proportions are expressed relative to the initial starting material (rk54 or rk52), corresponding to the total accumulated amounts of minerals fractionated along the liquid line of descent. TSC fractions were calculated as follows: TSCn = TSCn-1 + ISCn * AMFn-1, where n corresponds to the experiment of interest, n-1 to the preceding fractionation experiment, and AMF to the absolute residual melt fraction expressed relative to the initial starting material. For most experiments, instantaneous solid compositions are relatively constant and below 30 wt.%. A distinct decrease (more than 10 wt.%) is often related to a decompression step of 0.2 GPa, due to a shift of phase equilibria with decreasing pressure. This is further enhanced for water-undersaturated experiments because decompression decreases volatile solubility in silicate melts, and, thus, results in an increase of water activity in the experimental charge. The experiments at 0.2 GPa of the hot and hot oxidised path exhibit a strong increase in crystallinity. We propose two possible effects explaining this observation: (1) decompression leads to water-saturated conditions and crystallisation is mainly driven by cooling, and, (2) the negative Clapeyron slope of plagioclase and magnetite results in extensive crystallisation of these phases.
In contrast, accumulated crystal fractions of the intermediate and cold path display continuously increasing mineral proportions with progressive cooling. A comparison of relative mineral proportions between the five different fractionation paths reveals that phase relationships between olivine, clinopyroxene, and plagioclase are crucial. For the cooling-dominated ascent path (cold path) the extent of clinopyroxene crystallisation is higher with respect to the more decompression-controlled P–T trajectory (hot path). Relative proportions of crystallised plagioclase and olivine are slightly higher for the latter fractionation trend. For the hot oxidised path, higher amounts of oxides (hercynitic spinel or magnetite) formed due to distinctly more oxidising fO2 conditions, stabilising Fe3+-bearing mineral phases. The hot rk52 path fractionated almost double the amount of crystals compared to the hot path (44 wt.% vs 24 wt.%) at 1020 °C. This is an expression of the more primitive character of the rk52 starting material promoting extensive crystallisation with ongoing cooling.
Compositions of major phases
Compositions of major experimental phases (residual melts and coexisting minerals) were measured by EPMA and are reported in Table 3 and the Electronic Supplementary Material ESM 6.
Residual liquids
The evolution of major and minor oxide compositions of residual liquids with decreasing temperature (on an anhydrous base) is illustrated in Fig. 7. Liquid lines of descent follow calc-alkaline differentiation trends with increasing silica and alkali contents accompanied by a decrease of other compounds (e.g. MgO, FeO, and CaO), thereby evolving from basaltic to dacitic compositions. However, some distinct features can be identified, which are either valid for all five fractional crystallisation paths or only affect individual trajectories. Since several fractionation series exhibit similar evolution trends, the following umbrella terms are used in the remainder of this manuscript to facilitate the description of the observed patterns: the hot and hot oxidised path are called decompression-dominated, while the intermediate and cold path are referred to as cooling-dominated.
Silica contents increase with decreasing temperature from 48 to 67 wt.% (Fig. 7a). In detail, this trend of silica enrichment can be divided in a high-temperature interval with only a minor increase in SiO2, followed by a low-temperature stage with pronounced silica enrichment over a narrow temperature range. The onset of SiO2 enrichment is shifted to higher temperatures (990–1020 °C) for the decompression-dominated series compared to the cooling-dominated ones (960–990 °C) because of phase equilibria control. At high temperatures, the chemical evolution of residual liquids is governed by fractionation of olivine, clinopyroxene, and ± plagioclase. At lower temperatures, crystallisation of amphibole, anorthite-rich plagioclase, and an Fe–Ti–oxide results in a rapid increase of silica. Al2O3 reveals distinct bell-shaped trends with an initial increase followed by a plateau and a subsequent decrease (Fig. 7c). For the decompression-dominated series, maximum levels of Al2O3 are lower (< 20.0 wt.%) than for the cooling-dominated trajectories (> 20.0 wt.%), consistent with enhanced plagioclase stability at lower pressures. Similar to alumina, TiO2 exhibits an initial enrichment followed by a rapid decrease with variable inflection points (i.e. temperatures) for the individual FC series (Fig. 7b). These inflexion temperatures can be related to the onset of amphibole crystallisation. With decreasing temperature, saturation in ilmenite or Ti-bearing magnetite further depletes the residual melt in titanium. The hot oxidised path does not exhibit a late-stage decrease in TiO2, although magnetite saturation was reached. This feature is explained by low TiO2 (~ 2.9 wt.%) but high ferric iron contents in magnetite and the absence of amphibole in the crystallisation sequence.
FeO contents of residual liquids reveal a plateau with significant variability at high temperatures and a pronounced decrease initiating between 990 and 930 °C related to the saturation of Fe–Ti–oxides (Fig. 7d). MnO exhibits evolution trends mirroring iron with an initial increase, followed by a decrease when Fe–Ti–oxide saturation is reached (Fig. 7e). A linear decrease of MgO contents of residual liquids is observed with ongoing cooling (Fig. 7f) for all five FC paths. CaO contents exhibit an initial plateau followed by a continuous decrease with progressive cooling with inflexion points corresponding to clinopyroxene saturation (Fig. 7g). In detail, the cold path exhibits an almost linear trend, as clinopyroxene stability is enhanced at higher pressures, whereas the intermediate and hot path reveal only a minor CaO decrease from 1050 to 990 °C which is related to the decompression steps resulting in a destabilisation of clinopyroxene and a re-appearance of olivine. The rapid decrease of CaO observed for the last temperature step of the hot, hot oxidised, and intermediate path is related to the final decompression to 0.2 GPa coinciding with enhanced plagioclase crystallisation (c.f. Figure 6). The hot rk52 path reveals higher CaO concentrations during early stages of differentiation related to higher initial CaO contents, but approaches the other fractionation series at 1020 °C.
Na2O and K2O contents of experimental liquids define similar increasing trends with decreasing temperature, indicating an incompatible behaviour of both elements (Fig. 7h,i). Pronounced enrichments (hot, hot oxidised, intermediate path) correlate with intervals of enhanced crystallisation. The incompatible character of Na2O is an expression of the anorthite-rich nature of plagioclase. For the cold path, plagioclase crystallised at 870 °C exhibits a distinctly higher albite component, resulting in a decrease of Na2O in the coexisting liquid. For potassium, the flattening of the curve expressed by the cold path at low temperatures coincides with the saturation of biotite at 870 °C. Although errors are significant, P2O5 concentrations of residual melts (Fig. 7j) reveal an incompatible behaviour. For the intermediate and cold path, a decrease/flattening of the trends observed at 900 °C and 870 °C perfectly coincides with apatite saturation.
Olivine
Olivine was stable over a wide temperature range (900–1110 °C) since pressure decrease considerably expanded the olivine stability field. Olivine re-appeared upon decompression to 0.2 GPa for the hot oxidised (990 °C) and the intermediate path (900 °C) although being absent in previous higher pressure–temperature experiments. Molar forsterite contents (XFo) range from 0.91 to 0.63 (Fig. 8). Olivines crystallised at high temperatures (1050–1110 °C) exhibit XFo of 0.82–0.84. With ongoing cooling, olivines evolve towards more fayalitic compositions (XFo of 0.63–0.70). For the hot oxidised and the hot path, the situation is more complex: in both series, extensive magnetite crystallisation was observed in the lowest temperature runs (FM146 and FM150) resulting in a re-increase of XFo from 0.78 to 0.91 (hot oxidised path) and 0.66 to 0.71 (hot path). The very high forsterite content in the 990 °C run of the hot-oxidised path (XFo of 0.91) is related to the combined effects of (1) extensive magnetite crystallisation and (2) an increased Fe3+/Fetot ratio in the melt due to oxidising run conditions (fO2 ~ RRO). MnO contents of olivine increase with decreasing temperature, reaching a maximum of 2.6 wt.% at 900 °C for the intermediate path, while CaO concentrations vary between 0.21 and 0.33 wt.%.
Clinopyroxene
Experimental clinopyroxenes range between diopside and augite and contain considerable amounts of Al2O3 (2.1–8.5 wt.%, see Table 3). Sector zoning (e.g. in Al2O3 and TiO2 contents) was observed for two runs of the hot path (FM93 at 1050 °C and FM146 at 960 °C). There is no consensus if either one of the two sectors represents the "true" equilibrium composition to be expected at respective P–T conditions or if an average composition between both sectors would be more appropriate (e.g. Schwandt and Mckay 2006; Nandedkar et al. 2014). However, we infer that high-Al sectors represent equilibrium values. Clinopyroxene compositions derived by EPMA were normalised following the procedure of Wood and Banno (1973).
