Shallow magma diversions during explosive diatreme-forming eruptions


The diversion of magma is an important mechanism that may lead to the relocation of a volcanic vent. Magma diversion is known to occur during explosive volcanic eruptions generating subterranean excavation and remobilization of country and volcanic rocks. However, feedbacks between explosive crater formation and intrusion processes have not been considered previously, despite their importance for understanding evolving hazards during volcanic eruptions. Here, we apply numerical modeling to test the impacts of excavation and subsequent infilling of diatreme structures on stress states and intrusion geometries during the formation of maar–diatreme complexes. Explosive excavation and infilling of diatremes affects local stress states which inhibits magma ascent and drives lateral diversion at various depths, which are expected to promote intra-diatreme explosions, host rock mixing, and vent migration. Our models demonstrate novel mechanisms explaining the generation of saucer-shaped sills, linked with magma diversion and enhanced intra-diatreme explosive fragmentation during maar-diatreme volcanism. Similar mechanisms will occur at other volcanic vents producing crater-forming eruptions.


Recent field and geophysical studies have revealed complex networks of sub-vertical dikes to sub-horizontal sills underlying monogenetic volcanic fields1,2,3,4,5, with the growth of these networks affecting the location and style of eruptive activity. Hazardous vent-site shifts are documented for monogenetic eruptions6,7, resulting from lateral magma diversion during growth of dike and sill feeders3,8. Magma diversions and transitions in intrusion geometries can be explained by several physical and structural factors, such as mechanical contrasts9, pre-existing fractures10, and stress loading/unloading11,12. These diversions can modulate eruptive behavior between explosive and effusive activity13, resulting from changes in magma-water ratios3, reduced internal magma pressure causing volatile exsolution14,15, and/or a build-up of volatiles at dike-sill junctions1. The combination of explosive volcanic activity (e.g., base surges)16,17,18 and potential vent-site shifts6,8, which gradually increase the surface region impacted by an eruption, is highly hazardous to densely populated areas situated on volcanic fields (e.g., Mexico City, Mexico, and Auckland, New Zealand). The feedbacks between magma plumbing system development and the location of magma fragmentation must therefore be well understood to forecast and mitigate volcanic hazards19,20.

The development of shallow feeder systems is increasingly recognized as playing an important role in modulating eruptive activity3,21,22. However, no studies to date have modeled the succession of topographic (excavation) and material (infilling) changes occurring during an explosive eruptive sequence, and its influence on the development of underlying feeder systems. Previous studies demonstrate that unloading during crustal stretching11, volcanic mass-wasting23, and caldera collapse24 has a profound effect on intrusion pathways. Such events, however, occur rarely or over long timescales, whereas cratering and infilling processes are common to all explosive eruptions. Here we utilize, for the first time, finite element modeling to analyze the evolution of stress states during explosive excavation and filling of gravitationally loaded country rock. Although the process of crater excavation and infilling is common to all explosive eruptions, the most strongly crater-dominated eruptions, of maar-diatreme volcanism, are chosen for this study. This allows us to test how local stress fields, and therefore magma propagation, respond to the mechanical changes produced by excavation of maar-diatreme structures that are common in mafic and kimberlite volcanic fields (Fig. 1a). We conclude that stress fields generated from maar-diatreme volcanism can cause magma diversions, with diverted magma producing intrusions with a variety of geometries, which will affect the location of magma fragmentation sites and surface eruptions.

Fig. 1

Finite element model configuration. a Sketch of a maar–diatreme complex. Modified from Lorenz33. The dotted red square represents the area modeled numerically using an axisymmetric axis. b The initial step models the excavation stage. The model is gravitationally loaded with a lithostatic pre-stress and a body load. A vertical load acting on the diatreme’s wall represents the mass of rock excavated. c The second step models the infilling stage. The initial stress conditions and geometry are transferred from the initial step. The diatreme is filled with either 25, 50, or 75% of the total diatreme volume. Physical parameters are Ec = 15 GPa, ηc = 0.25, and ρc = 2300 kg m−3 for the crust, Ei = 2.5 GPa, ηi = 0.25, and ρi = 2000 kg m−3 for the infill


Stress states affecting intrusion geometries

We focus our analysis on the differential tectonic stress state

$$\Delta \sigma _{\mathrm{tect}} = \sigma _{\mathrm{r}} - \sigma _{\mathrm{z}},$$

with σr being the radial (horizontal) stress and σz the vertical stress, created within the crust and the diatreme infill, which affects the driving forces for vertical magma movements25,26. Negative values correspond to environments under horizontal compression (σz > σr) (e.g., in red Fig. 2c), which discourages vertical magma propagation in dikes and promotes lateral propagation in sills27. Positive values correspond to areas under horizontal extension (σr > σz), which favor vertical magma propagation (e.g., in blue Fig. 2c).

