Introduction

Large-scale explosive eruptions that eject more than 100 km3 of magma are one of the most severe natural disasters on Earth, which have devastating impacts on human activities, both at regional and global scales1,2,3,4,5,6. Such eruptions have various styles reflecting their tectonic environment, magma-system structures, and eruption-evolution processes7. Among them, one of the typical sequences involves a preceding Plinian eruption phase and/or an eruption of minor ignimbrite from a subsidiary vent, followed by caldera collapse and a catastrophic pyroclastic eruption from a ring-vent system7,8,9,10,11,12. However, such “initial” activities do not always lead to a catastrophic caldera-forming eruption, as most Plinian eruptions cease without caldera collapse13,14. Therefore, understanding the triggering mechanisms of caldera collapse is essential for predicting the evolution of such catastrophic explosive eruptions and for appropriate-disaster management responses6. Several theoretical approaches predict the decompression in a magma chamber required for the activation of caldera faults to induce caldera collapse7,15,16. Few previous studies, however, have documented the amount of the decompression of the magma chambers in natural caldera-forming eruptions based on petrological investigations of the erupted magmas17. The degree of decompression for the activation of caldera faults may be variable among different calderas, as the activity of caldera faults is controlled by the degree of fault-system development and the tectonic stress environment in the host rock7,15,16. Therefore, it is necessary to verify the decompression process of the magma chamber for each caldera-forming eruption using petrological evidence and to accumulate knowledge on the decompression conditions that induce caldera collapse.

Here, based on the variation in water content within volcanic glasses trapped in phenocrysts, we show that decompression of the magma chamber preceded caldera collapse, which resulted in a VEI 7 eruption at Aira volcano18 in southern Kyushu Island, Japan. Microanalytical measurements of the water content of volcanic glasses in the products of a geologically young caldera-forming eruption reveal the decompression process of the magma chamber that preceded caldera collapse. We traced the decompression of the magma chamber using the change in the water content in glass embayments within phenocrysts19,20,21,22,23 throughout the eruption sequence from the precursory stage to the main ignimbrite-forming eruption. Using the estimated decompression in the magma chamber, we also modeled the expected ground deformation in and around Aira volcano during the initial Plinian eruption phase.

Caldera-forming eruption of Aira volcano

The caldera-forming eruption of Aira volcano at around ~30,000 years ago (named the AT eruption) ejected approximately 400-km3 dense-rock equivalent (DRE) of high-silica rhyolite magma, which makes it one of the largest late-Pleistocene eruptions in the northwestern rim of the Pacific18,24.

Aira caldera is one of the collapse calderas within the north–south trending Kagoshima graben in the southern part of Kyushu Island18,24,25 (Fig. 1a). Though several minor ignimbrites older than the Ito pyroclastic flow (mainly erupted in the middle Pleistocene) are distributed around the Aira caldera, there is no clear evidence for the existence of a collapse caldera at the present location of the Aira caldera before the AT eruption24.

Fig. 1: Overview of AT-eruption products.
figure 1

a Distribution of products of the AT eruption. Inset shows the location of the Aira caldera. The solid red line indicates the topographic rim of the Aira caldera, broken blue lines are the isopach lines that represent the thickness of the Osumi pumice fall deposit, and the pink-colored area represents the distribution area of Ito ignimbrite. Orange circles with labels “O”, “T”, “I”, and “A” show the sampling locations of the Osumi pumice deposit, Tsumaya pyroclastic flow deposit, Ito ignimbrite, and the AT ash fall deposit, respectively. b Schematic stratigraphy of the eruptive products of the AT eruption showing sampling depths. c Optical microscopic image of glass embayments in a quartz phenocryst of the Osumi pumice fall deposit (sample id: 140901F8). This microphotograph was taken through a polished surface of a quartz phenocryst embedded in epoxy resin, showing the glass embayments on the crystal surface of the quartz. Labels “g” indicate representative glass embayments. Labels “b” show the bubbles in glass embayments. d Backscattered electron image of a quartz phenocryst (Qz) with several glass embayments (g) found in a quartz phenocryst from the Osumi pumice fall deposit (sample id: 171129C2). e Distribution of water content in the glass embayment and surrounding groundmass glasses. The colored circles indicate the analysis point and the color of each circle represents the quantified water content at each analysis point.

