Abstract
We estimated time scales of magma-mixing processes just prior to the 2011 sub-Plinian eruptions of Shinmoedake volcano to investigate the mechanisms of the triggering processes of these eruptions. The sequence of these eruptions serves as an ideal example to investigate eruption mechanisms because the available geophysical and petrological observations can be combined for interpretation of magmatic processes. The eruptive products were mainly phenocryst-rich (28 vol%) andesitic pumice (SiO2 57 wt%) with a small amount of more silicic pumice (SiO2 62–63 wt%) and banded pumice. These pumices were formed by mixing of low-temperature mushy silicic magma (dacite) and high-temperature mafic magma (basalt or basaltic andesite). We calculated the time scales on the basis of zoning analysis of magnetite phenocrysts and diffusion calculations, and we compared the derived time scales with those of volcanic inflation/deflation observations. The magnetite data revealed that a significant mixing process (mixing I) occurred 0.4 to 3 days before the eruptions (pre-eruptive mixing) and likely triggered the eruptions. This mixing process was not accompanied by significant crustal deformation, indicating that the process was not accompanied by a significant change in volume of the magma chamber. We propose magmatic overturn or melt accumulation within the magma chamber as a possible process. A subordinate mixing process (mixing II) also occurred only several hours before the eruptions, likely during magma ascent (syn-eruptive mixing). However, we interpret mafic injection to have begun more than several tens of days prior to mixing I, likely occurring with the beginning of the inflation (December 2009). The injection did not instantaneously cause an eruption but could have resulted in stable stratified magma layers to form a hybrid andesitic magma (mobile layer). This hybrid andesite then formed the main eruptive component of the 2011 eruptions of Shinmoedake.
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Introduction
Petrologic studies have revealed that pumice eruptions are often preceded by a mixing of mafic magma into pre-existing silicic magma. These events, including the 1991 eruption of Pinatubo (Pallister et al. 1992), the 1663 eruption of Usu volcano (Tomiya and Takahashi 1995), the 1953–1974 eruptions of Southwest Trident volcano (Coombs et al. 2000), the 1929 eruption of Hokkaido-Komagatake (Takeuchi and Nakamura 2001), the Holocene zoned eruption of Volcán San Pedro (Costa and Chakraborty 2004), and many others, suggest that magma mixing triggers eruption. Geodetic studies have also revealed that inflation often occurs prior to eruptions (e.g., Segall 2010), suggesting that the associated magma chambers were over-pressurized by magma injection from depth. However, the relationship between magma injection, magma mixing, and eruption triggering is unclear because injection does not necessarily cause instantaneous mixing if the injected magma is sufficiently denser than the pre-existing magma and has formed stable stratified layers. In such a case, the underlying mafic magma exerts only thermal effects for some time (e.g., Huppert and Sparks 1988; Jellinek and Kerr 1999; Burgisser and Bergantz 2011). Therefore, it is necessary to combine detailed geophysical and petrologic studies to examine and understand pre-eruptive processes.
The 2011 eruption of Shinmoedake volcano, Kirishima volcanic group, South Kyushu, Japan, is an ideal example for such studies because many geophysical, geological, and petrological observations have been conducted on the event (see next section). In this paper, we estimated the timescales of magma-mixing processes prior to the climactic sub-Plinian events on the basis of zoning analysis of magnetite phenocrysts, and we compared them with the time scales of volcanic inflation/deflation processes.
Zoning profiles of phenocrysts have been often analyzed to estimate time scales of various magmatic processes (e.g., Costa et al. 2008). Olivine is one of the most useful minerals for such studies (e.g., Gerlach and Grove 1982; Nakamura 1995; Martin et al. 2008) because it commonly occurs in mafic magma, and its rapid Mg–Fe interdiffusion enables timescales to be estimated at less than 1 month. Recently, Mg in plagioclase has been used to provide time scales of days to years (e.g., Costa et al. 2003, 2008; Druitt et al. 2012; Ruprecht and Cooper 2012). Magnetite phenocrysts are particularly useful in silicic magma systems for detecting the processes within days to months before eruption (e.g., Nakamura 1996; Devine et al. 2003; Chertkoff and Gardner 2004; Tomiya and Takahashi 2005) because of their rapid diffusion (Van Orman and Crispin 2010) and common occurrence in various types of magma. Titanium diffusion profiles of magnetite have often been analyzed to discuss time scales from magma mixing to eruption. Nakamura (1996) analyzed magnetite in dacite from the 1990–1995 lava-dome eruption of Unzen volcano, Japan, and determined time scales of less than several weeks, regardless of the time from the beginning of the eruption. Devine et al. (2003) analyzed magnetite in andesite from the lava-dome eruption of Soufrière Hills volcano, Montserrat, ongoing since 1995, and also determined similar time scales. Both of the authors concluded that injection of high-temperature magma into low-temperature mushy magma occurred continually for years during the dome eruption. Tomiya and Takahashi (2005) analyzed magnetite from one Plinian (rhyolite) and three sub-Plinian (dacite) eruptions of Usu volcano, Japan, and determined time scales of less than several days to several tens of days. They proposed that these time scales corresponded to the time of magma ascent because of similarity to the durations of the precursory seismicity of the eruptions. These studies for Unzen, Montserrat, and Usu all indicated timescales of days to weeks for magma mixing to eruption in silicic magma systems.