Fig. 2

State of stress within the crust surrounding the newly formed diatreme. a, b Differential tectonic stress along the diatreme flank and in the underlying crust for different wall dips (α = 80, 70, and 60°, in brown, purple, and orange-colored thick-dashed lines, respectively) and for different diatreme depths Dd = 500 m (a), Dd = 2000 m (b). Separated by a dash line, positive and negative values correspond to horizontal extensional and compressional stresses, respectively. c, d Differential tectonic stress and stress orientation within the crust for different diatreme geometries, Dd = 500 m, α = 80° (c); Dd = 2000 m, α = 60° (d). Blue and red shadings represent extensional and compressional Δσtect, respectively. Based on Melosh and Williams34 and McGovern and Solomon35, the hourglass shapes are oriented along the direction of greatest compressive stress (σ1); the red bars along the direction of least compressive stress (σ3). Circles represent out-of-the plane hourglass shapes (σ1 perpendicular to the r–z plane)

Finally, the orientation of the minimum compressive stress (σ3) is inferred to indicate the type of magmatic intrusion occurring within the domain, assuming that magmatic intrusions open perpendicular to σ3 (red bars in Figs. 2, 3)25. In regions subjected to horizontal extension, σ3 may be oriented in any direction along the horizontal plane and symmetry axis. Magma transport occurs through planar intrusions25, such as dikes (dips >60°) and sills (dips <10°), and our models and figures show a cross-section normal to the long-axis of a hypothetical intrusion. Other secondary factors known to affect intrusion geometries, such as preexisting structures10 and layers with contrasting mechanical properties9,28,29,30,31, were not considered in our modeling approach, but if included would further promote the development of the complex intrusive networks discussed9,32.

Fig. 3

State of stress within the diatreme’s infill and the surrounding crust. a, b Differential tectonic stress along the symmetrical axis of the model (left boundaries) for different diatreme’s depth Dd = 500 m (a), Dd = 2000 m (b), dipping angles α = 80° (a), α = 60° (b), and infill volume (colors blue, green, and yellow for 25, 50, 75% of infill, respectively). cf Differential tectonic stress and stress orientation within the infill and the crust for different diatreme geometries and infill volumes, c Dd = 500 m, α = 80°, 25% infill; d Dd = 500 m, α = 80°, 75% infill; e Dd = 2000 m, α = 60°, 25% infill; f Dd = 2000 m, α = 60°, 75% infill. Legend as in Fig. 2

Stress states during diatreme excavation and infilling

Excavated diatreme structures (no infilling) with steep diatreme walls (80° dip), subjected to instantaneous unloading, exhibit horizontal extension in the upper ~90% of the diatreme walls (positive values and blue shading in Fig. 2a, c, and Supplementary Figs. 1, 2), while the lower part, as well as the underlying host rock, are subjected to horizontal compression (negative values and red shading in Fig. 2a, c). Diatremes with gentler slopes show a decrease in the area subjected to horizontal extension (e.g., from ~40% of the wall for 70° dips to 0% for 60° dips) and an increase in the area of horizontal compression in the lower part of the diatreme and underlying crust (Fig. 2a, b, and Supplementary Figs. 1, 2). In all, we observe differential tectonic stresses down to −80 MPa in areas of horizontal compression, and up to 10 MPa in areas of horizontal extension in the country rock surrounding excavated diatremes with no infilling (Supplementary Fig. 1). The orientation of σ3 is vertical below the excavated diatreme, favoring sill formation, but rotates in the illustrated vertical r–z plane of the model in an anticlockwise manner to become sub-horizontal in the surrounding crust, which favors dike formation (red lines Fig. 2c, d and Supplementary Fig. 2). Finally, σ3 rotates further, immediately below the ground surface, into an orientation out of the illustrated plane (hourglasses without red lines, Fig. 2c, d and Supplementary Fig. 2).

Immediately following a major diatreme-excavation explosion, the diatreme structure is partly re-filled with vertically ejected volcaniclastic material. These infills exhibit horizontal extension of up to 10 MPa at their base. Maximum horizontal compression observed in the upper half of the infill is dependent on the infill volume percent and ranges from −1 to 10 MPa in our model runs (Fig. 3a, b and Supplementary Fig. 3). These stress magnitudes are also sensitive to the Young’s Modulus of infill, although stress orientations remain constant (see Supplementary Figs. 58). In the country rock below the diatreme, horizontal compression is present and its magnitude is also dependent on the infill volume percent and Young’s Modulus of the infill material. Values below the diatreme range up to −4 MPa (Fig. 3a, b and Supplementary Fig. 3). Horizontal extension occurs near the contact between the diatreme wall and the infill, with differential tectonic stress values up to 10 MPa (Fig. 3b). The orientation of σ3 within the infill is horizontal in its lower half, favoring dike intrusion, and vertical in the upper half, favoring sill intrusion. Within the surrounding host rock, the orientation of σ3 is vertical below the diatreme and rotates to sub-horizontal in the vicinity of diatreme walls up to the surface (Fig. 3c–f, Supplementary Figs. 912).

Impact on intrusive processes and magma fragmentation

Maar-diatreme formation results from country rock excavation and remobilization during explosive volcanism. A long-standing model of maar-diatreme formation involves progressive deepening of the base of the diatreme as the site of magma fragmentation descends due to water table drawdown33. By contrast, recent field, experimental, and numerical studies support fragmentation zones at almost any location and depth during diatreme formation13,36,37,38,39. The progressive up-structure widening of the diatreme in the latter models results from collapse of unsupported wallrock38, explosive fragmentation at shallower depths37, and also from lateral magma diversions, possibly in sills in the upper diatreme40. Such models thus require that vertically ascending magma preferentially stalls in the shallow subsurface, which our model shows is favored by the stress response to infilling.

Comparing natural volcanic features with products of theoretical models is fundamental for understanding the physical processes that influence the nature of volcanic activity and growth of different volcano types. In the shallow subsurface, dike overpressures typically range 1–10 MPa41,42. This overpressure is focused within the dike’s head, and is often released upon explosive fragmentation, with subsequent magma arriving from the dike tail being only weakly overpressured43. Local increases in horizontal compressive stresses of a few MPa tend to inhibit magma ascent in subvertically oriented dikes; in these instances, intrusion propagation may terminate entirely, or dikes will reorient according to the new stress state27, or intrude along crustal heterogeneities44. Field observations in monogenetic fields support stress changes that alter directions of intrusion propagation. For example, dikes are shown to transform to sills near the base of3, or within40, diatremes, and saucer-shaped sills (see Muirhead et al.3 for a detailed description) outcrop at the peripheries of nested diatremes and volcanic–conduit complexes3 (Supplementary Figs. 13, 14).