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Similar to many caldera-forming eruptions, the sequence of the AT eruption had an initial stage with a Plinian phase and a minor phreatomagmatic pyroclastic flow that preceded the subsequent massive ignimbrite-forming phase with caldera collapse18,24. Approximately 50 km3 of magma erupted during the initial stage to produce the Osumi pumice fall deposit (~40-km3 DRE26,27) from the southern caldera rim26, and subsequent Tsumaya pyroclastic flow deposit (~10-km3 DRE28) erupted from the northern part of the caldera24. The remaining 350 km3 of magma erupted to form a massive ignimbrite (Ito ignimbrite and its co-ignimbrite ash fall deposit named Aira-Tn ash fall deposit)18,24 after the onset of the caldera collapse, which is marked by the massive lag breccia at the base of the ignimbrite18,24,29 (Fig. 1).

Lack of evidence of a clear time gap, such as erosional surfaces or a pronounced oxidation zone in these deposits18,24,29, suggests that all units of the AT eruption were emplaced continuously within a short period. Duration of the Plinian phase of the Osumi pumice fall deposit at the beginning of the AT eruption is estimated as ~2.8 days based on the total mass of the pumice fall deposit26,27 (~40 km3, corresponding to ~1 × 1014 kg) and the magma-discharge rate30 (~4.2 × 108 kg s−1) estimated from the distribution of the deposit. No clear flow and cooling unit were identified within the Ito ignimbrite, which implies a short duration for the eruption and emplacement of the ignimbrite18,24,29. The analysis of the seasonal variation of the pollen fossils found in the products of the AT eruption also suggests that the AT eruption lasted 1–2 months31.

Most of the products of the AT eruption have a high-silica rhyolite composition with whole-rock SiO2 content between 74 and 77 wt%32,33. The phase-equilibrium relationship of the phenocrysts and the volatile concentrations in the glass inclusions in the phenocrysts suggest that the rhyolite magmas were stored at 140–260 MPa, corresponding to ~5–10 km below sea level assuming the density of the host rock as 2700 kg m−332,33.

Results

We measured the water contents in glass embayments and glass inclusions in the phenocrysts of the ejecta throughout the AT-eruption sequence. A glass embayment is a glass-filled channel found inside a phenocryst, one side of which is open to the surface of the phenocryst and connected to the external groundmass glass, and the other side is closed inside the phenocryst. The glass embayments are filled by silicate glasses with rhyolite composition (~78 wt% of SiO2) (Supplementary Data 1 and 2).

We measured the distribution of water content inside the glass embayments as a function of the distance from the embayment entrance to reveal the profile of water content along the glass embayments (Fig. 2a). In cases where the water content at the deeper part of the embayment is greater than 5 wt%, the water content inside the embayment is relatively constant and decreases toward the entrance of the embayment within 50–100 micrometers from the entrance. In cases where the water content at the deeper part of the embayment is less than 5 wt%, the water content inside the embayment is almost constant. The relatively flat profile of the water content at the deeper part of the glass embayment is named “plateau”.

Fig. 2: Variations in water content in glass embayments and inclusions.
figure 2

a Line profile of water content along the glass embayments. The distance shown in the horizontal axis of each diagram corresponds to the depth of the measured point from the entrance to the glass embayment. b Variation in water content of the plateau part of the glass embayment found in the quartz phenocrysts (deeper than ~100 μm from the surface of the phenocryst). Vertical axis shows the percentage. c Variation in water content of the isolated glass inclusions in the orthopyroxene and quartz phenocrysts. Vertical axis shows the percentage.