In this study, we examined diffusion profiles of Al and Mg in magnetite in addition to those of Ti. Al and Mg are minor elements in magnetite and are useful indicators of magmatic conditions because their sensitivity to such changes is higher than that of the major component ulvöspinel (Usp); thus, they are suitable for detecting magma mixing (Tomiya and Takahashi 2005). As a result, we successfully determined short time scales of approximately 1 day for magma-mixing processes prior to the 2011 eruption of Shinmoedake volcano.
Shinmoedake volcano and the 2011 eruption
Shinmoedake volcano is one of the major cones of the Kirishima volcano group, south Kyushu, Japan (Fig. 1). This volcano consists of lava flows that formed at least 15 ka and a pyroclastic cone that formed approximately 9 ka (Imura and Kobayashi 1991). It has been active since its largest eruption during the Kyoho era in 1716–1717 with repeated sub-Plinian activity, producing 1.7 × 1011 kg (6.8 × 107 m3 dense rock equivalent (DRE)) of pumice falls and pyroclastic flows. Between 1717 and 2008, small phreatic eruptions occurred in 1822, 1959, and 1991. Recent activity began on August 22, 2008, with a minor phreatic eruption (Geshi et al. 2010). In 2010, seven minor phreatic eruptions were also observed from March through July.
The 2011 eruption consisted of numerous eruption events (e.g., JMA (Japan Meteorological Agency) and Yamasato (2011); Miyabuchi et al. 2013). The first was a phreatomagmatic eruption on January 19, after which continuous fumarolic activity was observed in the crater. On January 26, a minor ash discharge started at 07:31 JST (UTC + 9 h). The climactic events began on January 26 at 14:49 JST with phreatomagmatic explosions and included three sub-Plinian eruptions (e.g., Furukawa et al. 2011; Kozono et al. 2013) on that day from 16:10 to 18:40 JST (event P1), and on January 27 from 02:00 to 05:00 JST (event P2), and from 16:20 to 18:00 JST (event P3). The total eruptive volume of the sub-Plinian eruptions was (1.2 to 1.6) × 107 m3 DRE (Kozono et al. 2013). Lava effusion followed the P3 explosion and nearly filled the summit crater by February 1, 2011, forming a lava lake approximately 600 m in diameter, 100 m in depth, and 1.9 × 107 m3 in volume (Shimono et al. 2011). After the lava effusion, approximately 20 Vulcanian explosions were observed through April 2011. The erupted volume of each explosion was less than 106 m3 (Oikawa et al. 2011). Since May 2011, only minor ash discharges and no Vulcanian explosions have been observed. These eruptions were effectively monitored by various geophysical observations including seismic, geodetic, and remote sensing monitoring (e.g., JMA and Yamasato 2011; Kawamoto et al. 2011; Shimono et al. 2011; Shimbori and Fukui 2012; Ueda et al. 2013).
Analytical methods
Samples were collected near Takachiho-gawara (points NF6 and ONHF326) and at Miike Elementary School (point MES) approximately 3 km south–southeast and 7 km southeast from the vent, respectively (Fig. 1b). These points are located along the main distribution axis of the sub-Plinian deposits (Furukawa et al. 2011). In this study, we concentrated mainly on the largest event, P2. Samples from NF6 were collected on the afternoon of January 27, 2011, between events P2 and P3.
Whole-rock compositions of the pumices were determined by X-ray fluorescence at the Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology (AIST). The procedure was similar to that reported by Geshi (2008). Tephra grains were individually pulverized by using a tungsten carbide mill. Ten major elements were analyzed with a PANalytical Axios spectrometer. Glass beads were prepared by the fusion of 0.5 g of the sample and Li tetraborate at a ratio of 1:10. The external error and accuracy in the process were less than 2 %.
Chemical compositions of phenocrysts were analyzed with the JEOL JXA-8900R electron microprobe at the Geological Survey of Japan, AIST. Thin sections of pumices were polished and analyzed. The analytical conditions for quantitative analyses included a 15-kV acceleration voltage and a 12-nA probe current. Counting times for minor elements in magnetite including Al, Mg, and Mn were 60–90 s, which is longer than the 20-s time for other elements (Si, Ti, Fe, Ca, Na, K, and P). The method reported by Stormer (1983) was used in the calculations of ferric/ferrous ratio and Usp component in magnetite.