By examining a simplified two-step process of maar-diatreme formation (excavation and infilling), our models reveal stress variations that explain these observed lateral magma diversions during explosive maar-diatreme volcanism. The initial process of diatreme excavation leads locally to unloading of the crust, and horizontal compression is generated in the crust underlying the newly formed diatreme, which results in a local stress rotation and a subvertical minimum compressional stress (σ3). Such a state of stress inhibits the vertical propagation of magma and favors lateral diversions through sills near the base of the diatreme (Fig. 4a). Similar magma diversions are shown to result from vertical unloading of the crust during rifting11. The tendency for a compressional stress state to induce dike arrest and lateral magma diversions will be greater for dikes with relatively low overpressures (no more than a few MPa)45, as is expected for mafic monogenetic eruptions, which exhibit relative low magma volumes and fluxes10. Inelastic processes, such as fracturing will occur during the initial explosive process. The damage zone would decrease the magnitude of the stress within the medium, but would not change the main characteristics of the horizontal and extensional stress46.

Fig. 4

Sketch of a maar-diatreme eruption and formation of the magmatic plumbing system. a The proto-diatreme (aka excavation stage) and b developing diatreme (aka infilling stage). The colored arrows represent the orientation of the minimum compressional stress (σ3), the blue and red colors represent the differential tectonic stress, extensional and compressional, respectively

During the second step, as the diatreme is filled with volcaniclastic material, a reduction in the magnitude of horizontal compression below the diatreme allows magma to ascend in dikes into the diatreme. For a range of plausible infill properties (sensitivity tests in Supplementary Figs. 48), horizontal extension generated in the lower half of the diatreme infill will further promote the upward ascent of dikes in these areas, as shown in nature by dikes observed in the lower diatreme (Fig. 4b) (e.g., ref. 39 and references therein). As predicted by Valentine and White36, our results show that the orientation and magnitude of σ3 within the infill can also promote irregular magma propagation paths (sub-vertical to inclined), and that magma can be drawn to the peripheries of the diatreme, which experience the greatest horizontal extensional stresses. Finally, once a significant volume of diatreme infill has been emplaced, horizontal compression is generated in the subsurface of the infill, stalling ascending magma and promoting magma-host mingling or lateral diversion of magma into sills (Fig. 4b). Once a laterally propagating sill reaches areas of horizontal extension near the diatreme flanks, it can then transform back into a dike or inclined sheet (dipping 10–60°3), ultimately producing a saucer-shaped sill geometry3. Additionally, as the laterally propagating sill in the upper diatreme reaches the diatreme walls magma will enter an area of horizontal extension that favors groundwater entry and thus phreatomagmatic explosions, resulting in upward widening of the overall structure36 and explosive surface eruptions.

Finally, as the diatreme develops and both the depth and volume of the clastic infill increase, the magnitude of shallow horizontal compression in the upper diatreme also increases. This is expected to have two important effects. First, increased horizontal compression in the upper part of the diatreme decreases the likelihood that dikes will reach the surface, thus requiring greater magma flux rates and overpressures to drive eruptions. Therefore, larger explosions would be predicted in evolved diatreme structures, as described by Valentine and White36. Secondly, lateral diversions of magma are expected to become more frequent within larger diatremes, and thus sill-driven lateral quarrying will be favored in well-developed examples, which may assist in the formation of nested diatremes47.

In conclusion, diatreme formation is a complex process that occurs during kimberlite and basaltic phreatomagmatic eruptions48,49. Furthermore, excavation of vents, with or without infilling, occurs during explosive eruptions of other styles (e.g., vulcanian and plinian eruptions). The stress changes examined here are expected also to take place in a variety of volcanic settings and eruptive scenarios, including on other planetary bodies, though typically imposed on different pre-eruption topography. For instance, syn-eruptive sill transitions and shallow magma diversion have been recorded seismically and geodetically at composite volcanoes (e.g., Stromboli, Italy50), and sill/laccolith inflation was detected after the onset of explosive volcanism during the 2011 eruption of Cordón Caulle, Chile12. Here, we show that stress states resulting from explosive excavation of country rock and diatreme infilling provide a novel mechanism to explain sill transitions and saucer-shaped sill formation in the crust immediately enclosing diatremes. Modeled stress fields in this study, and resulting intrusion geometries, provide new insights into processes controlling diatreme development, and support recent models of diatreme growth proposed by Valentine and White36 and Valentine et al.39. Overall, modeled stress states reveal a critical feedback between explosive maar-diatreme vent excavation, infilling, and development of geometrically complex magma networks. Phases of explosive excavation encourage magma to stall in sills below the excavated structure, allowing for lateral changes in the position of fragmentation zones early in the diatreme’s history rather than progressive deepening, whereas subsequent infilling should promote magma ascent to shallower levels within the diatreme. Horizontal compression in the upper diatreme drives lateral magma diversions, encouraging explosive diatreme widening and growth at shallow depths. Compressional stresses resulting from increasing infill volumes during continued diatreme growth are expected to promote sill-driven lateral quarrying, nest-diatreme formation, and larger explosive activity in well-developed examples. Our results suggest that while the diversion of magma during hazardous explosive eruptions may interrupt the eruptive sequence it does not necessarily indicate the end of an eruption, and can presage a shift in the vent location6,8. Such vent-site shifts should be considered in volcanic hazard mapping and eruptive-response scenarios19; detection of shifts and their precursors can be improved through more intensive geophysical and geodetic monitoring12,51.