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The water content in the plateau parts shows the systematic decrease along the stratigraphy of the deposits from 5–7 wt% to approximately 4–6 wt%, from the basal part of the Osumi pumice fall deposit to the top of the Osumi pumice fall deposit (Fig. 2b). The range of water content in the plateau parts is almost constant from the basal to the middle parts of the Osumi pumice fall deposit. The decrease of water content in the plateau parts becomes clear from the middle to upper parts of the Osumi pumice fall deposit (Fig. 2a and b). The water contents in the plateau parts ranging from 2 to 4 wt% were obtained from the Tsumaya pyroclastic flow deposit erupted just before the caldera collapse (Fig. 2b). Assuming that the partial pressure of water in the magma was equal to the total magmatic pressure, as the concentrations of CO2 and other volatile phase are negligible (less than 250 ppm33), the water content in the glass can be converted to the pressure based on water solubility in the rhyolite melt34. The water contents obtained from the basal–middle part of the Osumi pumice fall deposit (5–7 wt%) correspond to the solubility of the water at 140–260 MPa. The water contents obtained from the uppermost part of the Osumi pumice fall deposit (4–6 wt%) and the Tsumaya pyroclastic flow deposit (2–4 wt%) correspond to the solubility of the water at 90–190 MPa and 20–90 MPa, respectively. The water content in the plateau parts of the embayments hosted in the Ito ignimbrite and its co-ignimbrite ash ranges from 1.5 to 3.5 wt%, which corresponds to pressure conditions of 15–70 MPa (Fig. 2b).

In contrast to the clear decrease of the water content in glass embayments toward the eruption of the main ignimbrite, isolated glass inclusions have a similar range of water contents (5–7 wt%) without any clear trends throughout the stratigraphy (Fig. 2c). The range of water contents in the isolated glass inclusions was similar to that of glass embayments of the pumice collected from the basal part of the Osumi pumice fall. The water contents of 5–7 wt% in the isolated glass inclusions found in the Osumi pumice fall and the Tsumaya pyroclastic flow deposits correspond to a pressure of approximately 140–260 MPa, which is equivalent to depths of 5.3–9.8 km assuming the density of the host rock as 2700 kg/m3. This estimate is consistent with the pressure in the magma chamber based on the phenocryst-phase equilibrium relationships stated in previous studies32,33.

Two-step decompression of magmas

The profile of water content with two regions of different gradients, which is typically observed in the glass embayments (Fig. 2a), indicates that the magma has experienced two stages of decompressional dehydration with different decompression rates (Fig. 3).

Fig. 3: Two-step dehydration.
figure 3

a Distributions of water content along a 300-μm-long melt embayment calculated by the one-dimensional diffusion model. The decompression rate is assumed as 1 × 103 Pa s−1. The initial water content is 6.5 wt%. The distributions of water 12, 24, 36, and 48 h after the start of decompression are shown. The measured data of water contents shown in each panel are the same as those in Fig. 2a. The gray hatched area (~50 μm from the entrance of the embayment) is considered to be affected by the rapid dehydration in the second decompression step and/or post-eruption hydration. b Diffusion profiles formed in the embayment when the magma is decompressed to atmospheric pressure at different decompression rates, calculated by the one-dimensional diffusion model (red solid line). The numbers shown in the profiles indicate the decompression rate (×103 Pa s−1). The initial water content of sample 171129 C is 6.5 wt%, samples 181218B2 and 181218B3 are 6.0 wt%, 181218B4 is 5.0 wt%, and 140901F8 is 4.0%, decreasing with the progress of the eruption.

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With the dehydration of the melt outside of an embayment, the water content inside the embayment decreases by the diffusion of water through the entrance of the embayment. The diffusion will form a gradient of water content along the embayment. The steepness of the gradient depends on the dehydration rate of the surrounding melt and the length of the embayment. The existence of a plateau of water content in the embayments, as found in the ejecta of the AT eruption, indicates that the distribution of water inside and outside the embayment has been homogenized by diffusion with the slow dehydration rate in the surrounding melt. Assuming that the water content in the plateau records the saturated water content in the decompressing magma chamber when the magma was tapped from the chamber, the change of the water content in the plateau along the stratigraphic sequence of the eruption (Fig. 2b) can be regarded as a record of the decompression process of the magma chamber.