Tetrahedral aluminium contents AlIV (in atoms per formula unit, a.p.f.u.) exhibit a well-established negative linear correlation with the sum of ferrous iron and magnesium (Fe2+ + Mg) (Fig. 9a). This trend is almost parallel to the ideal trajectory of the Tschermak’s exchange vector (Fe2+,Mg)Si = AlVIAlIV (black arrow in Fig. 9a) revealing that tetrahedral aluminium incorporation in experimental clinopyroxenes is strongly controlled via the Tschermak’s substitution. Ti contents of clinopyroxenes (in a.p.f.u.) plotted against temperature show an initial increase followed by a late-stage depletion (Fig. 9b). These trends perfectly match TiO2 evolution trajectories of coexisting residual liquids (Fig. 7b) indicating that Ti incorporation in clinopyroxene is controlled by the melt composition (and, thus, indirectly the saturation of Fe–Ti–oxides). Total aluminium (Altot, in a.p.f.u.) as a function of temperature exhibits a bell-shaped behaviour (Fig. 9c). In an initial stage, Al in clinopyroxene increases with decreasing temperature, followed by a rapid decrease at lower temperatures. This trajectory is consistent with the Al2O3 evolution of residual liquids, indicating that melt composition (and, therefore, plagioclase saturation) controls Al in clinopyroxene. In addition, increasing silica activity in the melt shifts the Tschermak’s substitution to the silica-rich side resulting in a depletion of clinopyroxene in Al. Sodium contents of experimental clinopyroxenes exhibit a weak increase with ongoing cooling consistent with an enrichment of residual melts in Na2O (Fig. 9d). Alternatively, a slight increase in fO2 with decreasing temperature could favour a simultaneous increase of the acmite/aegirine component (NaFe3+Si2O6). Variations in fO2 could also explain the higher Na contents of clinopyroxenes synthesised along the hot oxidised path (fO2 ~ RRO).
Amphibole
Amphibole crystallised over a restricted temperature interval (870–990 °C) mostly because decompression resulted in an overall destabilisation of amphibole (e.g. Allen et al. 1975; Blatter et al. 2013). As a consequence, amphibole was absent in the decompression-dominated fractionation paths (except for run FM129 of the hot path). Synthesised amphiboles range from pargasite at high temperatures (990 °C), to ferroan pargasite (930–960 °C), and tschermakitic hornblende or magnesiohornblende at low temperatures (870–900 °C). Amphibole compositions were recalculated with the normalisation algorithm RAMP (Spear and Kimball 1984) with an empirical Fe3+/Fetot ratio of 0.20, representing a value in the range established by Clowe et al. (1988) for a tschermakitic hornblende at fO2 between QFM and NNO.
With decreasing temperature, Si contents of amphibole increase from 5.8 atoms per formula unit (a.p.f.u.) at 990 °C to 6.6 a.p.f.u. at 870 °C (Fig. 10a). Amphiboles synthesised in two low-temperature runs from the cold path (FM131, 900 °C and FM145, 870 °C) exhibit a faint chemical zonation (not visible in BSE images), most prominent in Ti concentrations. Si contents of low-Ti zones are higher compared to coexisting high-Ti ones (6.4 and 6.6 a.p.f.u. vs 6.2 and 6.3 a.p.f.u.) as Ti contents are controlled via the Ti-Tschermak’s exchange (see below) where enhanced Ti incorporation coincides with elevated Al and lower Si contents. Ti plotted against AlIV reveals well-defined positive correlations allowing the identification of two distinct subparallel trajectories (Fig. 10b). Slopes of AlIV vs Ti are parallel to the ideal Ti-Tschermak’s vector ((Fe2+,Mg)Si2 = TiAlIV2, black arrow) implying that incorporation of Ti in amphiboles is controlled by the Ti-Tschermak’s exchange reaction. The expression of two trajectories could be related to the rapid increase of Si contents between 930 and 900 °C resulting in lower AlIV and a change in co-crystallising Fe–Ti–oxides from Ti-bearing magnetite to ilmenite. Apparently, the coexistence with ilmenite slightly enhances the incorporation of Ti in amphiboles compared to the coexistence with magnetite (Ti content of 0.29 a.p.f.u. at 930 °C and 0.32 a.p.f.u. at 900 °C). Total alkali contents on the A-site (NaA + K) exhibit a positive correlation with tetrahedral aluminium and show a continuous decrease with decreasing temperature (Fig. 10c) consistent with the well-known temperature dependence of the edenite vector (▯Si = (Na,K)AlIV) (e.g. Holland and Blundy 1994).
The attainment of experimental equilibrium was tested calculating crystallisation temperatures employing the richterite–edenite thermometer by Holland and Blundy (1994) and resulting temperatures deviate 1–41 °C from effective run temperatures, in excellent agreement within the reported algorithm uncertainty (35–40 °C). Temperatures established for low-Ti zones of zoned amphiboles are distinctively off from experimental conditions unlike the high-Ti zones indicating that high-Ti amphibole compositions represent "real" equilibrium, whereas low-Ti ones are experimental relics, probably corresponding to partly-reacted metastable clinopyroxene. The algorithms of Ridolfi et al. (2010) and Ridolfi and Renzulli (2012) resulted in significant deviations from run conditions and strongly overestimate experimental temperatures (up to 195 °C), with increasing offset with decreasing temperature. Similarly, derived pressures and melt H2O contents are highly variable and do not match experimental run conditions. Thus, the amphibole thermobarometers of Ridolfi et al. (2010) and Ridolfi and Renzulli (2012) failed to reproduce experimental run conditions.
Plagioclase
Plagioclase crystallised over a wide temperature range (1050–870 °C) and occurred at pressures between 0.2 and 0.8 GPa. Anorthite contents reveal that plagioclase is anorthite-rich (An90–An77) and displays a consistent decrease with decreasing temperature for all five fractionation paths (Fig. 11a). The hot, hot oxidised, and intermediate path demonstrate a more pronounced decrease of anorthite contents for the last temperature step investigated, coinciding with an increase of coexisting residual liquids in Na2O (Fig. 7h). Although Na contents of the melt are also progressively increasing along the cold path, the decrease in anorthite is less pronounced. This difference can be explained considering water-saturation levels of the various experimental series. The lowest temperature runs of the hot, hot oxidised and intermediate path were performed at 0.2 GPa and, thus, water-saturation was reached in these charges. For H2O-undersaturated magmas, crystallisation with decreasing temperatures enriches residual melts in H2O and, thus, increases water activity. H2O activity also increases due to decreasing H2O solubility in silicate liquids with decreasing pressure (e.g. Hamilton et al. 1964; Shishkina et al. 2010; Ghiorso and Gualda 2015). Sisson and Grove (1993a) demonstrated that increasing water activity leads to the stabilisation of anorthite relative to the albite component in plagioclase. Thus, increasing H2O activities in nominally water-undersaturated magmas with ongoing differentiation suppress a pronounced decrease of anorthite contents of plagioclase. Upon water-saturation, this effect vanishes, and plagioclase compositions are controlled by the Na–Ca systematics of coexisting liquids. Although the last two experiments (870 and 900 °C) of the cold path at 0.4 GPa reached water-saturation (Table 2), plagioclase anorthite contents do not show a distinct decrease and reasons for this behaviour are currently unclear. Ca–Na ratios between plagioclase and residual melt and KD trajectories are illustrated in Fig. 11b. It is evident that each explored fractionation path exhibits a strong dependence of Ca–Na distribution coefficients on experimental temperature. At high temperatures (≥ 1020 °C) KD’s scatter around 3.0–4.0 but evolve to higher values (4.0–5.5) with cooling finally reaching a range of 5.5 to 7.0 at lowest temperatures. Sisson and Grove (1993a) showed that water content (and/or water activity) exerts a strong influence on Ca–Na distribution coefficients reaching maximum Ca–Na KD values of about 5.5 at water-saturation at 0.2 GPa. These findings agree with our data documenting progressively increasing water contents (and water activities) upon differentiation.