Axisymmetric finite element modeling

We use finite element models through COMSOL Multiphysics® to investigate for the first time the effects of diatreme excavation for single-explosion craters followed by the infilling of the newly formed diatreme on the local state of stress (Fig. 1). These stress changes are expected to affect the geometry of surrounding intrusions, which form normal to the least compressive stress52. Our approach allows us to calculate in 3D the locations favoring or not the vertical propagation of magmas, as well as the stress orientation controlling the geometry and direction of propagation of magmas. One limitation of finite element studies testing a 3D stress environment is that it limits the ability to model active intrusion propagation23, which currently can be performed only in a 2D stress state. However, combined numerical and analog studies show that intrusion propagation paths closely mimic those predicted by the modeled 3D stress state53.

Host rock state of stress

The 2D axisymmetric elastic domain has a Young’s Modulus (Ec) of 15 GPa (sandstone equivalent), a density (ρc) of 2300 kg m−3, and Poisson’s ratio (µ) of 0.25. The area of the elastic domain is 100 × 100 km to avoid side effects, and is subjected to gravitational loads54 expressed by an initial lithostatic stress

$$\sigma _{\mathrm{r}} = \sigma _{\mathrm{\theta }} = \sigma _{\mathrm{z}} = - \rho _{\mathrm{c}}.\,Z.\,g,$$

where \(Z\) is negative downward and negative stress values indicate compression, and \(g\) is the Earth’s gravitational acceleration (−9.81 m s−2), and a body load

$$\rho _{\mathrm{c}}.\,g$$

Excavation stage

The diatremes were initially modeled as inverted cones corresponding to an excavated volume of rock, where the depth to base of the diatreme and angle of the diatreme walls varied from 500–2000 m and 60–80°, respectively (Supplementary Table 1). An unloading force representing the missing vertical rock load is applied at the surface of the diatreme (red line in Fig. 1b)11. This represents an end-member situation in which a deep open crater forms prior to any infilling, as has been inferred for some kimberlites55.

Infilling stage

The second step of each model tested the effects of infilling of the diatreme after excavation (Fig. 1c). Their initial conditions (deformed geometry and state of stress) corresponded to the transferred solution of the initial model using COMSOL capabilities. Here, we consider the static case when the infill material is fully deposited, and hence not in a fluidized state56. The diatreme was filled with a lower-density volcaniclastic material (ρi = 2000 kg m−3), which exhibited a weak elastic response (Ei = 2.5 GPa, and µ = 0.25) compared to the surrounding, consolidated country rock. Sensitivity tests conducted for these parameters are presented in the Supplementary Material. These sensitivity tests reveal that similar stress orientations are generated within and around diatremes for a reasonable range of elastic moduli (i.e., 0.5–5 GPa). To test the varying effects related to the weight of the infill, a series of model runs were performed with the initial excavated cavity filled by 25, 50, and 75% of its original volume. We make the simplifying assumption that the material is deposited en masse57. Body loads were added to the infilling as well as the host rock to simulate the gravitational load. The contact between the infill and the host rock is not fixed, which allows the diatreme fill to deform independently of the surrounding domain.

End-member scenarios

Our models address end-member scenarios, and real diatreme-forming eruptions are expected to have more complex excavation and infilling histories in which the diatreme is only partially emptied or infilled13,38. Nevertheless, the “forcing directions” of the effects of excavation vs. infilling of the diatreme structure revealed by our modeling show the potential for country-rock responses to modulate magma behavior during evolution of diatremes.

Results from numerical modeling experiments

A parametric analysis to study the role of the geometry and size of the diatreme has been implemented during this study (Supplementary Table 1 and Supplementary Figs. 13 and 912).

Model sensitivity to volcaniclastic infill properties

The creation of a diatreme implies deposition within the diatreme structure of material resulting from the fragmentation of the country rocks and the magma. The sequence of events during the initial excavation and the filling of the diatreme is complex. While the material is believed to be deposited en masse57, it can remain fluidized58 until it is fully deposited. The nature of the deposit is a mixture of both consolidated and granular material, which are expected to behave either elastically or viscously, respectively (e.g., tuff, lapilli-tuff, and non-volcanic sediments mixed with basaltic magma59,60,61). The physical characteristics of the infill are a function of particle size range and packing along with other factors (e.g., moisture/water content), and encompass a wide range of values. The rheological behavior of the diatreme’s infill will therefore vary depending on the degree of rock induration at the time of intrusion, which will be strongly dependent on (1) the time interval between excavation and new magma intrusion events, (2) sediment properties affecting porosity (i.e., sorting, size, shape)62, and (3) the depth of the diatreme fill. As such, diatreme infills exhibit a variety of structures, such as brittle faults and intrusions (dike, sills)40, non-brittle folds 63, and peperite60, which reflect elastic to elastoplastic to fluid-like viscous behaviors.

To account for varying elasticity, we run a series of models that test a range of elastic moduli values, with some values acting to suppress the elastic response of the diatreme fill. We tested the sensitivity our models to a low and high density material (1500 kg m−3 instead of 2000 kg m−3 as in Gernon et al.58, and 2500 kg m−3, Supplementary Fig. 4) and Poisson’s ratio (0.2 and 0.3 instead of 0.25, Supplementary Fig. 4), and a variety Young’s modulus values (0.5, 1, 2.5, and 5 GPa instead of 10 GPa, Supplementary Figs. 58).

