Determination of paleoseasonality of fossil brachiopods using shell spiral deviations and chemical proxies

Brachiopods have been extensively used in paleoclimatic and paleoecological reconstructions, but their utility would greatly increase if paleoseasonality information could be obtained from their shells. Determining seasonal seawater temperature variations from fossil brachiopods requires knowledge of specimen ontogenetic ages, which is difficult to determine compared to other organisms secreting a shell by accretion. In this study, the combination of the spiral deviation methodology and chemical proxies is tested for determining specimen ontogenetic ages and paleoseasonality using two species of fossil brachiopods, Laqueus rubellus and Terebratula terebratula, of Pleistocene and Late Miocene age, respectively. Spiral deviations were obtained for Laqueus and Terebratula using an R program developed for modern taxa, and well-preserved shells were analyzed using oxygen isotopes and Mg/Ca ratios as chemical proxies for past seawater temperature. Results reveal that locations of spiral deviations on shells of L. rubellus displayed a strong direct relationship with Mg concentrations, and resulting Mg/Ca-derived paleotemperatures were seasonal. Conversely, specimens of T. terebratula did not show a consistently strong relationship between Mg concentrations and spiral deviations, although resulting paleotemperatures agreed with those from previous studies. Overall, the results from this study indicate that the spiral deviation methodology combined with chemical proxies presents great potential for utility in past seasonal seawater temperature reconstructions in pristinely preserved, biconvex fossil brachiopods.