The decrease of water contents in the plateau parts along the stratigraphy of the deposits shows that the magma chamber was depressurized from 140–260 MPa, which is the original magmatic pressure, to 90–190 MPa by the end of the eruption of the Osumi pumice fall deposit (~40 km3), and further depressurized to 20–90 MPa by the subsequent eruption of the Tsumaya pyroclastic flow (~10 km3). The caldera collapse occurred when the magmatic pressure in the magma chamber dropped to 20–90 MPa, due to the extraction of ~50 km3 of magma that produced the Osumi pumice fall and the Tsumaya pyroclastic flow. Our one-dimensional diffusion model shows that the decompression rate less than 1 × 103 Pa s−1 was necessary to decrease the water contents in the plateau from 6.5% to 4.0% keeping the variation of water contents less than 0.5 wt% in the plateau part (Fig. 3a and Supplementary Data 1). The decrease of the water content from 6.5 to 4% seen in the plateau parts during the eruption of the Osumi pumice fall is considered to have taken about 48 h or more at this decompression rate (Fig. 3a). This result is consistent with the estimated decompression rate (2.2–7.0 × 102 Pa s−1) from the duration of the Plinian phase of the Osumi pumice fall deposit (~2.8 days) estimated from the magma-discharge rate and total volume of erupted magma. This decompression rate of the magma chamber is also consistent with the estimation (<103 Pa s−1) from the number density of “pheno-bubbles” in the Osumi pumice, which were formed in the magma chamber35.

The steep gradient of water content at the entrance of the embayments (Fig. 2a) records a much higher decompression rate, which occurred after the formation of the plateau. The one-dimensional diffusion models indicate that the decompressional dehydration between 50 and 500 × 103 Pa s−1 can form the observed profile of water content in the glass embayments of the Osumi pumice fall (Fig. 3b). The estimated decompression rate from glass embayments is more than three orders of magnitude lower than those based on vesicle-number density of the matrix bubbles (~108 Pa s−1)35. As pointed out in the similar example of the Santorini volcano23, the difference between two estimated decompression rates suggests the acceleration of decompression rate of magmas during the ascent in the conduit from <5 × 104 Pa s−1 in the deeper portion of the conduit recorded in the diffusion profile of the glass embayments to ~108 Pa s−1 in the shallower portion of the conduit recorded by the matrix bubbles. However, the actual decompression rates of magmas may have a deviation from this estimation assuming a one-dimensional diffusion in a straight and cylindrical embayment due to the complex shapes of actual embayments (Fig. 1c and d), such as necking and curvature36. The absence of clear gradients of water content at the entrance of the embayments in the ejecta of the later stage of the eruption (Fig. 2a) is a result of the smaller contrast of water content in the diffusion profile due to the decrease of the water content in the plateau part. Hydration in the post-eruption period also overprints the diffusion profile with low contrast.

These results indicate that the first step of decompression, which is recorded in the plateau of water content, is the decompression process of the magma chamber due to the extraction of magmas toward the caldera collapse. The second step of decompression recorded in the diffusion profile at the entrance of the glass embayments is the rapid decompression during the ascent of magma through the conduit.

Decompression of the magma chamber and caldera collapse

The estimated decompression of the magma chamber prior to caldera collapse inferred from the water content in the plateau is consistent with the results from theoretical models16. Caldera collapse occurs when decompression of the magma chamber by rapid extraction of magma exceeds the threshold of fracturing and faulting in the roof rock of the chamber (Fig. 4). The amount of decompression that is required for a cylindrical caldera block to descend into an underlying magma chamber can be expressed as a function of the depth to the magma chamber and the diameter of the caldera fault16. In the case of the Aira caldera, the depth to the magma chamber was estimated to be approximately 6 km, based on the constraints from the water content in glass inclusions, and the horizontal diameter of the caldera fault was estimated to be approximately 14 km, assuming that the size of the topographic caldera floor indicates that of the top of the caldera block. According to the model proposed by a previous study16, if the magmatic pressure at the top of the magma chamber drops ~120 MPa from the lithostatic pressure, faults will be activated for a caldera with a size similar to that of Aira volcano. A large-scale decompression of the magma chamber, which exceeded half of the lithostatic pressure at the roof of the magma chamber, before the onset of caldera collapse, indicates that Aira caldera is a typical example of an “under-pressure caldera”7 that requires a large underpressure in the magma chamber for formation and activation of caldera faults. The absence of a previous caldera structure before the AT eruption suggests that the fault system of the Aira caldera needed to be fully generated during the AT eruption. The high shear strength of the host rock due to the absence of the previous caldera structure allowed a large decompression in the magma reservoir before the caldera started to collapse.