Results show that density and Poisson’s ratio have a negligible effect on the resulting stress magnitudes (Supplementary Fig. 4). We observe that only the infill density influences the magnitude of the differential tectonic stress. Lower-density values favor larger horizontal compressional stresses in the underlying crust and lower differential tectonic stress within the infill, and vice versa for larger densities (Supplementary Fig. 4). Although Young’s modulus does not influence stress orientations, it does affect the magnitudes of stresses sustained within the domain. In all, a decrease in Young’s modulus lowers the amount of stress generated within the diatreme fill, as decreasing this value gradually suppresses the elastic response of the material (Supplementary Figs. 58). However, stress magnitudes even for low values of Young’s modulus are still high enough to promote the magma diversions discussed in this study. Furthermore, lowering Young’s modulus actually increases the magnitudes of compressional stresses immediately below the base of the diatreme, and thus lateral magma diversions in sills are still expected during crater-forming eruptions even if elasticity is completely suppressed within the diatreme fill.

Although Young’s modulus is a relatively unknown parameter for the diatreme fill, these sensitivity analyses validate our approach and results, because the principle stresses remain the same between models, and thus intrusion geometries and the directions of magma diversions are consistent for the full range of reasonable elastic moduli values. Secondly, the magnitudes of the stress changes below and within the diatremes are high enough (always greater than a few MPa) to promote magma diversions.

Field observations of lateral magma diversion in maar-diatreme fields

Recent field and seismic reflection studies have documented lateral magma diversions, particularly in sills, related to monogenetic volcanoes1,3,5,22,40,64,65,66. The mechanical controls on sill formation in these fields are poorly constrained, and little is known regarding the important feedbacks between intrusion and eruptive processes during eruptive episodes. Re et al.22 and Muirhead et al.3 suggested that saucer-shaped sills observed in the Hopi Buttes volcanic field possibly formed in response to subaerial and/or subsurface volcanic additions/removals of mass. Re et al. [22] hypothesized that the presence of a volcanic load (e.g., a scoria cone) could produce local stress rotations immediately below volcanoes at Hopi Buttes volcanic field, which could lead to sill formation. However, it is unknown whether scoria cones were present during emplacement the intrusions documented in their study.

Model results presented in this study provide new insights into how these observed sills, and lateral magma diversions generally, may be dynamically linked with the excavation and filling of diatremes and other volcanic conduit structures during explosive eruptive episodes. Indeed, in the Hopi Buttes volcanic field, clear spatial associations are observed between sills, diatremes, and pyroclastic vent structures (termed massifs by ref. 67). The presence of bedded, vesicular pyroclasts (scoria) in these vent structures suggests that at one time they formed open cavities exposed at the surface. Below these vents, sub-vertical dikes are observed transitioning into sub-horizontal sills (stage a of Fig. 4). The geometrical arrangement of segments and orientation of segment long-axes support magma propagation radially away from these central conduits in saucer-shaped sills3. At Crown Butte, saucer-shaped sills surround two (nested?) maar-diatremes. These sills occur at upper diatreme levels, as predicted for a developing diatreme with large infill (stage b of Fig. 4), and primary magma flow indicators (i.e., orientation of segment long-axes) suggest magma has flow laterally away from within or below these diatremes (Supplementary Fig. 14)3. In all, these observations support magma diversions in sills during excavation and filling stages of diatreme development, and at different depths in the diatreme complex as predicted by the numerical modeling results.

Data availability

All the relevant data that have been used in the present study are available from the authors.


  1. 1.

    Richardson, J. A., Connor, C. B., Wetmore, P. H., Connor, L. J. & Gallant, E. A. Role of sills in the development of volcanic fields: insights from lidar mapping surveys of the San Rafael Swell, Utah. Geology 43, 1023–1026 (2015).

    ADS  Article  Google Scholar 

  2. 2.

    Kiyosugi, K. et al. Relationship between dike and volcanic conduit distribution in a highly eroded monogenetic volcanic field: San Rafael, Utah, USA. Geology 40, 695–698 (2012).

    ADS  Article  Google Scholar 

  3. 3.

    Muirhead, J. D., Van Eaton, A. R., Re, G., White, J. D. L. & Ort, M. H. Monogenetic volcanoes fed by interconnected dikes and sills in the Hopi Buttes volcanic field, Navajo Nation, USA. Bull. Volcanol. 78, 11 (2016).

    ADS  Article  Google Scholar 

  4. 4.

    van Wyk de Vries, B. et al. Craters of elevation revisited: forced-folds, bulging and uplift of volcanoes. Bull. Volcanol. 76, 1–20 (2014).

    Google Scholar 

  5. 5.

    McLean, C. E., Schofield, N., Brown, D. J., Jolley, D. W. & Reid, A. 3D seismic imaging of the shallow plumbing system beneath the Ben Nevis Monogenetic Volcanic Field: Faroe–Shetland Basin. J. Geol. Soc. Lond. 174, 468–485 (2017).

    Article  Google Scholar 

  6. 6.

    Ort, M. H. & Carrasco-Núñez, G. Lateral vent migration during phreatomagmatic and magmatic eruptions at Tecuitlapa Maar, east-central Mexico. J. Volcanol. Geotherm. Res. 181, 67–77 (2009).

    ADS  CAS  Article  Google Scholar 

  7. 7.

    Abrams, M. J. & Siebe, C. Cerro Xalapaxco: an unusual tuff cone with multiple explosion craters, in central Mexico (Puebla). J. Volcanol. Geotherm. Res. 63, 183–199 (1994).

    ADS  CAS  Article  Google Scholar 

  8. 8.

    Lefebvre, N. S., White, J. D. L. & Kjarsgaard, B. A. Spatter-dike reveals subterranean magma diversions: consequences for small multivent basaltic eruptions. Geology 40, 423–426 (2012).