Partitioning of minor elements in magnetite and melt has been discussed by many researchers (e.g., Sack 1982; Bacon and Hirschmann 1988; Lindsley 1991; La Tourrette et al. 1991; Toplis and Corgne 2002). Recently, Dare et al. (2012) compiled data on partition coefficients for major and trace elements between magnetite and melt, using the Geochemical Earth Reference Model database (http://earthref.org/GERM/). Partitioning of Al, Mg, and Mn between magnetite and melt strongly depends on the melt composition and the presence of co-existing silicate minerals because they are lithophile elements. It may also depend on mineral compositions, temperature, and oxygen fugacity; however, Toplis and Corgne (2002) reported that partitioning of divalent cations into magnetite is approximately independent of oxygen fugacity in spite of the fact that magnetite composition is a strong function of oxygen fugacity. For the magma compositions investigated here (calc–alkaline andesite), it is known that lithophile elements such as Mg (Mg/Mn) and Al decrease in magnetite during fractionation of a silicate melt (e.g., Dare et al. 2012). Thus, we here refer to a zoning pattern that shows an increase in Al and Mg toward the rim as “reverse zoning.”
Results
Compositions of bulk rocks, silicate minerals, and melt inclusions
The products of the sub-Plinian eruptions are composed mainly of phenocryst-rich (28 vol% on a vesicle-free basis) gray pumice of calc–alkaline andesite with a SiO2 content of 57 wt% (Figs. 2 and 3; Table 1). A small amount of andesitic–dacitic white pumice with an SiO2 content of 62–63 wt% and gray and white banded pumice (Fig. 2c) is also present. Chemical compositions of the gray pumices are similar to those of volcanic bombs and lapilli from Vulcanian eruptions during February 1 and 14 and gray pumice of the 1716–1717 eruption. Chemical compositions of the white pumices are similar to those of white pumice from the 1716–1717 eruption, that is, both eruptions show bimodal distribution in bulk rock compositions.
Phenocryst assemblage of the 2011 eruptive products includes plagioclase, clinopyroxene, orthopyroxene, olivine, magnetite, and ilmenite. This assemblage is common in gray, white, and banded pumices. Compositions of silicate minerals are shown in Figs. 4, 5, and 6 (after Saito et al. 2011). Recently, Suzuki et al. (2013) reported similar observations and obtained similar magma processes to those made in Saito et al. (2011) and this study, including mixing between silicic magma and mafic magma in short time scales. Plagioclase forms the dominant phenocrysts. Their zoning patterns are complex, showing oscillatory zoning, patchy zoning, and sieve texture. In addition, they exhibit variable compositions (An 51–92, where An = 100 × Ca/(Ca + Na) in moles; Fig. 4). Two peaks appear at approximately An 55 and An 90 in the core composition. The rim and groundmass compositions are generally An 70, which is between the two peaks. Clinopyroxene phenocrysts are relatively homogeneous in composition (Mg* 70 to 74, where Mg* = 100 × Mg/(Mg + Fe) in moles; Fig. 5). Orthopyroxene phenocrysts are also relatively homogeneous in composition (Mg* 64 to 68), although some exhibit high Mg* (>70). Orthopyroxene and clinopyroxene phenocrysts often show reverse zoning in Mg* within rims approximately 10 μm in width. The two-pyroxene thermometer of the QUILF software (Lindsley and Frost 1992) was used to determine that most pairs, including core–core and rim–rim, indicate equilibrium temperatures of 900–1,000 °C, although some rim–rim pairs show higher temperatures at 1,050–1,150 °C. Olivine phenocrysts show homogeneous cores (Mg* 75–80; Fig. 6) and normal zoning near the rims up to several tens of microns (Fig. 7), with or without reaction rims of orthopyroxene.
Phenocryst aggregates are common in all types of pumice, and their mineral assemblage is typically plagioclase + orthopyroxene + clinopyroxene + magnetite + ilmenite. Neither high-Ca (approximately An 90) plagioclase nor olivine is included in such aggregates.
Melt inclusions in phenocrysts (Saito et al. 2011; Saito 2012) are basaltic andesite (SiO2 54 wt%) in olivine and rhyolite (SiO2 75 wt%) in low-Ca plagioclase and in pyroxene. Dacitic (SiO2 68 wt%) melt inclusions are also observed in pyroxene.