Fe–Ti–oxides
Spinel group minerals exhibit a strong compositional dependence on temperature, where hercynitic spinel crystallised at high temperatures (1020–1050 °C), titanomagnetite formed at intermediate temperatures (930–960 °C), and Ti-bearing magnetite was stable at low temperatures (900–930 °C). This transition in spinel composition corresponds to the onset of ferric iron incorporation in the spinel structure at the expense of Al. Spinel group minerals of the hot oxidised path exhibit elevated ferric iron contents and diminished Ti concentrations compared to spinel from the other series because of the higher fO2 of these experiments. Ilmenite crystallised along the cold path and coexists with magnetite at 960 °C and 0.6 GPa, but represents the only stable Fe–Ti–oxide in the two lowest temperature runs (900 and 870 °C). Generally, MgO contents of experimental ilmenite are minor (4.03–5.00 wt.%), and recalculated ferric iron contents range from 0.09 to 0.18 a.p.f.u.
Minor phases
Biotite was only stable in the lowest temperature run of the cold path (870 °C and 0.4 GPa) with an xMg of 0.70, an average TiO2 content of 3.87 wt.%, and minor amounts of Na2O (1.10 wt.%). Similarly, orthopyroxene was only observed in the lowest temperature run of the intermediate path and exhibits weak sector zonation most pronounced in alumina and iron contents. The xMg’s of 0.72 (high-Al sector, 2.63 wt.% Al2O3) and 0.69 (low-Al sector, 1.55 wt.% Al2O3) identify these orthopyroxenes as hypersthene. MnO contents are rather high with 2.43 wt.% (high-Al) and 2.95 wt.% (low-Al).
Discussion
Comparison of experimental liquid lines of descent with Cascades volcanic rocks
First, we compare the experimentally derived liquid lines of descent (LLD) with a compilation of bulk rock data from the Cascades volcanics in the Western U.S. (Du Bray et al. 2006) and with previous isobaric fractional and equilibrium crystallisation experiments. Since our polybaric fractionation series were terminated when residual liquids reached andesitic to dacitic compositions, more evolved (rhyolitic) compositions exhibited by the natural rocks were not reproduced. However, differentiation trends of intermediate and more evolved magmas are controlled by multicomponent phase equilibria and follow well-defined compositional trajectories as established by previous experimental studies (e.g. Grove and Baker 1984; Sisson and Grove 1993a; Blatter et al. 2017; Müntener and Ulmer 2018; Ulmer et al. 2018; Marxer and Ulmer 2019). It has to be emphasised that comparisons between experimental LLD’s and natural rocks assume that the latter represent true liquid compositions, which is not entirely true for most cases and, thus, has to be kept in mind for the following discussion.
Overall, LLD’s of our polybaric fractionation series as well as previous experimental trends from the literature only partly overlap with the differentiation trends defined by the Cascades volcanic rocks. Due to the near-linear relationship with experimental temperature (Fig. 7f), we chose MgO to illustrate experimental and natural differentiation trends. Silica contents of the polybaric LLD’s define a nonlinear increase with decreasing MgO similar to the Cascades rocks, with an excellent overlap at low MgO (≤ 3–4 wt.%) for the last fractionation steps of each polybaric series (Fig. 12a). At less evolved stages, residual melts plot at the lower end of the field delineated by natural rocks. One possible reason is the low SiO2 of our starting material (SiO2 of 47.4 wt.%). Primitive rocks from the Cascades volcanoes, however, are generally more enriched in silica. Furthermore, for any specific MgO content, LLD’s defined by previous experimental studies plot at the lower end of natural rocks delineated by the Cascades, but generally above our own data. However, the differentiation trend of Nandedkar et al. 2014; reproduces well the natural spread, which could be related to the more silicic character of their starting material and the slightly lower initial water content favouring the attainment of a higher melt silica activity.
TiO2 contents of experimental melts agree well with the natural rock compositions but essentially only reproduced the lower range of natural titanium contents (Fig. 12b). The elevated TiO2 concentrations of some Cascades rocks can be explained by compositional variations of primary mantle-derived magmas, where high TiO2 rocks represent H2O-poor decompression melts (i.e. high-alumina olivine tholeiites) (e.g. Bartels et al. 1991; Grove et al. 2002), while rocks with lower TiO2 contents correspond to subduction related magmas produced by fluid flux-melting of mantle rocks (e.g. Grove et al. 2002, 2005). Fractional crystallisation LLD’s at 0.7–1.0 GPa (Nandedkar et al. 2014; Ulmer et al. 2018) also reproduce the natural differentiation trend albeit at lower maximum TiO2 compared to polybaric fractionation. This can be related to the efficient depletion of residual melts in titanium due to enhanced amphibole fractionation at higher pressures and/or slightly higher fO2 (NNO to NNO+1) favouring earlier saturation of Fe–Ti–oxides. The effect of amphibole fractionation on melt TiO2 contents is also shown by the LLD at 0.4 GPa of Nandedkar (2014), where amphibole and Fe–Ti–oxide crystallisation was not observed resulting in an enrichment of the residual melts in TiO2. The LLD’s by Blatter et al. (2013), albeit starting at higher TiO2 contents, reveal a similar evolution, where the onset of TiO2 decrease is almost pressure independent and agrees well with our polybaric data.
Experimental liquids are enriched in Al2O3 with respect to the Cascades rocks (Fig. 12c). This is related to the combined effects of suppressed crystallisation of plagioclase at high pressures (0.6–0.8 GPa) and the elevated Al2O3 contents of our primary starting materials (Table 1). This indicates that a majority of the Cascades volcanics did not fractionate exclusively in the lower crust, as rocks with comparable MgO concentrations reveal distinctly lower Al2O3 contents than the experimental LLD’s. Decompression of ascending magmas enhances plagioclase crystallisation, resulting in a decrease of Al2O3 of experimental liquids following compositional trends of the natural rocks. In fact, only residual liquids of the last decompression steps to 0.2 GPa for the hot, hot oxidised, and intermediate path plot within the Cascades range, while the cold path remains at too high Al2O3 contents due to pronounced fractionation at higher pressures. Isobaric differentiation trends between 0.7 and 1.0 GPa (Blatter et al. 2013; Nandedkar et al. 2014; Ulmer et al. 2018) closely follow our polybaric fractionation trends and likewise overestimate Al2O3 contents with respect to the natural rocks. Only the 0.4 GPa LLD’s reproduce the natural differentiation trend (Blatter et al. 2013; Nandedkar 2014) illustrating the effect of pressure on Al2O3 contents of residual liquids.
Our fractionation experiments overestimate iron contents (Fig. 12d) with respect to the natural rock record at intermediate stages of differentiation (2–6 wt.% MgO). This could be related to delayed saturation of Fe–Ti–oxides as a consequence of slightly lower fO2 of our experiments compared to the natural rock record. In contrast, the most evolved run of the hot oxidising path plots at too low FeO contents inferring that fO2 conditions close to RRO put an upper bound on magmatic redox conditions. This interpretation is supported by experiments at more oxidising conditions, which better reproduce the natural rock record (NNO to NNO+1 for Nandedkar (2014), Nandedkar et al. (2014), and Ulmer et al. (2018) or RRO-0.5 to RRO+1.3 for Blatter et al. (2013)).
CaO characteristics (Fig. 12e) of the polybaric fractionation paths are shifted towards higher values at intermediate (5–10 wt.%) MgO contents. Only upon the last fractionation steps, our data overlap with the natural rock record. This can be explained by higher CaO contents of our starting material compared to the Cascades volcanics. This interpretation is supported by previous experiments on related starting compositions from the Adamello which overlap with our data and also plot at too high CaO concentrations (Fig. 12e). However, LLD’s established by Blatter et al. (2013) almost perfectly reproduce the Cascades trend indicating that CaO trajectories are dominantly controlled by the primary magma composition and less by the initial stages of differentiation.
K2O evolution trends closely reproduce the natural trend exhibited by the Cascades rocks (Fig. 12f), mostly covering the upper end of potassium concentrations. The last fractionation experiments of the hot, hot oxidised, and intermediate path plot at the upper boundary of the natural compositions. This is related to the incompatible behaviour of potassium in calc-alkaline systems and a slightly elevated K2O content of our primary starting material. Residual liquids of the equilibrium and fractional crystallisation experiments plot at slightly lower potassium contents but show a similar characteristic enrichment in K2O upon decreasing MgO (Fig. 12f).
