Radiogenic heat production (RHP) is a major contributor to the thermal structure of the Earth's interior, primarily driven by the decay of radioactive elements. This study presents RHP data from the Rundvågshetta region, analysed using high-purity germanium (HPGe) gamma-ray spectroscopy. Rundvågshetta, located on the Sôya Coast near Lützow-Holm Bay, East Antarctica, is predominantly composed of Precambrian high-grade metamorphic rocks. The region is chiefly underlain by pyroxene gneisses, with intercalated garnet-biotite gneisses being more prevalent in the northern area. Despite its geological significance, the natural radioactivity of this region remains largely unexplored.
This study aims to determine the concentration of radionuclides and quantify radiogenic heat production rates across different lithologies. Previous research indicates that the metamorphic rocks of the Lützow-Holm Complex are derived from igneous protoliths, highlighting the need for a detailed assessment of their radiogenic properties. The heat produced by the decay of uranium (U), thorium (Th), and potassium (K) within crustal rocks plays a critical role in governing lithospheric heat flow. The relative contribution of these elements to total heat production varies significantly among different rock types.
For instance, the highest concentration of ²³⁸U (20 ppm) is observed in granitic gneiss, whereas pyroxene gneiss exhibits the lowest concentration (0.16 ppm). Similarly, ²³²Th is most enriched in garnet gneiss (3.68 ppm) and least concentrated in hornblende granulite (0.8 ppm). Additionally, felsic gneiss has the highest ⁴⁰K concentration (4.78 wt%), while pyroxene granulite records the lowest (0.16 wt%). The radiogenic heat production rates in the bedrock of Rundvågshetta range from 2.30 microwatts per cubic meter in granitic gneiss, indicative of U and Th enrichment during magmatic differentiation, to 0.15 microwatts per cubic meter in pyroxene gneiss.
These findings reveal substantial variability in RHP across different lithologies, strongly influenced by mineralogical composition. The presence of potassium feldspar, plagioclase, biotite, and trace radioactive minerals such as zircon and monazite significantly impact radionuclide concentrations. Understanding these variations is essential for refining regional heat flow models and assessing the role of geochemical differentiation in controlling radiogenic heat production. Moreover, the study underscores the importance of detailed heat production mapping for geothermal energy exploration.
Currently, heat generation maps based on radioactive decay are being developed, and we look forward to presenting them at the forthcoming conference.

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