| Abstrakt: |
A large mantle helium anomaly and separate domains of high heat flow are the predominant manifestations of bimodal magmatic activity in the Milford valley. The mantle helium anomaly (1.9–2.6 R/Ra) covers 270 km2 and is subdivided into two separated domains: a cold shallow groundwater regime and high temperature hydrothermal activity. The zone of anomalous heat flow covers >100 km2 and is also subdivided into two adjacent domains, comprising hydrothermal activity at Roosevelt Hot Springs (RHS) (3–7 W/m2) and conductive heat flow (100–180 mW/m2). While the transfer of heat and mantle helium at RHS are coupled, heat and helium transfer are decoupled in the adjacent cold groundwater regime to the west. Both the mantle helium and geothermal anomalies are attributed to recent mafic‐felsic magmatic intrusions of >400 km3, however, the absence of volcanic eruptions <500,000 years indicates magmas stall before rising to shallow crustal level <10 km depth. Deep level magmatism produces a felsic composition melt, which is inferred to be responsible for the widespread and near uniform range of diluted mantle helium values. A thick and impermeable mass of crystalline granitic basement rock at the mid‐crustal level divides the ascent of mantle helium into separate flow paths. It may also impede the rise of buoyant magma trapping thermal energy that facilitates partial melting, slow cooling, and development of a thick thermal aureole. Partitioning of convective and conductive thermal regimes and independent flow paths supplying deeply derived helium characterize the development of a large long‐lived magma‐related geothermal system. Plain Language Summary: Productive high‐grade geothermal resources, a form of renewable energy, are associated with volcanic centers and zones of hydrothermal activity in regions undergoing crustal thinning. The Milford valley in southwest Utah is host to a long dormant volcanic center whose modern expression is mostly limited to hydrothermal activity at Roosevelt Hot Springs, which has produced energy since 1984. The US Department of Energy established the Utah FORGE enhanced geothermal systems (EGS) field laboratory in an adjacent zone of extensive hot dry crystalline rock to advance new methods of energy production. Newly discovered additional natural expression of the geothermal system occurs in the shallow cold groundwaters defined by infiltration of deep‐derived mantle helium. It is the primary indication of undiscovered zones of high heat flow and geothermal resources concealed beneath the surface. The isotopic composition of the helium, plus the high geothermal heat flow, suggest that helium is derived from a large body of magma (>400 km3) that is similar in composition to the volcanic deposits that erupted 500,000 to 800,000 years ago in the nearby Mineral Mountains. A thick mass of impermeable granitic rock forms a barrier to magma ascent, suppressing the recent volcanic activity, and producing geothermal resources instead. Key Points: A large groundwater mantle He anomaly and geothermal resources are shallow manifestations of mafic‐felsic magmatism in the lower crustTwo pathways transect the crust transferring mantle He with or without heat at Roosevelt Hot Springs and the adjacent cold groundwater regimeMid‐crustal granitic basement rock impedes the rise of buoyant magma trapping thermal energy that facilitates partial melting and slow cooling [ABSTRACT FROM AUTHOR] |
Plný text