Composition and zoning profiles of Fe–Ti oxides
Magnetite phenocrysts in the 2011 pumices show various compositions. On the basis of their zoning profiles and core compositions, we classified magnetite phenocrysts into three types: A0, A1, and B (Figs. 8, 9, and 10; Table 2). Type A0 has low Mg (MgO < 2.0 wt%; Mg/Mn < 8) and low Al (Al2O3 < 2.2 wt%) homogeneous cores (Fig. 8a, b, c, d) and exhibits faint reverse zoning with slightly higher Mg near the rim in both gray and white pumices (Fig. 10a). The sizes of type A0 phenocrysts are larger than other types and are typically more than 100 μm or up to approximately 300 μm in radius (Table 3). Type A1 has slightly higher Mg and Al cores than those of type A0 (Fig. 8a, b, c, d) and shows remarkable reverse zoning with higher Mg and Al contents toward the rim in gray pumice but weak reverse zoning in white pumice (Fig. 10b, f). Subtype A1’ has higher Mg and Al cores than type A1 (Fig. 8b, d) and lacks the homogeneous cores (Fig. 10g) observed in A1 (Fig. 10f). The core compositions gradually change from type A1 to type A1’, and the rim compositions of these two types nearly overlap (Fig. 8b, d). The sizes of type-A1’ magnetite are smaller than approximately 70 μm in radius (Table 3); thus, they are identified as microphenocrysts. Type B has a distinctly higher Ti (XUsp > 0.32, where XUsp is mole fraction of Usp component) content than that in all types and a higher Al composition than that of type A1 (Fig. 8b, d). Subtype B’ has the highest Mg (MgO > 3.0 wt%; Mg/Mn > 15) and Al (Al2O3 > 3.0 wt%) core compositions (Fig. 8b, d) and lacks the homogeneous cores (Fig. 10h) observed in type B (Fig. 10g). The sizes of type-B’ magnetite are smaller at approximately 25–40 μm in radius; thus, they are identified as microphenocrysts.
The rim composition (MgO, Al2O3) of type A0 is similar to the core composition of type A1 (Fig. 8a, b, c, d). The rim composition of type A1 is similar to the core compositions of type A1’ and type B’ (Fig. 8b, d). The rim compositions of types A1’ and B are similar to the core composition of type B’ (Fig. 8b, d). The rim composition of type B’ is higher in Al2O3 and lower in XUsp (Fig. 8b, d), thus we propose a hidden end member, X, beyond the rim compositions. Type A1 is the most abundant. Apparent ratios of types A0, A1, and B are 14 %, 62 %, and 24 % in the gray pumice and 50 %, 50 %, and 0 % in white pumice, respectively, for P2.
Ilmenite phenocrysts have no (P2) or thin (P3) reaction rims of magnetite that are several microns in thickness. Two types of ilmenite were identified on the basis of core compositions (Fig. 8e, f). One has low Mg (MgO < 3.0 wt%; Mg/Mn < 13), low Al (Al2O3 < 0.35 wt%), and high XIlm cores, and the other has high Mg (MgO > 3.5 wt%; Mg/Mn > 15), high Al (Al2O3 > 0.4 wt%), and low XIlm cores, where XIlm is mole fraction of ilmenite (Ilm) component. According to Bacon and Hirschmann (1988), Mg/Mn of equilibrium magnetite for the first type of ilmenite (Mg/Mn = 10 to 13) is approximately 7–9, which corresponds to type A0 magnetite (Fig. 8a, b). Similarly, equilibrium magnetite for the second type of ilmenite (Mg/Mn = 15–19) is approximately 10–13, which corresponds to type A1 magnetite. Thus, we consider the first type of ilmenite to be type A0 and the second to be type A1. No ilmenite was determined to be in equilibrium with type B magnetite.
Types A0 and A1 ilmenite with no reaction rims show faint or no reverse zoning (Figs. 8e, f and 11a, b). Near the contacts between type A1 magnetite and type A1 ilmenite grains in aggregates, compositions significantly change toward the contacts (Fig. 11c), that is, XUsp and MgO in magnetite significantly increase and Al2O3 in magnetite decreases toward the contact.
Fe–Ti oxide geothermometry
We estimated magmatic temperatures by using the magnetite–ilmenite geothermometer described by Andersen and Lindsley (1985) with Stormer (1983). According to a comparison of four representative methods (Blundy and Cashman 2008) in addition to the recommendation of Gardner et al. (1995), we judged that the method by Andersen and Lindsley (1985) with Stormer (1983) is the best choice for a temperature range in the present study because it gave the smallest average absolute deviation (±33 °C); other methods gave more scattered or biased results (Fig. 13 of Blundy and Cashman 2008). Ilmenite phenocrysts often form aggregates with types A0 and A1 magnetite. From the cores of magnetite and ilmenite, we obtained 875 °C and log fO2 = −11.4 for type A0 and 889 °C and log fO2 = −11.1 for type A1, respectively. From the points adjacent to (<approximately 5 μm) the contact between type A1 magnetite and type A1 ilmenite grains in aggregates, we obtained temperatures of 933–966 °C and log fO2 = −10.6 to −10.1. These estimates are consistent with those by two-pyroxene thermometry, which is approximately 900–1,000 °C.
Discussion 1: magma-mixing processes
End members of magma mixing
Two types of magma were identified on the basis of silicate mineral compositions such as bimodal distribution in plagioclase compositions (approximately An 55 and An 90; Saito et al. 2011) and mineral assemblage of phenocryst aggregates. One is a low-temperature silicic magma that contains low-Ca (approximately An 55) plagioclase, orthopyroxene, clinopyroxene, magnetite, and ilmenite with a rhyolitic melt. The other is a high-temperature mafic magma that contains high-Ca (approximately An 90) plagioclase and olivine with a basaltic–andesitic melt. Clearly, the two contrasting types of magma were mixed prior to the sub-Plinian eruption of Shinmoedake. The intermediate composition (An 70) of plagioclase rims and groundmass plagioclase represents conditions after the magma mixing.