    ADS  CAS  Article  Google Scholar 

  9. 9.

    Kavanagh, J. L., Menand, T. & Sparks, R. S. J. An experimental investigation of sill formation and propagation in layered elastic media. Earth Planet Sci. Lett. 245, 799–813 (2006).

    ADS  CAS  Article  Google Scholar 

  10. 10.

    Le Corvec, N., Menand, T. & Lindsay, J. Interaction of ascending magma with pre-existing crustal fractures in monogenetic basaltic volcanism: an experimental approach. J. Geophys. Res. Solid Earth 118, 968–984 (2013).

    ADS  Article  Google Scholar 

  11. 11.

    Maccaferri, F., Rivalta, E., Keir, D. & Acocella, V. Off-rift volcanism in rift zones determined by crustal unloading. Nat. Geosci. 7, 297–300 (2014).

    ADS  CAS  Article  Google Scholar 

  12. 12.

    Castro, J. M. et al. Rapid laccolith intrusion driven by explosive volcanic eruption. Nat. Commun. 7, 13585 (2016).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  13. 13.

    Valentine, G. A. et al. Experiments with vertically and laterally migrating subsurface explosions with applications to the geology of phreatomagmatic and hydrothermal explosion craters and diatremes. Bull. Volcanol. 77, 15 (2015).

    ADS  Article  Google Scholar 

  14. 14.

    Kavanagh, J. L., Boutelier, D. & Cruden, A. R. The mechanics of sill inception, propagation and growth: experimental evidence for rapid reduction in magmatic overpressure. Earth Planet Sci. Lett. 421, 117–128 (2015).

    ADS  CAS  Article  Google Scholar 

  15. 15.

    White, J. D. L. Impure coolants and interaction dynamics of phreatomagmatic eruptions. J. Volcanol. Geotherm. Res. 74, 155–170 (1996).

    ADS  CAS  Article  Google Scholar 

  16. 16.

    Lorenz, V. Syn- and posteruptive hazards of maar-diatreme volcanoes. J. Volcanol. Geotherm. Res. 159, 285–312 (2007).

    ADS  CAS  Article  Google Scholar 

  17. 17.

    Taddeucci, J., Sottili, G., Palladino, D. M., Ventura, G. & Scarlato, P. A note on maar eruption energetics: current models and their application. Bull. Volcanol. 72, 75–83 (2010).

    ADS  Article  Google Scholar 

  18. 18.

    Németh, K., Cronin, S. J., Smith, I. E. M. & Agustin Flores, J. Amplified hazard of small-volume monogenetic eruptions due to environmental controls, Orakei Basin, Auckland Volcanic Field, New Zealand. Bull. Volcanol. 74, 2121–2137 (2012).

    ADS  Article  Google Scholar 

  19. 19.

    Lindsay, J. et al. Towards real-time eruption forecasting in the Auckland Volcanic Field: application of BET_EF during the New Zealand National Disaster Exercise ‘Ruaumoko’. Bull. Volcanol. 72, 185–204 (2010).

    ADS  Article  Google Scholar 

  20. 20.

    Sandri, L., Jolly, G., Lindsay, J., Howe, T. & Marzocchi, W. Combining long- and short-term probabilistic volcanic hazard assessment with cost-benefit analysis to support decision making in a volcanic crisis from the Auckland Volcanic Field, New Zealand. Bull. Volcanol. 74, 705–723 (2012).

    ADS  Article  Google Scholar 

  21. 21.

    Lefebvre, N. S., White, J. D. L. & Kjarsgaard, B. A. Arrested diatreme development: Standing Rocks East, Hopi Buttes, Navajo Nation, USA. J. Volcanol. Geotherm. Res. 310, 186–208 (2016).

    ADS  CAS  Article  Google Scholar 

  22. 22.

    Re, G., White, J. D. L. & Ort, M. H. Dikes, sills, and stress-regime evolution during emplacement of the Jagged Rocks Complex, Hopi Buttes Volcanic Field, Navajo Nation, USA. J. Volcanol. Geotherm. Res. 295, 65–79 (2015).

    ADS  CAS  Article  Google Scholar 

  23. 23.

    Maccaferri, F., Richter, N. & Walter, T. R. The effect of giant lateral collapses on magma pathways and the location of volcanism. Nat. Commun. 8, 1097 (2017).

    ADS  Article  PubMed  PubMed Central  Google Scholar 

  24. 24.

    Corbi, F. et al. How caldera collapse shapes the shallow emplacement and transfer of magma in active volcanoes. Earth Planet Sci. Lett. 431, 287–293 (2015).

    ADS  CAS  Article  Google Scholar 

  25. 25.

    Rubin, A. M. Propagation of magma-filled cracks. Annu. Rev. Earth Planet Sci. 23, 287–336 (1995).

    ADS  CAS  Article  Google Scholar 

  26. 26.

    Le Corvec, N., McGovern, P. J., Grosfils, E. B., Galgana, G. Effects of crustal-scale mechanical layering on magma chamber failure and magma propagation within the Venusian lithosphere. J. Geophys. Res. Planets 120, 2015JE004814 (2015).

  27. 27.

    Menand, T., Daniels, K. A. & Benghiat, P. Dyke propagation and sill formation in a compressive tectonic environment. J. Geophys. Res. 115, B08201 (2010).

    ADS  Article  Google Scholar 

  28. 28.

    Geshi, N., Kusumoto, S. & Gudmundsson, A. Effects of mechanical layering of host rocks on dike growth and arrest. J. Volcanol. Geotherm. Res. 223–224, 74–82 (2012).

