Utilizing thermal isostasy to estimate sub-lithospheric heat flow and anomalous crustal radioactivity

• Published in: Earth and planetary science letters Vol. 450; pp. 197 - 207
• Main Authors: Hasterok, D., Gard, M.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.09.2016
• Subjects: continental lithosphere; Convection; cratons; edge-driven convection; Estimates; heat flow; heat generation; Heat loss; Heat transfer; Heat transmission; Lithosphere; Mantle; mantle heat loss; Radioactivity; ISW, Australia, Western Australia; PSE, Australia, Tasmania; mantle heat loss; continental lithosphere; heat flow; edge-driven convection; cratons; heat generation
• ISSN: 0012-821X; 1385-013X
• DOI: 10.1016/j.epsl.2016.06.037

While surface heat flow relates to the heat loss through the lithosphere, it can be difficult to quantify and separate the heat produced internally through radiogenic decay from the heat transferred across the base of the lithosphere by mantle convection. In this study, we apply a thermo-isostatic analysis to Australia and estimate the sub-lithospheric and radiogenic heat flow components by employing a simple 1-D conservation of energy model. We estimate an anomalous radiogenic heat production across much of eastern Australia generally accounting for >50 mW m−2, while western Australia appears to have high crustal compositionally corrected elevation, possibly related to chemical buoyancy of the mantle lithosphere. A moderately high sub-lithospheric heat flow (∼40 mW m−2) along the eastern and southeastern coast, including Tasmania, is coincident with locations of Cenozoic volcanism and supports an edge-driven convection hypothesis. However, the pattern of sub-lithospheric heat flow along the margin does not support the existence of hotspot tracks. Thermo-isostatic models such as these improve our ability to identify and quantify crustal from mantle sources of heat loss and add valuable constraints on tectonic and geodynamic models of the continental lithosphere's physical state and evolution. •A method for estimating crustal heat production is developed using thermal isostasy.•Chemical buoyancy for Archean roots is estimated for Australian cratons.•A sub-lithospheric heat flow high along the coast is consistent with edge-convection.•Eastern Australian heat production is 2.5 times higher than expected.