Figure 13a presents FeOtot/MgO ratios (all iron as FeO) as a function of SiO2 content of residual melts to distinguish tholeiitic from calc-alkaline differentiation trends (Miyashiro 1974). Residual liquids from previous experimental series follow the boundary between the tholeiitic and calc-alkaline field during early stages of differentiation but enter the latter upon advanced crystallisation. Our data reveal a distinct excursion towards tholeiitic compositions with increasing SiO2 followed by a back-bend into the calc-alkaline field related to Fe–Ti–oxide crystallisation. On the contrary, the 0.7 GPa differentiation trends display only a weak initial enrichment in iron and become calc-alkaline between 55 and 60 wt.% of SiO2. The variations in FeOtot/MgO among different experimental series is controlled by fO2 during differentiation as discussed in detail by Sisson et al. (2005). The combined effects of low fO2 and low H2O contents result in delayed crystallisation of Fe–Ti–oxides, driving residual liquids into the tholeiitic field, while calc-alkaline trajectories are favoured by more hydrous and oxidising conditions (e.g. Sisson et al. 2005; Blatter et al. 2013; Nandedkar et al. 2014).
In the TAS diagram (SiO2 vs Na2O + K2O) the experimental series reproduce the natural differentiation trend (Fig. 13b). However, the high-pressure LLD’s at 0.7 and 1.0 GPa evolve along the lower limit of the natural compositional field and reach rhyolitic compositions, while the polybaric trends rather plot at the upper end and only extend into the andesite or dacite field. These differences in TAS trajectories are related to variations in Na2O and K2O contents of the different starting materials (e.g. potassium) and/or variable phase equilibria (e.g. stability fields of plagioclase and amphibole).
In summary, a detailed comparison of our experimental data and previous studies with the natural rock record from the Cascades reveals that polybaric fractional crystallisation only partly reproduces the chemical variability of arc rocks. Differences for some oxides (e.g. K2O or SiO2) can be explained by variations in the experimental starting materials while others are related to the redox conditions during differentiation (e.g. FeO and FeOtot/MgO). Distinct differences among other components, such as Al2O3, are controlled by phase equilibria, i.e. the fractionation of clinopyroxene during early stages of differentiation at high pressures and the simultaneous suppression of plagioclase crystallisation. The compositional spread revealed by natural calc-alkaline rock suites requires additional magmatic processes besides polybaric fractionation, such as imperfect fractionation (i.e. crystal entrainment during melt extraction), magma mixing (e.g. Sisson et al. 2005; Reubi and Blundy 2009; Blatter et al. 2013), or crustal assimilation (e.g. DePaolo 1981; Hildreth and Moorbath 1988) and is addressed in the last section of the discussion.
Evolution of the alumina saturation index
Evolution trajectories of the alumina saturation index (ASI, molar ratio of Al2O3/(CaO + Na2O + K2O)) of experimental liquids are compared with volcanic rocks from the Cascades and the 1.0 GPa fractionation experiments of Ulmer et al. (2018) preceding the polybaric series (Fig. 14). Natural rocks follow a differentiation trend from metaluminous (ASI < 1) towards weakly peraluminous (ASI > 1) compositions. In contrast, our polybaric LLD’s differ significantly and plot at elevated ASI’s. Most remarkably, the cooling-dominated fractionation trends (cold and intermediate path) rapidly evolve towards peraluminous compositions and become corundum-normative at silica contents between 48 and 52 wt.%. In contrast, the decompression-dominated fractionation trends (hot and hot oxidised path) remain metaluminous during differentiation and enter the compositional field covered by the natural rocks upon final decompression to 0.2 GPa. This difference between different polybaric fractionation series is directly related to the effect of pressure on phase equilibria. At high pressures (0.6–0.8 GPa), extensive clinopyroxene crystallisation results in a pronounced depletion of residual melts in CaO. Such an evolution towards andesitic or dacitic peraluminous differentiates at high pressures has previously been reported by experimental studies (e.g. Blatter et al. 2013; Nandedkar et al. 2014; Ulmer et al. 2018). Upon decompression to 0.4–0.2 GPa, clinopyroxene and amphibole destabilise at the expense of olivine and plagioclase keeping residual liquids metaluminous. Consequently, decompression-dominated fractionation trends better reproduce the natural compositional range.
Phase relations and liquid lines of descent in pseudoternary projections
Compositions of residual experimental liquids and the Cascades volcanics are plotted in the normative olivine (Ol) – clinopyroxene (Cpx) – quartz + orthoclase (Qtz + Or) pseudoternary diagram projected from plagioclase (Plag), apatite (Ap), and ilmenite–hematite (Ilm–Hem) to illustrate the control of phase equilibria on the LLD’s (Fig. 15). Normative mineral compounds were re-calculated from melt compositions following the approach presented by Grove et al. (1992) and modified by Blatter et al. (2017). To facilitate the interpretation of LLD’s, we additionally plotted bulk compositions of experimental cumulates (highlighted by the grey shaded background). Cumulate compositions were calculated based on phase proportions (Table 2) and average compositions of mineral phases (Table 3) and are reported in the Electronic Supplementary Material ESM 7. For normative calculations, ferric/ferrous iron ratios of residual melts were estimated as follows: For runs buffered close to NNO (hot, hot rk52, intermediate, and cold path), an Fe3+/Fetot ratio of 0.20 was assumed based on results from the Kress and Carmichael (1991) algorithm. Accordingly, a value of 0.35 was employed for the hot oxidised path. For the Cascades volcanics we assumed a ratio of 0.20 inferring that these rocks predominantly formed at moderately oxidising fO2 conditions.
All five LLD’s exhibit a continuous decrease of normative clinopyroxene and olivine accompanied by an enrichment in quartz + orthoclase, illustrated by the differentiation trends away from the Ol–Cpx side-line towards the Qtz + Or corner. These trends are consistent with extensive crystallisation of Fe–Mg silicates with ongoing cooling (Figs. 7 and 12). Differentiation trajectories can roughly be distinguished in three intervals: an initial phase characterised by olivine fractionation resulting in an increase or stagnation of the clinopyroxene component, followed by a second interval dominated by clinopyroxene and olivine cotectic crystallisation depleting residual liquids efficiently in normative clinopyroxene, and a final interval, where the crystallisation of amphibole and magnetite leads to a pronounced enrichment of residual melts in SiO2 shifting the trajectories towards the Qtz + Or corner. Such differentiation trends are a characteristic feature of calc-alkaline differentiation, as previously shown by numerous studies (Sisson and Grove 1993a; Pichavant and Macdonald 2007; Nandedkar et al. 2014; Ulmer et al. 2018). Experimental cumulates define two main groups. The first one lies close to the Ol apex and represents dunitic or troctolitic cumulates. The second group plots close to the Qtz + Or base-line at similar normative Ol and Cpx contents and either represents clinopyroxene- or amphibole-dominated cumulates. In detail, amphibole-bearing cumulates are shifted towards more negative Qtz + Or (due to nepheline-normative amphibole) while clinopyroxene-dominated ones are displaced to slightly higher Cpx.
During early stages of fractionation, melt compositions from the hot, intermediate, and cold path are similar, with an enhanced decrease of the clinopyroxene component accompanied by a less distinct reduction of the olivine compound. Subsequently, the hot path diverges from the more cooling-dominated intermediate and cold LLD’s. The latter two trajectories continue their evolution towards the Cpx base-line, while the hot path bends towards the Qtz + Or corner as a consequence of enhanced olivine crystallisation and destabilisation of clinopyroxene, keeping residual melts metaluminous. Crystallisation of clinopyroxene and amphibole drives the cooling-dominated fractionation trends into the peraluminous compositional field. The intermediate path exhibits extensive orthopyroxene and magnetite fractionation in the last step directing residual liquids towards the Qtz + Or corner, while the LLD defined by the cold path is controlled by amphibole fractionation and evolves deeper into the peraluminous field. The hot rk52 path was explored to test if an elevated clinopyroxene component of the initial basaltic magma results in an LLD subparallel to the previous FC paths (hot, intermediate, or cold), but displaced to higher normative clinopyroxene. This was, however, not the case; it converges with the other series originating from the starting material rk54 upon the last temperature step investigated. Thus, starting crystallisation from a more Cpx-rich initial composition just results in higher proportions of early clinopyroxene fractionation but has no effect on the later stage chemical evolution of the residual liquids. In contrast, the hot oxidised path branches off from the hot path at 1080 °C and 0.8 GPa and evolves along a trajectory subparallel to the LLD’s of the other fractionation series but maintains higher normative clinopyroxene components, underlining the important control of fO2 on crystallisation-differentiation.