Fig. 4: Evolution of magma decompression during the AT eruption.
figure 4

Decompression of magma chamber and deformation of the host rock toward the caldera collapse and eruption of massive ignimbrite. A rhyolite magma chamber was subjected to lithostatic pressures of 140–260 MPa, corresponding to depths of 5.3–9.4 km below the surface of the Aira volcano before the eruption. Extraction of magmas from the magma chamber caused decompression in the magma chamber. Pressure in the magma chamber decreased to ~90–190 MPa due to the extraction of the magma by the eruption of the Osumi pumice fall during the Plinian phase. Down-sag deformation of the roof rock was initiated by the pressure difference between the lithostatic pressure acting on the host rock of the magma chamber and the decreasing magmatic pressure in the chamber during the Plinian phase. The extracted magmas were decompressed rapidly during their ascent through the conduit to the ground surface. Caldera collapse started when blocks of roof rock detached by the ring fracture subsided into the magma chamber. The subsidence of the blocks into the magma chamber accelerated further magma output, to form a massive ignimbrite.

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Though the decompression estimated from the glass embayments is slightly larger than the theoretical prediction, the decompression in the magma chamber, leading to the activation of caldera faults, should be greater than the modeled value obtained using a simple piston-cylinder fault, considering the complex structure of a caldera fault with branching37,38 and down-sag deflection of the host rock39,40.

The <0.5 wt% to 3.5 wt% range of water contents in the embayments of Ito ignimbrite and its co-ignimbrite ash erupted with the caldera collapse (Fig. 2b) suggests the extraction of magmas from various depths of the magma chamber with different pressure conditions. Decompression of a magma stored in the shallow part of the magma chamber during the precursory stage induced the collapse of the roof of the magma chamber, and enhanced the extraction of the magmas stored in the melt bodies distributed in the different parts of the crystal mush body41.

Ground deformation prior to the caldera collapse

Progressive magma extraction from the magma chamber during the precursory stage may cause down-sag deformation39,40 and fracturing of the roof rock of the magma chamber37,38. Based on the estimated volume of magma extracted from the magma chamber of the AT eruption, the expected ground deformation has been modeled by an elastic deformation model, assuming a cylindrical magma chamber with a horizontal diameter of 14 km and a vertical length of 3 km at a depth of 6 km from the ground surface at the center of the Aira caldera (Fig. 5a). The volume of this magma chamber corresponds to the total volume of the erupted magma during the AT eruption18,24. The model shows that the subsidence of the ground surface just above the center of the magma chamber was estimated to be >150 m (Fig. 5b and c) when 40 km3 of magma, equivalent to the total volume of the erupted magma that produced the Osumi pumice fall deposit, was extracted from this magma chamber. The area where subsidence exceeded 10 m is expected to be within a 13-km radius from the center of the magma chamber. Assuming that the magma chamber is located at the center of Aira caldera, ~50 m of subsidence is expected at the coastline of Kagoshima Bay due to the eruption that produced the Osumi pumice fall deposit (Fig. 5b and c). Judging from the estimated duration of the Osumi pumice fall eruption, this ground deformation occurred within ~3 days from the onset of the eruption. Such rapid and massive caldera subsidence may have caused seawater intrusion into the caldera area, resulting in violent phreatomagmatic explosions during the eruption of the Tsumaya pyroclastic flow at the end of the precursory stage.