Magnetite data also provided evidence of mixing between high- and low-temperature magmas, such as the reverse zoning apparent in most of the magnetite phenocrysts and the increase in temperature from the cores to the contacts between magnetite and ilmenite. The temperatures from the cores of magnetite and ilmenite (875–889 °C) and those from the contacts between magnetite and ilmenite (933–966 °C) represent the conditions before and just after the magma mixing, respectively. The reverse zoning was formed by diffusion rather than growth because the widths of zoning differed among the elements (Fig. 10). The absence or thin appearances of reverse-zoned rims of pyroxene or reaction rims of ilmenite also confirm that the magma mixing occurred just prior to the eruptions.
On the basis of magnetite compositions, the three types of magnetite contribute to discussions of more detailed processes. First, we consider that type A0 magnetite represents the low-temperature end member of the magma-mixing process because this type has the lowest Mg and Al contents and homogeneous cores, indicating stable conditions prior to magma mixing. In addition, type A0 was little affected by heating and showed reverse zoning due to magma mixing. The origin of type A1 is similar to that of type A0 but originated from a portion in which the effects of magma mixing were more significant. The variable rim compositions of type A1 suggest local heterogeneity in melt compositions and temperature during the magma mixing. We also consider type A1’ magnetite to be of the same origin as type A1 magnetite for the following reasons: Core compositions change from types A1 to A1’ gradually; the core composition of type A1’ magnetite are between those of the core and rim of type A1 magnetite (Fig. 8); and no homogeneous Al2O3 core is present in type A1’ magnetite. These features indicate that type A1’ magnetite was originally type A1 magnetite that experienced significant diffusion to the core. The small sizes of type A1’ grains (Table 3) also support this interpretation. An additional possibility is that type A1’ magnetite is actually type A1 magnetite; however, its true center was not included in the thin section. This possibility, however, can be disproved because the sectioning effect on type A1 magnetite (Fig. 10b, f) results in a zoning profile that shows a decrease in MgO from the rim to core with an Al2O3 decrease. Zoning profiles of type A1’ magnetite, however, show that MgO is nearly flat (Fig. 10c) with decreasing Al2O3 from rim to core (Fig. 10g).
Despite having the highest MgO and Al2O3 contents, type B’ magnetite is not a representative high-temperature end member because it also shows reverse zoning with an increase in Al2O3 toward the rim (Figs. 8 and 10), indicating that type B’ magnetite was also heated by high-temperature magma. Thus, no magnetite is present in the high-temperature magma that contained high-Ca plagioclase and olivine. We consider that type B’ magnetite originated from mixed magma that was formed between low- and high-temperature end members because its core compositions are similar to the rim compositions of types A1, A1’, and B.
Although its XUsp is much higher than other types, we consider type B to be an intermediate between types A1 and B’ on the basis of the following observations: Al2O3 contents of the cores of type B magnetite are between type A1 (A1’) and type B’ magnetite (Fig. 8b, d); common or continuous conditions between types B and B’ magnetite were indicated by the common negative correlation between XUsp and Al2O3 (Fig. 8d) and the common zoning pattern in XUsp of a decrease toward the rim (Fig. 10k, l); and Mg/Mn of the cores and the zoning pattern of MgO of type B magnetite are similar to those of type A1 magnetite (Figs. 8b and 10b, c). Thus, type B magnetite has characteristics intermediate between types A1 and B’ magnetite. When we arrange the types of magnetite in ascending order of Al2O3 as types A0, A1, A1’, B, and B’, the values of XUsp are nearly constant from type A0 to type A1’ before abruptly increasing between types A1’ and B and gradually decreasing to type B’ (Fig. 8d). Because only types A0 and A1 magnetite coexist with ilmenite, we consider that the abrupt jump of XUsp, showing an increase in Ti content in magnetite, corresponds to the vanishing point or stability limit of ilmenite; below this point, XUsp is buffered and is nearly constant with the low value of 0.28 to 0.29, owing to the presence of ilmenite. The negative correlation between Al2O3 and XUsp of types B and B’ magnetite can be explained by elemental partitioning of Al and Ti in magnetite (Lindsley 1991).
We here consider four types of magma, A0, A1, B, and X, which originally contained types A0, A1 (+A1’), B (+B’), and no magnetite, respectively (Fig. 12; Table 4). Magma A0 was the low-temperature end-member silicic magma and contained low-Ca (approximately An 55) plagioclase, orthopyroxene, clinopyroxene, type A0 magnetite, and type A0 ilmenite. Magma A1 was similar to magma A0 but was significantly heated just prior to the eruption, as evidenced by the significant reverse zoning of type A1 magnetite; this is in contrast to magma A0, which was not significantly heated and preserved the characteristics of the low-temperature end-member magma. Magma A0 was likely mushy magma because its crystal content should have been higher than 28 vol%. Magma X is the high-temperature mafic end-member magma and contains high-Ca (approximately An 90) plagioclase and olivine. Magma B is intermediate magma formed by further heating of magma A1 and mixing between low-temperature (A0 or A1) and high-temperature (X) magmas.
