Abstract We present a comprehensive multidisciplinary investigation of the Healy submarine volcano in the southern Kermadec arc, northeast of New Zealand. We show the first results of sidescan‐sonar data collected at a submarine arc volcano by an Autonomous Underwater Vehicle (AUV). We derive a seafloor geological map using visual observations including video and still photographs as well as samples collected by the manned submersible Pisces V , and integrate them with high‐resolution bathymetric data, AUV magnetics, and hydrothermal plume geochemistry, to model the complex interplay of magmatic and tectonic processes and their control on the evolution of seafloor hydrothermal activity. Our results show that recent basaltic dikes, possibly associated with the onset of back‐arc extension, preferentially intrude along structurally weakened sectors of the older caldera rim, particularly its southeastern walls, exploiting inherited structures that facilitate the upwelling of magma and fluids. Hydrothermal activity exhibits a similar spatial‐temporal transition, shifting from older venting associated with arc magmatism around the caldera rim to more recent spatially diffuse venting linked to the emplacement of basaltic dikes and extensional fracturing. This relative spatial shift in magma, vent, and fluid distribution reflects the progressive reorganization of magmatic and hydrothermal activity within an arc‐backarc transitional setting, making Healy a relevant case study for examining relative feedback among magmatic, structural, and hydrothermal processes.
Bagnasco et al. (Thu,) studied this question.