Abstract
Sea-level change is thought to influence the frequencies of volcanic eruptions on glacial to interglacial timescales. However, the underlying physical processes and their importance relative to other influences (for example, magma recharge rates) remain poorly understood. Here we compare an approximately 360-kyr-long record of effusive and explosive eruptions from the flooded caldera volcano at Santorini (Greece) with a high-resolution sea-level record spanning the last four glacial–interglacial cycles. Numerical modelling shows that when the sea level falls by 40 m below the present-day level, the induced tensile stresses in the roof of the magma chamber of Santorini trigger dyke injections. As the sea level continues to fall to −70 or −80 m, the induced tensile stress spreads throughout the roof so that some dykes reach the surface to feed eruptions. Similarly, the volcanic activity gradually disappears after the sea level rises above −40 m. Synchronizing Santorini’s stratigraphy with the sea-level record using tephra layers in marine sediment cores shows that 208 out of 211 eruptions (both effusive and explosive) occurred during periods constrained by sea-level falls (below −40 m) and subsequent rises, suggesting a strong absolute sea-level control on the timing of eruptions on Santorini—a result that probably applies to many other volcanic islands around the world.
Highlights
To simulate the influence of sea-level loading, we present the results of numerical modelling (Fig. 2; Supplementary Information Figure 2) which indicate that stress changes due to changes in sea-level during the Late Quaternary are sufficient to trigger or inhibit dyke injection from the magma chamber
We model the shallow magma chamber at 4 km depth as a 6 km-wide sill-like flat ellipsoid and initially in lithostatic equilibrium with the host rock
During the rise above -40 m there exist recently formed feederdykes (Fig. 3), some of which are still hot and perhaps partly molten close to the chamber. We suggest that these different conditions explain why during sea level rise eruptions stop at sea level of 0 m; 10.7 +/- 3.6 kyr) rather than at -40 m at 132.5 +/- 2.1 ka
Summary
The authors thank the two excellent reviewers who greatly improved the quality of the manuscript. CS dedicates his contribution to this paper to Amy and Rory
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