According to the bulk-rock and melt-inclusion compositions of the eruptive products, we consider magma A0 and magma X to be dacite (SiO2 ≥ 63 wt%) and basalt or basaltic andesite (SiO2 ≤ 54 wt%), respectively (Table 4). Magmas A1 and B were not end members but were modified or mixed magma. Magma B in particular may reflect local conditions because of its low frequency of appearance.
Neither type of magma erupted solely; rather, their eruptions were mixed. White pumice (andesitic dacite) was comprised of magma A0 + magma A1. Gray pumice (andesite) was comprised of mainly magma A1 with small contributions of magmas B, X, and A0.
Mixing processes
Figure 12 shows a schematic diagram of the magma-mixing processes just prior to the 2011 eruption. Mixing between magmas A1, B, and X formed the significant reverse zoning of types A1 and B magnetite. Hereafter, we refer to this process (A1 + B + X) as mixing I. An additional mixing with magmas A0 formed the slight reverse zoning of type A0 magnetite. Hereafter, we refer to this latter process (+A0) as mixing II. Gray pumice was formed by two-stage mixing (A1 + B + X) + A0; mixing I initially formed the main part of the gray pumice, and mixing II modified it. White pumice was formed only by mixing II (A1 + A0). Banded pumice was formed in the later stage of mixing II.
Magma A1 already had slightly higher temperatures and was slightly more mafic than magma A0 when mixing I began. This result was deduced from the higher Mg and Al cores of type A1 magnetite over those of type A0 (Fig. 8). Therefore, Magma A1, the main component of the 2011 eruptive products, could have been a mobile layer (Burgisser and Bergantz 2011) that was formed long before the eruption by reheating of the mushy magma body (magma A0). Eruption of mobile-layer magma is often a precursory phase of large Plinian eruptions (Takeuchi 2004, 2011). In such cases, the eruptive products of the main Plinian phase are composed of phenocryst-rich silicic magma from the main part of a mushy magma chamber. Because of high viscosity, the mushy main part is not able to erupt solely but can follow less-viscous precursory magma, which occurred during the 1991 eruption of Pinatubo (Pallister et al. 1992) and the 1929 eruption of Hokkaido-Komagatake (Takeuchi and Nakamura 2001). In the cases of the 2011 eruptions of Shinmoedake, however, the main part (magma A0) did not erupt as a large Plinian eruption. This result may indicate that the magma chamber of Shinmoedake did not have sufficient eruptibility (Takeuchi 2011) at that time and that only the mobile layer (magma A1) could erupt with a minor contribution of the main part (magma A0) of the magma chamber.
Discussion 2: time scales of the magma-mixing processes
Diffusion coefficients in magnetite
Diffusion coefficients and chemical behaviors of Mg and Al differ from those of Ti. We combined these elements in order to (1) distinguish whether the zoning profiles were formed by diffusion or crystal growth, (2) detect processes that did not change Ti content, and (3) estimate shorter time scales than those estimated by Ti diffusion.
The diffusion coefficient depends on various factors such as temperature, oxygen fugacity, and chemical composition. We calculated the diffusion coefficient of Ti by using the equation of Van Orman and Crispin (2010) with a temperature of 950 °C, log fO2 = −11, and XUsp = 0.3, which corresponds to the conditions just after the mixing of magmas A1 and B. The diffusion coefficient of Al is assumed to be the same as that of Ti because the available diffusion coefficient data for Al and Ti are similar (Van Orman and Crispin 2010). Moreover, the diffusion widths of these elements in our zoning profiles are similar (Fig. 10). Thus, we obtained a coefficient of 4.3 × 10−16 m2/s for Ti and Al. If we assume a temperature of 900 °C, which corresponds to the condition at the beginning of the magma mixing, we obtain 6.9 × 10−16 m2/s. The reason why diffusion coefficient increases with decreasing temperature (e.g., Fig. 23 of Van Orman and Crispin 2010) is that a vacancy mechanism, which has strong negative activation enthalpy, becomes dominant in lower temperatures than those occurring with an interstitial mechanism. Therefore, the diffusion coefficient has a minimum value at a temperature of approximately 980 °C for Ti. The error caused by temperature uncertainty is thus small (less than a factor of 2) because the temperature of concern is near this minimum value.