Fig. 5: Configuration and results of modeling deformation during caldera collapse.
figure 5

a Outline of the configuration of the model. A cylindrical magma chamber with a horizontal diameter of 14 km and a vertical length of 3 km at the depth of 7 km from the ground surface is assumed for the simulation. The magma chamber is centered on the center of the Aira caldera. Broken red line shows the projection of the magma chamber to the present sea level. Broken blue line is the current topographic caldera rim. b Calculated vertical displacement of ground surface at the end of the eruption of the Osumi pumice fall due to the 40-km3 extraction of magma from a magma chamber beneath the Aira caldera. The minus sign indicates subsidence. The contour interval is −10 m. Broken red line and blue line mark the projection of the magma chamber to the present sea level, and the topographic caldera rim, respectively. White solid line shows the current coastline. c The vertical displacement profile as a function of the distance from the deformation center after the extraction of magma from the chamber with a volume of (dashed and dotted) 10, (dotted) 20, and (solid) 40 km3. The inverted triangles mark the distance corresponding to the perimeter of the magma chamber.

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Extensive deformation of the roof rock enhanced fracturing in the roof rock, and resulted in the propagation and enlargement of the conduits, as observed in the case of the eruptions of the Osumi pumice fall and Tsumaya pyroclastic flow18,24. The propagation and enlargement of the conduits during the eruptions of the Osumi pumice fall and Tsumaya pyroclastic flow maintained or increased the magma discharge flux toward the onset of caldera collapse, despite the progress of decompression in the magma chamber27. The decompression of the magma chamber may have been accelerated by an increase in the magma flux due to the expansion of the conduit, resulting in the threshold for caldera collapse being exceeded.

Discussion

The results of this study reveal that the decompression of the magma chamber from 140–260 MPa to 20–90 MPa, due to the extraction of ~50 km3 of magma as the Osumi pumice fall deposit and the Tsumaya pyroclastic flow, triggered the collapse of the Aira caldera and the eruption of ~350 km3 of magma that produced the Ito ignimbrite, which accounts for 88% of the total volume of the magma erupted during the AT eruption. Therefore, detection of the degree of magma-chamber decompression during a “precursory stage” is crucial for the prediction of the eruption of a catastrophic ignimbrite as the decompression of the magma chamber can cause caldera collapse.

The Plinian phase of the Osumi pumice fall is characterized by the extraction of a large volume of magma (~40 km3,26,27) with a high eruption rate (~4.2 × 108 kg s−130), which is two orders higher than that of the largest historical eruption of Sakurajima, post-caldera volcano of the Aira caldera, in 1914 (0.09-km3 DRE42, 5 × 106 kgs−1 43). The 1914 eruption resulted in only ~1 m of subsidence at the caldera rim44, with the extraction of a total of 1.5 km3 of magma mainly as a lava flow from the Aira caldera. This comparison suggests that a future eruption that precedes caldera collapse is expected to cause much larger and faster ground deformation than what has been experienced during historic eruptions. This case study in the Aira caldera confirms that extensive decompression of a magma chamber, and the consequent deformation of the roof rock and the enlargement of the conduit12,16,27, are thought to be the branching mechanism from a “normal” Plinian eruption to the eruption of a massive ignimbrite-forming pyroclastic flow associated with caldera collapse. Therefore, we conclude that monitoring the intensity of ground deformation during an eruption would allow the total decompression of a magma chamber to be estimated, and thereby prediction of the potential of caldera collapse and initiation of a massive ignimbrite-forming eruption.

Methods

Sampling

A series of AT-eruption products were collected for petrological investigation. The pumice clasts of the Osumi pumice fall deposit were collected from an outcrop along the eastern coast of Kagoshima Bay, ~26 km southeast of the caldera center (Shinjo Fumoto, Tarumizu City), where the thickness of the Osumi pumice fall deposit at the outcrop is approximately 5 m (Fig. 1). The Osumi pumice fall deposit in the outcrop consists of a nonwelded pile of lapilli-size clasts of rhyolite pumice. The size of clasts shows upward coarsening; maximum clast size varies from ~4 cm at the bottom to ~12 cm at the top of the deposit. The Osumi pumice fall deposit in this outcrop is covered by an ~3-m-thick Tarumizu pyroclastic flow deposit45. The pumice clasts were collected from six different levels of the deposit of the outcrop.