In principle, the exact location of the olivine–clinopyroxene cotectic curve controlling the LLD of arc magmas depends on pressure, fO2, and bulk system composition (i.e. xMg). The olivine–clinopyroxene cotectic is shifted towards clinopyroxene-rich compositions with decreasing pressure (i.e. polybaric fractionation) leading to a destabilisation of clinopyroxene at the expense of olivine (e.g. Grove et al. 1992; Hamada and Fujii 2008; Stamper et al. 2014; Melekhova et al. 2015) and a displacement of LLD’s towards the Cpx apex. Consequently, cooling-dominated polybaric fractionation (cold path) exhibits an evolution towards strongly peraluminous compositions, while the LLD of decompression-dominated one (hot path) plots at higher normative clinopyroxene and remains in the metaluminous field. The intermediate path lies between these two endmembers, but also becomes weakly peraluminous upon progressive differentiation. An increase of fO2 leads to the destabilisation of clinopyroxene at the expense of olivine. This effect is linked to the ferrous iron content of the crystallising magma. An increase of fO2 results in reduced proportions of FeO in the melt at the expense of Fe2O3 and an increase of the effective xMg (= Mg/(Mg + Fe2+)) of the residual melt favouring olivine over clinopyroxene (e.g. Ulmer et al. 2018). In fact, the hot oxidised path at RRO exemplifies this influence of fO2 on the olivine–clinopyroxene cotectic, which is displaced towards higher normative Cpx component relative to NNO. In addition, elevated fO2 conditions promoted crystallisation of spinel phases, further enhancing SiO2 enrichment and FeO decrease of residual melts.
The comparison of the experimental LLD’s with compositions of the Cascades volcanics reveals that polybaric differentiation cannot completely reproduce the natural rock record. The depletion of residual liquids in normative clinopyroxene contents along the cold and intermediate path drives them below the natural rock record into the peraluminous field. However, the intermediate path experiences a pronounced shift towards the quartz + orthoclase corner during the last differentiation step (fractionation of Fe–Ti–oxide bearing norites) resulting in an overlap with the natural rock record for weakly peraluminous compositions. The LLD of the hot path is slightly shifted towards higher normative clinopyroxene and follows the lower limit of the natural rocks overlapping in the last fractionation step with metaluminous intermediate to more evolved natural rocks. The hot oxidised path follows higher normative clinopyroxene contents overlapping with the Cascades volcanics.
Consequently, decompression-dominated magma ascent paths closely overlap with natural volcanic rocks, while cooling-dominated ascent trajectories deviate significantly. The present data emphasise the possible importance of fO2 of silicate magmas on LLD’s: only the hot oxidised path is able to reproduce the compositional trend of volcanic rocks inferring that redox conditions of fractionating arc magmas are, in fact, about one log-unit higher (NNO+1 to NNO+2) than commonly assumed (NNO to NNO+1) (e.g. Gill 1981; Cottrell et al. 2021).
General implications for arc magma differentiation
Our experiments show that decompression-dominated polybaric fractionation represents a possible scenario for arc magma differentiation, although the applicability of this model exhibits some limitations. Consequently, additional (open-system) magmatic processes and/or different near-adiabatic decompression paths with variable initial temperature need to be considered to derive a general model for arc magmatism able to explain the observed compositional variation of natural calc-alkaline rocks.
One process is mixing of melts with different compositions (i.e. basaltic and dacitic to rhyolitic) in the lower crust (e.g. Hildreth and Moorbath 1988). Thereby, the evolved magmas either represent differentiation products of basaltic magmas originating from the underlying mantle or low-degree partial melts from previously solidified basaltic magmas re-melted by heat supply of freshly injected primitive melts. After mixing, these buoyant metaluminous intermediates start ascending towards the upper crust and further differentiate via polybaric fractionation. In fact, rocks from the Cascades exhibit broadly linear trajectories for several chemical parameters (Figs. 12, 13, and 15) between compositions from evolved basalt (~ 8 wt.% MgO) to andesite/dacite (~ 2 wt.% MgO). However, primitive rocks do not match these linear trends pointing towards early crystallisation-differentiation of primary mantle-derived basalts. Likewise, more evolved rhyodacitic to rhyolitic compositions do not represent extrapolations of the linear intermediate trajectories. This observation indicates that the late stage chemical evolution of residual liquids is, again, dominated by crystallisation processes. The distinct rheology contrast between mafic and felsic magmas is severely hampering any efficient mixing of strongly contrasting compositions and favouring magma mingling instead (e.g. Eichelberger 1975; Sparks and Marshall 1986; Blundy and Sparks 1992). However, in case of mixing components being close in composition and temperature (i.e. evolved basalt and andesite) this difference in rheology also diminishes potentially facilitating the mixing process.
A second, potentially even more important, mechanism is incomplete fractionation and crystal retention in decompressing magmas. Early fractionation of primitive basalt at the crust–mantle boundary is dominated by the crystallisation of olivine, clinopyroxene, and very minor Cr-rich spinel resulting in wherlite and olivine–clinopyroxenite cumulates. Derivative buoyant residual magmas rising towards the upper crust may contain significant proportions of this clinopyroxene-dominated crystal cargo. Upon ascent and decompression, the olivine–clinopyroxene cotectic shifts towards clinopyroxene by dissolving entrained clinopyroxene, while olivine remains stable and/or continues to crystallise/fractionate. Consequently, normative clinopyroxene contents of the ascending magma increase driving it towards the compositional range covered by natural rocks (Fig. 15).
In summary, we infer that the compositional variation revealed by natural calc-alkaline rocks can be reproduced by a combination of polybaric fractionation, mixing of magmas of differentiated basaltic and andesitic/dacitic composition, and the entrainment of clinopyroxene upon melt extraction in the lower crust. A conceptual model illustrating the various processes of arc magma differentiation is shown in Fig. 16. Hydrous mantle-derived primitive basalts fractionate olivine + clinopyroxene ± spinel, and minor amounts of plagioclase and amphibole in the lower crust. This fractionation process is accompanied by mixing between evolved basaltic and andesitic/dacitic magmas. Clinopyroxene and olivine-dominated cumulate assemblages are potentially entrained due to imperfect fractionation processes in the lower crust. During decompression and magma ascent, residual liquids further evolve via polybaric fractionation of olivine, plagioclase, and magnetite and by dissolution or minor crystallisation of clinopyroxene. In addition, differentiation during ascent is potentially accompanied by mixing/mingling of compositionally similar magma batches in the conduit. Finally, resulting evolved magmas are either emplaced in the upper crust and solidify to intermediate/felsic plutonic rocks or erupt on the surface building arc volcanic complexes.
Conclusions
This experimental study explored the scenario of polybaric fractional crystallisation of arc magmas and tested its applicability to explain the compositional variation of natural calc-alkaline rocks at convergent plate margins. A total of five different magma ascent paths were explored to investigate the combined effects of cooling and decompression, fO2, and the composition of the initial starting material on the resultant liquid lines of descent. The most relevant findings of this study are:
-
During polybaric fractionation, decompression causes continuous changes in phase equilibria controlling the LLD’s. With decreasing pressure, clinopyroxene is destabilised at the expense of olivine resulting in a shift of the olivine–clinopyroxene cotectic curve towards more clinopyroxene normative compositions. The stability field of plagioclase expands with decreasing pressure, with important effects on Al2O3 contents of derivative liquids. Amphibole crystallisation was restricted to elevated pressures of 0.4–0.6 GPa, but absent in the lowest pressure runs at 0.2 GPa.
-
Liquid lines of descent established via polybaric fractional crystallisation follow calc-alkaline differentiation trends with continuously increasing silica and alkali contents and depletion in MgO. Differentiation trends of cooling-dominated fractionation evolve towards peraluminous melt compositions similar to previous high-pressure isobaric crystallisation studies and do not reproduce the compositional variation observed for calc-alkaline volcanic rocks from the Cascades (Western U.S.). For decompression-dominated fractionation, the pressure-induced shift of the olivine–clinopyroxene cotectic results in a slight deflection of LLD’s towards higher normative clinopyroxene keeping them metaluminous, similar to the natural volcanic record.