The diffusion coefficient of Mg in magnetite has rarely been reported and has not been cited even in the most comprehensive review papers (e.g., Costa et al. 2008; Van Orman and Crispin 2010). Only experiments by Semberg et al. (2011) estimated the value to be approximately 10−15 to 10−16 m2/s at 900 °C. We here consider the coefficient to be the same as that of Fe for the following reasons: The available diffusion coefficient data of divalent cations of Fe, Mn, Co, and Ni are similar and are significantly higher than those of Ti and Al under our conditions of interest (Van Orman and Crispin 2010); the diffusion coefficients of Mg and Fe are the same in spinel (Liermann and Ganguly 2002), which is a mineral similar to magnetite; and the diffusion widths of Mg and Fe in our zoning profiles are similar. Because the zoning profiles of Mg and Fe are complementary with an Mg increase accompanied by an Fe decrease and vice versa (Fig. 10), coupled diffusion is indicated between the cations. The diffusion coefficient of Fe was calculated by using the equation of Van Orman and Crispin (2010) with the same condition as for Ti. Thus, we obtained 4.4 × 10−15 m2/s for Mg, which is consistent with the experimental results of Semberg et al. (2011). If we assume a temperature of 900 °C, we obtain 6.6 × 10−15 m2/s. The diffusion coefficient for Fe has a minimum value at about 950 °C; therefore, the error caused by temperature uncertainty is also small at less than a factor of 2.
Fitting calculation
We estimated diffusion time to constrain the time scales of the magma mixing by fitting a simple diffusion model to the observed zoning profiles (Fig. 13a). We considered a grain as an isotropic sphere with homogeneous initial composition, fixed rim composition during diffusion, and no crystal growth to obtain a simple, spherically symmetrical diffusion model (e.g., equation 6.1 and Fig. 6.1 of Crank 1975). We solved the diffusion equation numerically by using the finite difference method. Examples of fitting calculations are shown in Figs. 9b and 13a; fitting parameters and estimated time scales are listed in Table 3.
Estimated time scales from magma mixing to eruption
The estimated time scales are shown in Fig. 13b; each point corresponds to one zoning profile. The estimated time scales may have an error of a factor 2 to 4 or more (Costa et al. 2008) due to the error of fitting, the uncertainties in the diffusion coefficients, and possible sectioning effects.
The estimated diffusion time of type A1 magnetite is 0.4 to 3 days with an average of 1.1 days, and that of type B magnetite is 0.5 to 0.9 days (Fig. 13b). These times correspond to the time of mixing I until eruption. The diffusion time of type B’ magnetite can also be calculated if the proper initial conditions are chosen. However, it is difficult to determine such conditions properly for type B’ magnetite because there are no flat cores, which are the most probable initial conditions. Thus, the time scales of type B’ magnetite are not discussed here. The diffusion time of type A0 magnetite is 0.04 to 0.4 days with an average of 0.13 days (Fig. 13b); this time corresponds to the time of mixing II until eruption. The lower limit is further lowered if we consider the grains with no reverse zoning, which represent almost no diffusion time. Most of the time scales obtained by previous studies for pre-eruptive processes that used zoning profiles of phenocrysts were a few days to a few years (Costa et al. 2008). The estimated time scales for mixing I and mixing II thus belong to the shortest group among them.
Deduced from its significant effects on zoning profiles, mixing I was the dominant process and likely triggered the eruption. Mixing II followed mixing I because the time scale was shorter than and almost continuous with that of mixing I. Mixing II was thus a subordinate process and likely accompanied magma ascent. Formation of banded pumice occurred during ascent in the later stage of mixing II. Thus, mixing I was pre-eruptive mixing, whereas mixing II was syn-eruptive mixing. However, they could have occurred sequentially, likely by a single triggering mechanism.
It may have been possible for additional mixing events to occur prior to mixing I that were not recorded in magnetite because this mineral was completely re-equilibrated; however, we can show that this possibility is unlikely given the following. The maximum (upper limit) diffusion time that we can detect, t max, is estimated to be t max ∼ 0.4 a 2/D because a zoning profile with non-dimensional time (Dt/a 2) larger than approximately 0.4 is almost flat and yields no information (Fig. 13a). For example, the t max of Ti and Al in magnetite is 108 days when the radius a is 100 μm. The estimated non-dimensional times for mixing I are well below this upper limit (Dt/a 2 < 0.4; Table 3). Furthermore, no mixing events occurred between mixing I and t max prior to the January 26–27, 2011, eruptions. On the other hand, we could not detect mixing events that occurred more than t max prior to the eruptions.
We therefore obtained time scales from zoning profiles of Mg in olivine phenocrysts (Fig. 7b; Saito 2012; Saito (2012, in preparation)) because t max for olivine was longer than that for magnetite. Olivine phenocrysts show normal zoning within several tens of microns from the rim. The diffusion model discussed previously (Crank 1975) gives diffusion times of 1 to 10 days by using 1.65 × 10−16 m2/s as the diffusion coefficient of Mg for a- and b- axes in olivine at 960 °C (Johnson et al. 2008). These times are consistent with the time of mixing I obtained by types A1 and B magnetite. The t max of Mg in olivine is 281 and 1,120 days when the radius is 100 and 200 μm, respectively. Zoning profiles of olivine thus reveal that the mafic magma did not significantly mix into the silicic magma for months or years until that occurring 1 to 10 days prior to the eruption.