The pumice samples of the Tsumaya pyroclastic flow deposit were collected from an outcrop ~11 km northeast of the caldera center (Near Shiroyama Park, Kirishima City). The thickness of the Tsumaya pyroclastic flow deposit was approximately 8 m. The Tsumaya pyroclastic flow deposit at the outcrop consists of nonwelded stratified ash-flow deposit. The presence of accretionary lapilli in the deposit suggests the low-temperature emplacement of the deposit.

The pumice samples of the Ito ignimbrite, which is the main ejecta of the AT eruption, were collected from the western coast of Satsuma Peninsula, 35 km west of the caldera center (Fukiage Beach, Hioki City). The Ito ignimbrite at this site is a nonwelded pumice-rich flow deposit approximately 80-m-thick. The AT ash-fall deposit was collected from an outcrop ~40 km southeast of the caldera center (Shibushi City). In this outcrop, an ~4-m-thick AT ash-fall deposit covers the Ito ignimbrite.

Sample collections are conducted not in areas that require permission for sample collection, such as nature parks or nature-conservation areas. Some samples were collected on private land with the permission of the landowners.

Measurements

To investigate the decompression process throughout the sequence of the caldera-forming eruption, we analyzed the water content of glass inclusions and embayments in phenocryst crystals. The high-silica rhyolite erupted during the AT eruption contained up to ~23 vol.% of plagioclase, orthopyroxene, and quartz crystals as phenocrysts32. Minor volumes of magnetite and ilmenite were also found as phenocrysts. The quartz phenocrysts exhibited corroded outlines with embayments due to the heating of rhyolite magma by the mafic injection just prior to the AT eruption32.

The phenocryst crystals were extracted from crushed pumice samples. The separated phenocryst crystals were fixed in epoxy resin and then polished to expose the glass embayment and inclusions. The polished surfaces of the crystals were coated with carbon for analysis with a scanning electron microscope (SEM). The thickness of the carbon coating on the samples ranged from 35 to 45 nm.

It is difficult to distinguish whether the glass region exposed on the polished surface is a part of the embayment or a glass inclusion closed inside the crystal because embayments that extend obliquely to the polishing surface are, in most cases, only partially exposed to the polishing surface. To determine whether the glass region exposed on the polished surface is part of the embayment, we used transmitted light observation with an optical microscope, and determined that the glass embayment is continuous with the groundmass glass outside the crystal. The longitudinal section of the embayment was exposed to the observation surface by polishing while observing with an optical microscope to measure the compositional profile along the embayment. After confirming that glass inclusions were completely enclosed in the crystal by observation using an optical microscope, we proceeded with polishing to expose the glass inclusions on the polished surface to measure their chemical composition.

The chemical composition of the volcanic glass was determined using an energy-dispersive X-ray spectrometer (EDS), X-Max 20 of Oxford Instrumentals, mounted on the SEM JEOL JSM6610LV at the Geological Survey of Japan. The beam current for the measurement was 1.000 nA and the acceleration voltage was 15 kV. We analyzed an area larger than ~10 μm2 for each analysis to avoid damage to the glass and loss of alkaline elements. The detection limit of these elements was less than approximately 0.1 wt%.

The water content in glass was determined using the stoichiometric balance between the oxygen and cation elements in the analyzed area32,46,47. Elements with larger atomic numbers than oxygen were quantified using EDS by the software INCA of Oxford Instrumentals. O, Na, Mg, Al, Si, P, K, Ca, Ti, Mn, and Fe were detected in the analyzed glasses. Assuming that all elements form oxides, the quantified oxygen was distributed according to the valence of each element. Assuming that the excess oxygen formed H2O, the water content in the volcanic glass was calculated. All iron in the glass was in the form of ferric oxide (Fe3+). Because the composition of glass embayments and inclusions in the samples were rhyolite with less than 1.1 wt% of iron, the error of quantification of H2O caused by the estimation of Fe2+/Fe3+ ratio is less than 0.2 wt%. Analytical results are shown in Supplementary Data 1 and 2.