    Article  Google Scholar 

  29. 29.

    Gudmundsson, A. The effects of layering and local stresses in composite volcanoes on dyke emplacement and volcanic hazards. Comptes Rendus Geosci. 337, 1216–1222 (2005).

    ADS  Article  Google Scholar 

  30. 30.

    Maccaferri, F., Bonafede, M. & Rivalta, E. A quantitative study of the mechanisms governing dike propagation, dike arrest and sill formation. J. Volcanol. Geotherm. Res. 208, 39–50 (2011).

    ADS  CAS  Article  Google Scholar 

  31. 31.

    Rivalta, E., Bottinger, M. & Dahm, T. Buoyancy-driven fracture ascent: experiments in layered gelatine. J. Volcanol. Geotherm. Res. 144, 273–285 (2005).

    ADS  CAS  Article  Google Scholar 

  32. 32.

    Taisne, B. & Jaupart, C. Dike propagation through layered rocks. J. Geophys. Res. 114, B09203 (2009).

    ADS  Google Scholar 

  33. 33.

    Lorenz, V. On the growth of maars and diatremes and its relevance to the formation of tuff rings. Bull. Volcanol. 48, 265–274 (1986).

    ADS  Article  Google Scholar 

  34. 34.

    Melosh, H. J., Williams, C. A. Mechanics of graben formation in crustal rocks: A finite element analysis. Journal of Geophysical Research  94, 13961-13973 (1989).

    ADS  Article  Google Scholar 

  35. 35.

    McGovern, P. J., Solomon, S. C. State of stress, faulting, and eruption characteristics of large volcanoes on Mars. Journal of Geophysical Research 98, 23553 (1993). 

    ADS  Article  Google Scholar 

  36. 36.

    Valentine, G. A. & White, J. D. L. Revised conceptual model for maar-diatremes: subsurface processes, energetics, and eruptive products. Geology 40, 1111–1114 (2012).

    ADS  Article  Google Scholar 

  37. 37.

    Sweeney, M. R. & Valentine, G. A. Transport and mixing dynamics from explosions in debris-filled volcanic conduits: numerical results and implications for maar-diatreme volcanoes. Earth Planet Sci. Lett. 425, 64–76 (2015).

    ADS  CAS  Article  Google Scholar 

  38. 38.

    White, J. D. L. & Ross, P. S. Maar-diatreme volcanoes: a review. J. Volcanol. Geotherm. Res. 201, 1–29 (2011).

    ADS  CAS  Article  Google Scholar 

  39. 39.

    Valentine, G. A., White, J. D. L., Ross, P.-S., Graettinger, A. H., Sonder, I. Updates to concepts on phreatomagmatic maar-diatremes and their pyroclastic deposits. Front. Earth Sci. 5 (2017).

  40. 40.

    Valentine, G. A., van Wyk & de Vries, B. Unconventional maar diatreme and associated intrusions in the soft sediment-hosted Mardoux structure (Gergovie, France). Bull. Volcanol. 76, 807 (2014).

    ADS  Article  Google Scholar 

  41. 41.

    Geshi, N., Kusumoto, S. & Gudmundsson, A. Geometric difference between non-feeder and feeder dikes. Geology 38, 195–198 (2010).

    ADS  Article  Google Scholar 

  42. 42.

    Gudmundsson, A. Stress estimates from the length/width ratios of fractures. J. Struct. Geol. 5, 623–626 (1983).

    ADS  Article  Google Scholar 

  43. 43.

    Lister, J. R. & Kerr, R. C. Fluid-mechanical models of crack propagation and their application to magma transport in dykes. J. Geophys. Res. 96, 10049–010,077 (1991).

    ADS  Article  Google Scholar 

  44. 44.

    Kavanagh, J. L., Rogers, B. D., Boutelier, D. & Cruden, A. R. Controls on sill and dyke-sill hybrid geometry and propagation in the crust: the role of fracture toughness. Tectonophysics 698, 109–120 (2017).

    ADS  Article  Google Scholar 

  45. 45.

    Taisne, B., Tait, S. & Jaupart, C. Conditions for the arrest of a vertical propagating dyke. Bull. Volcanol. 73, 191–204 (2011).

    ADS  Article  Google Scholar 

  46. 46.

    Kaiser, P. K. & Tang, C. A. Numerical simulation of damage accumulation and seismic energy release during brittle rock failure—Part II: Rib pillar collapse. Int. J. Rock Mech. Min. Sci. 35, 123–134 (1998).

    Article  Google Scholar 

  47. 47.

    White, J. D. L. & McClintock, M. K. Immense vent complex marks flood-basalt eruption in a wet, failed rift: Coombs Hills, Antarctica. Geology 29, 935–938 (2001).

    ADS  Article  Google Scholar 

  48. 48.

    Brown, R. J. & Valentine, G. A. Physical characteristics of kimberlite and basaltic intraplate volcanism and implications of a biased kimberlite record. GSA Bull. 125, 1224–1238 (2013).

    Article  Google Scholar 

  49. 49.

    Kurszlaukis, S. & Lorenz, V. Differences and Similarities between Emplacement Models of Kimberlite and Basaltic Maar-Diatreme Volcanoes. Vol. 446, 101–122 (Special Publications, Geological Society, London, 2017).

  50. 50.

    Casagli, N. et al. Deformation of Stromboli Volcano (Italy) during the 2007 eruption revealed by radar interferometry, numerical modelling and structural geological field data. J. Volcanol. Geotherm. Res. 182, 182–200 (2009).

    ADS  CAS  Article  Google Scholar 

  51. 51.