Magma-mixing process without crustal deformation
We determined that a significant magma-mixing process (mixing I) occurred 0.4 to 3 days prior to the sub-Plinian eruptions (Fig. 13b). Then, we compared the result with geodetic observations. Continuous inflation has been observed by Global Positioning System (GPS) since December 2009 (Kawamoto et al. 2011), and remarkable deflation was observed by GPS and tiltmeters during the sub-Plinian eruptions and lava effusion (Ueda et al. 2013). However, no significant change was observed within several days before the sub-Plinian eruptions (Fig. 14), as well as no increase in seismicity. Therefore, mixing I was not accompanied by a significant change in volume of the magma chamber. We consider that magmatic overturn of a pre-existing stratified magma chamber (e.g., Ruprecht et al. 2008; Woods and Cowan, 2009; Burgisser and Bergantz 2011) or melt accumulation within the magma chamber (e.g., Gudmundsson 2012) is probable. Injection of a new magma batch from the outside, on the contrary, can be excluded because it should be accompanied by significant volume change.
The time difference between the beginning of magma mixing and that of magma injection may vary among volcanoes; here, we consider that the former is recorded in crystals, and the latter is observed as volcanic unrest, including crustal deformation. The former and the latter were several days and 13 months prior to the 2011 eruption of Shinmoedake, respectively. On the other hand, Kahl et al. (2011, 2013) determined that the beginning of magma mixing recorded in olivine crystals from a recent eruption of Mt. Etna correlates to that of several signs of volcanic unrest. In the case of Etna, the contrast between the mixing end members was smaller, and both magmas were less viscous than those of Shinmoedake, so that the magmas could have easily mixed with no significant time difference.
Finally, we consider the re-homogenization process of type A0 magnetite into type A1 magnetite in the hybrid magma or mobile layer (Fig. 12). The re-homogenization process is implied because the type A1 magnetite is homogeneous in white pumice (Fig. 10b, f, j, n). The formation of homogeneous type A1 grains by diffusion of type A0 grains requires a minimum of about 30 days, according to the t max of Ti and Al in magnetite. The re-homogenization time is consistent with the beginning of ground inflation in December 2009; therefore, the formation of the hybrid magma and the ground inflation may have begun at the same time.
The injection of high-temperature mafic magma into the pre-existing mushy silicic magma was likely continuous and gradual over 13 months from December 2009, as evidenced by the continuous inflation. The density and viscosity contrast between the mafic and silicic magmas prevented the mafic injection from causing an immediate eruption and instead initially resulted in stable stratified magma layers (Fig. 12a, b). The silicic magma was heated by the underlying mafic magma and was partly re-melted and loosened to form a mobile layer (hybrid andesite in Fig. 12) (e.g., Jellinek and Kerr 1999; Kaneko and Koyaguchi 2004; Burgisser and Bergantz 2011). Despite continuous injection, eruptions and further significant mixing did not occur until this relatively static process suddenly changed to a dynamic process to exhibit overturn on January 2011. The mechanism of this sudden change is an important issue in the forecasting of eruptions. Since such activity is difficult to detect by geodetic and seismic observations, we should consider additional methods appropriate for such processes.
Conclusions
We estimated time scales of magma-mixing processes just prior to the 2011 sub-Plinian eruptions of Shinmoedake volcano mainly on the basis of zoning analysis of magnetite phenocrysts. A significant pre-eruptive mixing process, mixing I, occurred several days before the eruptions and triggered the eruptions. Because this process was not accompanied by significant crustal deformation, magmatic overturn within the magma chamber was a probable mechanism. In addition, subordinate syn-eruptive mixing processes, mixing II, occurred only several hours prior to eruptions during the magma ascent. These mixing events likely occurred continually before and after the beginning of the eruptions. Mafic injection began more than several tens of days prior to mixing I, likely coinciding with the beginning of the inflation in December 2009, to form the hybrid andesite mobile layer. This hybrid andesite was the main eruptive component of the 2011 eruptions of Shinmoedake.
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Acknowledgments
We thank Ryuta Furukawa, Shun Nakano, Teruki Oikawa, Tetsuo Kobayashi, and the Japan Meteorological Agency (JMA) for providing the samples used in this research. Teruki Oikawa also provided photos of pumice. We thank the JMA and the Geospatial Information Authority of Japan for providing geodetic data. We acknowledge valuable discussions with Hiroshi Shinohara and Shingo Takeuchi. Comments on the earlier version by Mary R. Reid were very helpful in improving the manuscript. Careful reading and valuable comments by Paul J. Wallace and two anonymous reviewers greatly improved the manuscript. This work was partly supported by a Japan Society for the Promotion of Science (JSPS) Grant-in-Aid for Scientific Research (KAKENHI No. 23540564 to A.T.).
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Tomiya, A., Miyagi, I., Saito, G. et al. Short time scales of magma-mixing processes prior to the 2011 eruption of Shinmoedake volcano, Kirishima volcanic group, Japan. Bull Volcanol 75, 750 (2013). https://doi.org/10.1007/s00445-013-0750-1
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DOI: https://doi.org/10.1007/s00445-013-0750-1