-
Results from oxidised fractionation experiments demonstrate a fundamental control of fO2 on the chemical evolution of calc-alkaline liquids. The LLD is shifted towards clinopyroxene-rich normative compositions resulting in an excellent match of experimental melts with natural bulk rock compositions. Consequently, our data indicate that fO2 potentially plays a key role for arc magma differentiation opening new avenues for future studies on the quantification of varying redox conditions on calc-alkaline phase equilibria.
-
Based on the compositional variation revealed by typical calc-alkaline rocks, polybaric fractional crystallisation alone cannot explain the natural arc magmatic differentiation trend. Mixing between differentiated basalts and intermediate liquids (andesite and/or dacite) and crystal entrainment from previously formed clinopyroxene-dominated cumulates during melt segregation are important in modifying LLD’s defined by fractional crystallisation. Both processes result in an enrichment of residual melts in normative clinopyroxene and, thus, circumvent the evolution of magmas towards peraluminous compositions. However, additional experimental and petrological research is required to test and refine this model.
Data availability
Data established in this project are made available electronically as supplementary material to this manuscript.
Code availability
Not applicable.
References
Allen JC, Boettcher AL, Marland G (1975) Amphiboles in andesite and basalt: I. Stability as a function of P-T-fO2. Am Miner 60:1069–1085
Almeev RR, Ariskin AA, Kimura JI, Barmina GS (2013) The role of polybaric crystallization in genesis of andesitic magmas: phase equilibria simulations of the Bezymianny volcanic subseries. J Volcanol Geoth Res 263:182–192. https://doi.org/10.1016/j.jvolgeores.2013.01.004
Alonso-Perez R, Müntener O, Ulmer P (2009) Igneous garnet and amphibole fractionation in the roots of island arcs: experimental constraints on andesitic liquids. Contrib Mineral Petrol 157:541–558. https://doi.org/10.1007/s00410-008-0351-8
Anderson AT (1973) The before-eruption water content of some high-alumina magmas. Bull Volcanol 37:530–552. https://doi.org/10.1007/BF02596890
Baker DR (2004) Piston-cylinder calibration at 400 to 500 MPa: a comparison of using water solubility in albite melt and NaCl melting. Am Miner 89:1553–1556. https://doi.org/10.2138/am-2004-1026
Barr JA, Grove TL (2010) AuPdFe ternary solution model and applications to understanding the fO2 of hydrous, high-pressure experiments. Contrib Mineral Petrol 160:631–643. https://doi.org/10.1007/s00410-010-0497-z
Bartels KS, Kinzler RJ, Grove TL (1991) High-pressure phase-relations of primitive high-alumina basalts from Medicine Lake volcano, northern California. Contrib Mineral Petrol 108:253–270. https://doi.org/10.1007/Bf00285935
Blatter DL, Sisson TW, Hankins WB (2013) Crystallization of oxidized, moderately hydrous arc basalt at mid- to lower-crustal pressures: implications for andesite genesis. Contrib Mineral Petrol 166:861–886. https://doi.org/10.1007/s00410-013-0920-3
Blatter DL, Sisson TW, Hankins WB (2017) Voluminous arc dacites as amphibole reaction-boundary liquids. Contrib Mineral Petrol 172:27. https://doi.org/10.1007/s00410-017-1340-6
Blundy J, Cashman K (2001) Ascent-driven crystallisation of dacite magmas at Mount St Helens, 1980–1986. Contrib Mineral Petrol 140:631–650. https://doi.org/10.1007/s004100000219
Blundy J, Cashman K (2008) Petrologic reconstruction of magmatic system variables and processes. Miner, Incl Volcan Process 69:179–239. https://doi.org/10.2138/rmg.2008.69.6
Blundy JD, Sparks RSJ (1992) Petrogenesis of mafic inclusions in granitoids of the Adamello Massif, Italy. J Petrol 33:1039–1104. https://doi.org/10.1093/petrology/33.5.1039
Blundy J, Melekhova E, Ziberna L, Humphreys MCS, Cerantolo V, Brooker RA, McCammon C, Pichavant M, Ulmer P (2020) Effect of redox on Fe-Mg-Mn exchange between olivine and melt and an oxybarometer for basalts. Contrib Mineral Petrol 175:103. https://doi.org/10.1007/s00410-020-01736-7
Botcharnikov RE, Koepke J, Holtz F, McCammon C, Wilke M (2005) The effect of water activity on the oxidation and structural state of Fe in a ferro-basaltic melt. Geochim Cosmochim Acta 69:5071–5085. https://doi.org/10.1016/j.gca.2005.04.023
Bowen NL (1915) The later stages of the evolution of the igneous rocks. J Geol 23:1–91
Bowen NL (1928) The evolution of the igneous rocks. Princton University Press, Princton
Burnham CW (1994) Development of the Burnham model for prediction of H2O solubility in magmas. In: Carroll MR, Holloway JR (eds) Volatiles in magmas. Reviews in mineralogy and geochemistry, vol 30. Mineralogical Society of America, Washington, pp 123–130
Burnham CW, Davis NF (1974) The role of H2O in silicate melts: II. Thermodynamic and phase relations in the system NaAlSi3O8-H2O to 10 kilobars, 700 °C to 1100 °C. Am J Sci 274:902–940. https://doi.org/10.2475/ajs.274.8.902
Cawthorn RG, O’Hara MJ (1976) Amphibole fractionation in calc-alkaline magma genesis. Am J Sci 276:309–329. https://doi.org/10.2475/ajs.276.3.309
Clark SP (1959) Effect of pressure on the melting points of eight alkali halides. J Chem Phys 31:1526–1531. https://doi.org/10.1063/1.1730648
Clemens JD, Stevens G, Farina F (2011) The enigmatic sources of I-type granites: the peritectic connexion. Lithos 126:174–181. https://doi.org/10.1016/j.lithos.2011.07.004
Clemens JD, Stevens G, Mayne MJ (2021) Do arc silicic magmas form by fluid-fluxed melting of older arc crust or fractionation of basaltic magmas? Contrib Mineral Petrol. https://doi.org/10.1007/s00410-021-01800-w
Clowe CA, Popp RK, Fritz SJ (1988) Experimental investigation of the effect of oxygen fugacity on ferric-ferrous ratios and unit-cell parameters of four natural clinoamphiboles. Am Mineral 73:487–499
Collins WJ, Murphy JB, Johnson TE, Huang HQ (2020) Critical role of water in the formation of continental crust. Nat Geosci 13:331–338. https://doi.org/10.1038/s41561-020-0573-6
Cottrell E, Birner SK, Brounce M, Davis FA, Waters LE, Kelley KA (2021) Oxygen fugacity across tectonic settings. In: Moretti R, Neuville DR (eds) AGU Geophysical Monograph Series - Magma Redox Geochemistry. Wiley, Hoboken, pp 33-61
Davidson J, Turner S, Handley H, Macpherson C, Dosseto A (2007) Amphibole “sponge” in arc crust? Geology 35:787–790. https://doi.org/10.1130/G23637A.1
DePaolo DJ (1981) Trace element and isotopic effects of combined wallrock assimilation and fractional crystallization. Earth Planet Sci Lett 53:189–202. https://doi.org/10.1016/0012-821x(81)90153-9
Dessimoz M, Müntener O, Ulmer P (2012) A case for hornblende dominated fractionation of arc magmas: the Chelan Complex (Washington Cascades). Contrib Mineral Petrol 163:567–589. https://doi.org/10.1007/s00410-011-0685-5
Du Bray EA, John DA, Sherrod DR, Evarts RC, Conrey RM, Lexa J (2006) Geochemical database for volcanic rocks of the Western Cascades, Washington, Oregon, and California. US Geol Surv Data Ser 15:49. https://doi.org/10.3133/ds155