The quantified value of the H2O content in representative glass samples was double-checked by hydrogen gas manometry (HGM), Fourier transform infrared spectrometry (FT-IR), and secondary ion mass spectrometry (SIMS) to confirm consistency among different methods (Supplementary Fig. 1 and Supplementary Table 1).

As some glass inclusions and embayments were affected by devitrification, particularly in the pyroclastic deposits, the glass samples were examined using both optical microscopy and SEM to confirm that there was no crystallization. To avoid the effect of post-eruption hydration (Supplementary Fig. 2), analytical values within 30 μm of the glass surface were not used. To minimize the effect of rapid dehydration during ascent in the conduit, glasses occurring deeper than ~100 μm from the surface of the host phenocryst were measured for the water content in the “plateau” part of embayments.

Diffusion model

We modeled the development of the water content profile in a 300-µm-long melt embayment filled with rhyolite melt, using a one-dimensional diffusion model. The modeled melt embayment connects to the melt outside on one side, and the other end is closed in the host crystal. The diffusion coefficient of water in the rhyolite melt is assumed as 1 μm2 s−1 at 800 °C48. The temperature of the magma used in the model is based on the equilibrium temperature of magnetite–ilmenite pairs in the Osumi pumice fall deposit (780–840 °C)33. The pressure dependence of the solubility of water is taken from published constraints34.

For the modeling of magma-chamber decompression in the first step, the initial water content in the melt was assumed as 6.5 wt%, based on the water content in the plateau part of the glass embayments of the Osumi pumice fall deposit (Fig. 2a and b). This water content corresponds to the saturated water content of rhyolite magma at 223 MPa34. We examined the profile of water contents in a melt embayment when the melt on the outside of an embayment dehydrates at various decompression rates ranging from 1 × 102 Pa s−1 to 1 × 105 Pa s−1 (Supplementary Figs. 3 and 4).

For the modeling of second-step decompression in the conduit, cases with initial water content of 6.5%, 6, and 5% were modeled, depending on the degree of decompression dehydration in the magma reservoir. The profiles of water contents in a melt embayment were examined when the melt on the outside of an embayment dehydrates at various decompression rates ranging from 10 × 103 Pa s−1 to 500 × 103 Pa s−1 (Supplementary Fig. 5).

Deformation model

The elastic response to magma discharge was calculated using a 3D finite-element code, oregano_ve49. The modeled rectangular parallelepiped domain had a thickness of 100 km and a horizontal dimension of 192 × 192 km. The mechanical boundary condition corresponded to the traction on the top surface of zero in any direction, and normal displacement and tangential traction of zero for the rest of the boundary surfaces. The elastic properties, shear modulus, (μ = 1010 Pa), and Poisson’s ratio (ν = 0.25) were constant in the model. A cylindrical magma chamber with a radius of r and a thickness of h was used for the calculation. The chamber was positioned at the center of Aira caldera, where the deflation source during the 1914 eruption and subsequent inflation source were assumed to be located. The depths to the top and bottom of the magma chamber were assumed to be 6 and 9 km, respectively, based on the initial water content (5–6.5 wt%) in the embayment and inclusions of the Osumi pumice fall deposit, which corresponds to a pressure of approximately 140–250 MPa. The radius of the magma chamber (r) was assumed to be 7 km, based on the area of the caldera floor. The volume of the magma chamber was 462 km3, which corresponds to the total erupted volume of the AT eruption of ~400 km3. However, we ignored this original finite thickness of the chamber by applying a simple dislocation model for an instantaneous deflation at a depth of 7 km, for which the split-node method developed in a previous study50 was adopted in the finite-element code used in this study49. This approximation may be validated by the ratio of the half-thickness of the chamber to the depth (~1.5/7 = ~0.2).