RAPOSEIRO, P.M., RITTER, C., ABBOTT, M., HERNANDEZ, A., PIMENTEL, A., LASHER, E., PLÓCIENNIK, M., BERLAJOLLI, V., KOTRYS, B., POMBAL, X.P., SOUTO, M., GIRALT, S., GONÇALVES, V. (2024) – Late Holocene climate dynamics in the Azores archipelago. Quaternary Science Reviews, 331: 108617. DOI: 10.1016/j.quascirev.2024.108617.

​The location of the Azores Archipelago makes this group of islands an excellent setting for investigating past long-term temperature and precipitation changes in the central North Atlantic region. Here, we present a chironomid-based quantitative temperature reconstruction and a record of oxygen isotope composition of chironomid head capsules for the last ca. 1200 years, based on the Lake Prata core (São Miguel Island, Azores). Chironomids from Lake Prata show that the temperature trend is aligned with the prevailing past global temperature trends, indicating warming during the Medieval Climate Anomaly (MCA; ca. 950-1300 CE) and subsequent cooling during the Little Ice Age (LIA; ca. 1300-1800 CE). Furthermore, changes in lake water oxygen isotope composition from chironomid head capsules were recorded with more positive δ¹⁸O values (18.2 ± 0.2‰) during the MCA and more negative values (varying between 14.8‰ and 17.6‰) during the LIA, indicating a positive shift in the precipitation-evaporation balance and/or heavier precipitation in winter relative to summer. Our study revealed that, in subtropical regions with a temperate oceanic climate and low thermal variation, there is a limited correlation between the isotopic composition of precipitation and temperature. Additionally, the temporal sequence of oxygen isotope values obtained from chironomid head capsules closely corresponds to variations in precipitation seasonality inferred from distinct climatic proxies. This consistency underscores the robustness of quantitative reconstructions and indicates that δ¹⁸Ochironomid records are promising for future investigations, especially in the context of lakes located on oceanic islands characterised by limited thermal variability.