Eichelberger JC (1975) Origin of andesite and dacite: evidence of mixing at Glass Mountain in California and at other circum-Pacific volcanos. Geol Soc Am Bull 86:1381–1391. https://doi.org/10.1130/0016-7606(1975)86%3c1381:Ooaade%3e2.0.Co;2
Erdmann S, Martel C, Pichavant M, Kushnir A (2014) Amphibole as an archivist of magmatic crystallization conditions: problems, potential, and implications for inferring magma storage prior to the paroxysmal 2010 eruption of Mount Merapi, Indonesia. Contrib Mineral Petrol 167:1016. https://doi.org/10.1007/s00410-014-1016-4
Eugster HP (1957) Heterogeneous reactions involving oxidation and reduction at high pressures and temperatures. J Chem Phys 26:1760–1761. https://doi.org/10.1063/1.1743626
Eugster HP, Wones DR (1962) Stability relations of the ferruginous biotite, annite. J Petrol 3:82–125. https://doi.org/10.1093/petrology/3.1.82
Foden JD, Green DH (1992) Possible role of amphibole in the origin of andesite: some experimental and natural evidence. Contrib Mineral Petrol 109:479–493. https://doi.org/10.1007/BF00306551
Ghiorso MS, Evans BW (2008) Thermodynamics of rhombohedral oxide solid solutions and a revision of the Fe–Ti two–oxide geothermometer and oxygen-barometer. Am J Sci 308:957–1039. https://doi.org/10.2475/09.2008.01
Ghiorso MS, Gualda GAR (2015) An H2O-CO2 mixed fluid saturation model compatible with rhyolite-MELTS. Contrib Miner Petrol 169:53. https://doi.org/10.1007/s00410-015-1141-8
Gill J (1981) Orogenic andesites and plate tectonics. Springer Verlag, Berlin
Goltz AE, Krawczynski MJ, Gavrilenko M, Gorbach NV, Ruprecht P (2020) Evidence for superhydrous primitive arc magmas from mafic enclaves at Shiveluch volcano, Kamchatka. Contrib Mineral Petrol. https://doi.org/10.1007/s00410-020-01746-5
Green TH, Ringwood AE (1968) Genesis of the calc-alkaline igneous rock suite. Contrib Mineral Petrol 18:105–162. https://doi.org/10.1007/BF00371806
Grove TL, Baker MB (1984) Phase-equilibrium controls on the tholeiitic versus calc-alkaline differentiation trends. J Geophys Res 89:3253–3274. https://doi.org/10.1029/JB089iB05p03253
Grove TL, Kinzler RJ, Bryan WB (1992) Fractionation of mid-ocean ridge basalt (MORB). Geophys Monogr Ser 71:281–310. https://doi.org/10.1029/GM071p0281
Grove TL, Parman SW, Bowring SA, Price RC, Baker MB (2002) The role of an H2O-rich fluid component in the generation of primitive basaltic andesites and andesites from the Mt. Shasta region, N California. Contrib Mineral Petrol 142:375–396. https://doi.org/10.1007/s004100100299
Grove TL, Elkins-Tanton LT, Parman SW, Chatterjee N, Müntener O, Gaetani GA (2003) Fractional crystallization and mantle-melting controls on calc-alkaline differentiation trends. Contrib Mineral Petrol 145:515–533. https://doi.org/10.1007/s00410-003-0448-z
Grove TL, Baker MB, Price RC, Parman SW, Elkins-Tanton LT, Chatterjee N, Müntener O (2005) Magnesian andesite and dacite lavas from Mt. Shasta, northern California: products of fractional crystallization of H2O-rich mantle melts. Contrib Mineral Petrol 148:542–565. https://doi.org/10.1007/s00410-004-0619-6
Hamada M, Fujii T (2008) Experimental constraints on the effects of pressure and H2O on the fractional crystallization of high-Mg island arc basalt. Contrib Mineral Petrol 155:767–790. https://doi.org/10.1007/s00410-007-0269-6
Hamilton DL, Burnham CW, Osborn EF (1964) The solubility of water and effects of oxygen fugacity and water content on crystallization in mafic magmas. J Petrol 5:21–39. https://doi.org/10.1093/petrology/5.1.21
Hernlund J, Leinenweber K, Locke D, Tyburczy JA (2006) A numerical model for steady-state temperature distributions in solid-medium high-pressure cell assemblies. Am Mineral 91:295–305. https://doi.org/10.2138/am.2006.1938
Hildreth W, Moorbath S (1988) Crustal contributions to arc magmatism in the Andes of Central Chile. Contrib Mineral Petrol 98:455–489. https://doi.org/10.1007/Bf00372365
Holland T, Blundy J (1994) Non-ideal interactions in calcic amphiboles and their bearing on amphibole-plagioclase thermometry. Contrib Mineral Petrol 116:433–447. https://doi.org/10.1007/BF00310910
Holloway JR, Blank JG (1994) Application of experimental results to C-O-H species in natural melts. In: Carroll MR, Holloway JR (eds) Volatiles in magmas. Reviews in mineralogy and geochemistry, vol 30. Mineralogical Society of America, Washington, pp 187–230
Holloway JR, Burnham CW (1972) Melting relations of basalt with equilibrium water pressure less than total pressure. J Petrol 13:1–29. https://doi.org/10.1093/petrology/13.1.1
Holtz F, Behrens H, Dingwell DB, Johannes W (1995) H2O solubility in haplogranitic melts: compositional, pressure, and temperature dependence. Am Mineral 80:94–108. https://doi.org/10.2138/am-1995-1-210
Hughes EC, Buse B, Kearns SL, Blundy JD, Kilgour G, Mader HM (2019) Low analytical totals in EPMA of hydrous silicate glass due to sub-surface charging: obtaining accurate volatiles by difference. Chem Geol 505:48–56. https://doi.org/10.1016/j.chemgeo.2018.11.015
Hurlimann N, Müntener O, Ulmer P, Nandedkar R, Chiaradia M, Ovtcharova M (2016) Primary magmas in continental arcs and their differentiated products: petrology of a post-plutonic dyke suite in the Tertiary Adamello Batholith (Alps). J Petrol 57:495–533. https://doi.org/10.1093/petrology/egw016
Kaegi R, Muentener O, Ulmer P, Ottolini L (2005) Piston-cylinder experiments on H2O undersaturated Fe-bearing systems: an experimental setup approaching fO2 conditions of natural calc-alkaline magmas. Am Mineral 90:708–717. https://doi.org/10.2138/am.2005.1663
Keller CB, Schoene B, Barboni M, Samperton KM, Husson JM (2015) Volcanic-plutonic parity and the differentiation of the continental crust. Nature 523:301–307. https://doi.org/10.1038/nature14584
Knipping JL, Webster JD, Simon AC, Holtz F (2019) Accumulation of magnetite by flotation on bubbles during decompression of silicate magma. Sci Rep 9:3852. https://doi.org/10.1038/s41598-019-40376-1
Kress VC, Carmichael ISE (1991) The compressibility of silicate liquids containing Fe2O3 and the effect of composition, temperature, oxygen fugacity and pressure on their redox states. Contrib Mineral Petrol 108:82–92. https://doi.org/10.1007/BF00307328
Lange RA, Carmichael ISE (1987) Densities of Na2O-K2O-CaO-MgO-FeO-Fe2O3-Al2O3-TiO2-SiO2 liquids: new measurements and derived partial molar properties. Geochim Cosmochim Acta 51:2931–2946. https://doi.org/10.1016/0016-7037(87)90368-1
Macpherson CG, Dreher ST, Thirlwall MF (2006) Adakites without slab melting: high pressure differentiation of island arc magma, Mindanao, the Philippines. Earth Planet Sci Lett 243:581–593. https://doi.org/10.1016/j.epsl.2005.12.034
Martel C, Pichavant M, Holtz F, Scaillet B, Bourdier JL, Traineau H (1999) Effects of fO2 and H2O on andesite phase relations between 2 and 4 kbar. J Geophys Res-Solid Earth 104:29453–29470. https://doi.org/10.1029/1999JB900191
Marxer F (2021) Polybaric fractional crystallisation of arc magmas - an experimental study. Zürich: Doctoral Thesis, ETH Zürich, 369 p.