    Aoki, Y., Takeo, M., Ohminato, T., Nagaoka, Y. & Nishida, K. Magma Pathway and Its Structural Controls of Asama Volcano, Japan. Vol. 380, 67–84 (Special Publications, Geological Society, London, 2013).

  52. 52.

    Anderson, E. M. The Dynamics of Faulting and Dyke Formation with Applications to Britain. 2nd edn, 206 (Oliver and Boyd, London, 1951).

  53. 53.

    Corbi, F., Rivalta, E., Pinel, V., Maccaferri, F. & Acocella, V. Understanding the link between circumferential dikes and eruptive fissures around calderas based on numerical and analog models. Geophys. Res. Lett. 43, 6212–6219 (2016).

    ADS  Article  Google Scholar 

  54. 54.

    Grosfils, E. B. Magma reservoir failure on the terrestrial planets: assessing the importance of gravitational loading in simple elastic models. J. Volcanol. Geotherm. Res. 166, 47–75 (2007).

    ADS  CAS  Article  Google Scholar 

  55. 55.

    Scott Smith, B. H. Canadian kimberlites: geological characteristics relevant to emplacement. J. Volcanol. Geotherm. Res. 174, 9–19 (2008).

    ADS  CAS  Article  Google Scholar 

  56. 56.

    Gernon, T. M., Gilbertson, M. A., Sparks, R. S. J. & Field, M. The role of gas-fluidisation in the formation of massive volcaniclastic kimberlite. Lithos 112, 439–451 (2009).

    ADS  Article  Google Scholar 

  57. 57.

    Sohn, Y. K. & Chough, S. K. The Ilchulbong tuff cone, Cheju Island, South Korea. Sedimentology 39, 523–544 (1992).

    ADS  Article  Google Scholar 

  58. 58.

    Gernon, T. M., Gilbertson, M. A., Sparks, R. S. J. & Field, M. Gas-fluidisation in an experimental tapered bed: insights into processes in diverging volcanic conduits. J. Volcanol. Geotherm. Res. 174, 49–56 (2008).

    ADS  CAS  Article  Google Scholar 

  59. 59.

    Martin, U. & Németh, K. Blocky versus fluidal peperite textures developed in volcanic conduits, vents and crater lakes of phreatomagmatic volcanoes in Mio/Pliocene volcanic fields of Western Hungary. J. Volcanol. Geotherm. Res. 159, 164–178 (2007).

    ADS  CAS  Article  Google Scholar 

  60. 60.

    Busby-Spera, C. J. & White, J. D. L. Variation in peperite textures associated with differing host-sediment properties. Bull. Volcanol. 49, 765–776 (1987).

    ADS  Article  Google Scholar 

  61. 61.

    Skilling, I. P., White, J. D. L. & McPhie, J. Peperite: a review of magma–sediment mingling. J. Volcanol. Geotherm. Res. 114, 1–17 (2002).

    ADS  CAS  Article  Google Scholar 

  62. 62.

    Schöpfer, M. P. J., Abe, S., Childs, C. & Walsh, J. J. The impact of porosity and crack density on the elasticity, strength and friction of cohesive granular materials: insights from DEM modelling. Int. J. Rock Mech. Min. Sci. 46, 250–261 (2009).

    Article  Google Scholar 

  63. 63.

    Kwon, C. W. & Sohn, Y. K. Tephra-filled volcanic neck (diatreme) of a mafic tuff ring at Maegok, Miocene Eoil Basin, SE Korea. Geosci. J. 12, 317–329 (2008).

    ADS  CAS  Article  Google Scholar 

  64. 64.

    Németh, K. & Martin, U. Shallow sill and dyke complex in western Hungary as a possible feeding system of phreatomagmatic volcanoes in “soft-rock” environment. J. Volcanol. Geotherm. Res. 159, 138–152 (2007).

    ADS  Article  Google Scholar 

  65. 65.

    van den Hove, J. et al. Spatial analysis of an intra-plate basaltic volcanic field in a compressional tectonic setting: South-eastern Australia. J. Volcanol. Geotherm. Res. 335, 35–53 (2017).

    ADS  Article  Google Scholar 

  66. 66.

    Fierstein, J. & Hildreth, W. Eruptive history of the Ubehebe Crater cluster, Death Valley, California. J. Volcanol. Geotherm. Res. 335, 128–146 (2017).

    ADS  CAS  Article  Google Scholar 

  67. 67.

    Re, G., White, J. D. L., Muirhead, J. D. & Ort, M. H. Subterranean fragmentation of magma during conduit initiation and evolution in the shallow plumbing system of the small-volume Jagged Rocks volcanoes (Hopi Buttes Volcanic Field, Arizona, USA). Bull. Volcanol. 78, 55 (2016).

    ADS  Article  Google Scholar 

Download references


J.D.M. acknowledges support from National Science Foundation grant EAR-1654518. J.D.L.W. maar-diatreme work supported by NZ MBIE subcontract to GNS Science and by DEVORA (Determining Volcanic Risk in Auckland). This work represents LMV/ClerVolc contribution #290.

Author information




N.L.C. contributed to the conception and conduction of the modeling, and writing of the manuscript; J.D.M. and J.D.L.W. contributed to the initial project idea, the writing, and editing of the manuscript.

Corresponding author

Correspondence to Nicolas Le Corvec.

Ethics declarations

Competing interests

The authors declare no competing interests.

Additional information

Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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 license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license 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 license, visit

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Le Corvec, N., Muirhead, J.D. & White, J.D.L. Shallow magma diversions during explosive diatreme-forming eruptions. Nat Commun 9, 1459 (2018).

Download citation

Further reading


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.