Distribution of Vapor and Condensate in a Hydrothermal System: Insights From Self‐Potential Inversion at Mount Tongariro, New Zealand

Inversion of self‐potential data for source current density, j s , in complex volcanic settings, yields hydrological information without the need for a prior groundwater flow model; j s contains information about pH, pore saturation, and permeability, from which we infer the distribution of liquid and vapor phases. To understand the hydrothermal flow dynamics and hydraulic connectivity between surface thermal features at Mount Tongariro volcano, New Zealand, we undertook a reconnaissance scale self‐potential survey and developed an inversion routine for j s , constrained by an existing 3‐D conductivity model from magnetotelluric measurements. The 3‐D distribution of j s at Mount Tongariro reveals a discontinuous zero j s zone interpreted as vapor or residually saturated pore space, surrounded by low to moderate j s interpreted as circulating condensate liquid. Bounding faults act as conduits for down flowing groundwater or condensate, as well as barriers for the hydrothermal system. Localized small‐scale circulation associated with individual surface thermal features, rather than a single circulating system, accounts for the lack of widespread anomalous geochemical observations prior to the 2012 Te Maari eruption.