Marxer F, Ulmer P (2019) Crystallisation and zircon saturation of calc-alkaline tonalite from the Adamello Batholith at upper crustal conditions: an experimental study. Contrib Mineral Petrol 174:84. https://doi.org/10.1007/s00410-019-1619-x
Matjuschkin V, Brooker RA, Tattitch B, Blundy JD, Stamper CC (2015) Control and monitoring of oxygen fugacity in piston cylinder experiments. Contrib Mineral Petrol 169:9. https://doi.org/10.1007/s00410-015-1105-z
Melekhova E, Blundy J, Robertson R, Humphreys MCS (2015) Experimental evidence for polybaric differentiation of primitive arc basalt beneath St. Vincent, Lesser Antilles. J Petrol 56:161–192. https://doi.org/10.1093/petrology/egu074
Mills RD, Glazner AF (2013) Experimental study on the effects of temperature cycling on coarsening of plagioclase and olivine in an alkali basalt. Contrib Mineral Petrol 166:97–111. https://doi.org/10.1007/s00410-013-0867-4
Miyashiro A (1974) Volcanic rock series in island arcs and active continental margins. Am J Sci 274:321–355. https://doi.org/10.2475/ajs.274.4.321
Müntener O, Ulmer P (2006) Experimentally derived high-pressure cumulates from hydrous arc magmas and consequences for the seismic velocity structure of lower arc crust. Geophys Res Lett 33:5. https://doi.org/10.1029/2006gl027629
Müntener O, Ulmer P (2018) Arc crust formation and differentiation constrained by experimental petrology. Am J Sci 318:64–89. https://doi.org/10.2475/01.2018.04
Müntener O, Kelemen PB, Grove TL (2001) The role of H2O during crystallization of primitive arc magmas under uppermost mantle conditions and genesis of igneous pyroxenites: an experimental study. Contrib Mineral Petrol 141:643–658. https://doi.org/10.1007/s004100100266
Nandedkar RH (2014) Evolution of hydrous mantle-derived calc-alkaline liquids by fractional crystallization at 0.7 and 0.4 GPa - an experimental study. Zürich: Doctoral Thesis, ETH Zürich, 204 p.
Nandedkar RH, Ulmer P, Müntener O (2014) Fractional crystallization of primitive, hydrous arc magmas: an experimental study at 0.7 GPa. Contrib Mineral Petrol 167:1015. https://doi.org/10.1007/s00410-014-1015-5
Neave DA, Maclennan J (2020) Clinopyroxene dissolution records rapid magma ascent. Front Earth Sci 8:188. https://doi.org/10.3389/feart.2020.00188
Osborn EF (1959) Role of oxygen pressure in the crystallization and differentiation of basaltic magma. Am J Sci 257:609–647. https://doi.org/10.2475/ajs.257.9.609
Osborn EF (1962) Reaction series for subalkaline igneous rocks based on different oxygen pressure conditions. Am Mineral 47:211–226
Pichavant M, Macdonald R (2007) Crystallization of primitive basaltic magmas at crustal pressures and genesis of the calc-alkaline igneous suite: experimental evidence from St Vincent, Lesser Antilles arc. Contrib Mineral Petrol 154:535–558. https://doi.org/10.1007/s00410-007-0208-6
Reubi O, Blundy J (2009) A dearth of intermediate melts at subduction zone volcanoes and the petrogenesis of arc andesites. Nature 461:1269–1273. https://doi.org/10.1038/nature08510
Ridolfi F, Renzulli A (2012) Calcic amphiboles in calc-alkaline and alkaline magmas: thermobarometric and chemometric empirical equations valid up to 1,130 °C and 2.2 GPa. Contrib Mineral Petrol 163:877–895. https://doi.org/10.1007/s00410-011-0704-6
Ridolfi F, Renzulli A, Puerini M (2010) Stability and chemical equilibrium of amphibole in calc-alkaline magmas: an overview, new thermobarometric formulations and application to subduction-related volcanoes. Contrib Mineral Petrol 160:45–66. https://doi.org/10.1007/s00410-009-0465-7
Rutherford MJ (2008) Magma ascent rates. Miner Incl Volcan Process 69:241–271. https://doi.org/10.2138/rmg.2008.69.7
Schwandt CS, Mckay GA (2006) Minor- and trace-element sector zoning in synthetic enstatite. Am Mineral 91:1607–1615. https://doi.org/10.2138/am.2006.2093
Shishkina TA, Botcharnikov RE, Holtz F, Almeev RR, Portnyagin MV (2010) Solubility of H2O- and CO2-bearing fluids in tholeiitic basalts at pressures up to 500 MPa. Chem Geol 277:115–125. https://doi.org/10.1016/j.chemgeo.2010.07.014
Sisson TW, Grove TL (1993a) Experimental investigations of the role of H2O in calc-alkaline differentiation and subduction zone magmatism. Contrib Mineral Petrol 113:143–166. https://doi.org/10.1007/BF00283225
Sisson TW, Grove TL (1993b) Temperatures and H2O contents of low-MgO high-alumina basalts. Contrib Mineral Petrol 113:167–184. https://doi.org/10.1007/BF00283226
Sisson TW, Ratajeski K, Hankins WB, Glazner AF (2005) Voluminous granitic magmas from common basaltic sources. Contrib Mineral Petrol 148:635–661. https://doi.org/10.1007/s00410-004-0632-9
Sparks RSJ, Marshall LA (1986) Thermal and mechanical constraints on mixing between mafic and silicic magmas. J Volcanol Geoth Res 29:99–124. https://doi.org/10.1016/0377-0273(86)90041-7
Spear FS, Kimball KL (1984) RECAMP - a FORTRAN-IV program for estimating Fe3+ contents in amphiboles. Comput Geosci 10:317–325. https://doi.org/10.1016/0098-3004(84)90029-3
Stamper CC, Melekhova E, Blundy JD, Arculus RJ, Humphreys MCS, Brooker RA (2014) Oxidised phase relations of a primitive basalt from Grenada, Lesser Antilles. Contrib Mineral Petrol 167:954. https://doi.org/10.1007/s00410-013-0954-6
Tang M, Erdman M, Eldridge G, Lee CTA (2018) The redox “filter” beneath magmatic orogens and the formation of continental crust. Sci Adv 4:1–7. https://doi.org/10.1126/sciadv.aar4444
Tatsumi Y, Takahashi T (2006) Operation of subduction factory and production of andesite. J Mineral Petrol Sci 101:145–153. https://doi.org/10.2465/jmps.101.145
Thompson AB, Matile L, Ulmer P (2002) Some thermal constraints on crustal assimilation during fractionation of hydrous, mantle-derived magmas with examples from central alpine batholiths. J Petrol 43:403–422. https://doi.org/10.1093/petrology/43.3.403
Turner SJ, Langmuir CH (2015) The global chemical systematics of arc front stratovolcanoes: evaluating the role of crustal processes. Earth Planet Sci Lett 422:182–193. https://doi.org/10.1016/j.epsl.2015.03.056
Ulmer P (2007) Differentiation of mantle-derived calc-alkaline magmas at mid to lower crustal levels: experimental and petrologic constraints. Periodico Di Mineralogia 76:309-325
Ulmer P, Kaegi R, Müntener O (2018) Experimentally derived intermediate to silica-rich arc magmas by fractional and equilibrium crystallization at 1.0 GPa: an evaluation of phase relationships, compositions, liquid lines of descent and oxygen fugacity. J Petrol 59:11–58. https://doi.org/10.1093/petrology/egy017
Villiger S, Ulmer P, Müntener O, Thompson AB (2004) The liquid line of descent of anhydrous, mantle-derived, tholeiitic liquids by fractional and equilibrium crystallization-an experimental study at 1.0 GPa. J Petrol 45:2369–2388. https://doi.org/10.1093/petrology/egh042
Waters LE, Lange RA (2015) An updated calibration of the plagioclase-liquid hygrometer-thermometer applicable to basalts through rhyolites. Am Mineral 100:2172–2184. https://doi.org/10.2138/am-2015-5232
Wood BJ, Banno S (1973) Garnet-orthopyroxene and orthopyroxene-clinopyroxene relationships in simple and complex systems. Contrib Mineral Petrol 42:109–124. https://doi.org/10.1007/BF00371501
Acknowledgements
We would like to thank Lukas Martin, Eric Reusser, and Julien Allaz for assistance during SEM-EDS and EPMA analyses and Andy Huber, Andreas Jallas, and Thomas Good for technical support in the experimental labs. We are grateful to Tom Sisson, Manuel Pimenta Silva, Olivier Bachmann, and Max Schmidt for constructive and enlightening discussions. Thoughtful and constructive reviews from Mike Krawczynski, Andrea Goltz, and an anonymous reviewer as well as the editorial handling by Dante Canil are gratefully acknowledged. This work was supported by the ETH research grant ETH-14 16-1 covering F.M.
Funding
Open Access funding enabled and organized by Projekt DEAL. This work was supported by the ETH research grant ETH-14 16-1 covering F.M.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
We declare no conflicts of interests.
Additional information
Communicated by Dante Canil.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Marxer, F., Ulmer, P. & Müntener, O. Polybaric fractional crystallisation of arc magmas: an experimental study simulating trans-crustal magmatic systems. Contrib Mineral Petrol 177, 3 (2022). https://doi.org/10.1007/s00410-021-01856-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00410-021-01856-8