Decoding the oxygen isotope signal for seasonal growth patterns in Arctic bivalves

• Published in: Palaeogeography, palaeoclimatology, palaeoecology Vol. 446; pp. 263 - 283
• Main Authors: Vihtakari, Mikko, Renaud, Paul E., Clarke, Leon J., Whitehouse, Martin J., Hop, Haakon, Carroll, Michael L., Ambrose, William G.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.03.2016
• Subjects: Bivalvia; Brackish; Ciliatocardium ciliatum; Den föränderliga jorden; Dynamic time warping; Marine; Sclerochronology; Secondary ion mass spectrometry; Serripes groenlandicus; The changing Earth; PNE, Norway, Svalbard, Spitsbergen, Ny-Aalesund, Kongsfjorden; PN, Arctic; Sclerochronology; Secondary ion mass spectrometry; Ciliatocardium ciliatum; Serripes groenlandicus; Dynamic time warping
• ISSN: 0031-0182; 1872-616X; 1872-616X
• DOI: 10.1016/j.palaeo.2016.01.008

Chemical and physical variations in skeletal structures of marine organisms can reflect environmental variability, forming the basis for reconstructing the conditions in which the organism lived. The successful use of these bio-archives for reconstructing seasonal environmental conditions is dependent on understanding intra-annual growth patterns and timing of their deposition within skeletal structures. We studied intra-annual shell growth patterns, as well as the timing and environmental processes associated with winter growth line deposition in two circumpolar bivalve mollusks, Serripes groenlandicus and Ciliatocardium ciliatum. Shell growth deposited during a 1-year deployment on oceanographic moorings in Kongsfjorden and Rijpfjorden, Svalbard, was analyzed in situ for δ18O values using high spatial resolution secondary ion mass spectrometry (SIMS). A new digital method was developed to measure the location of SIMS spots along chronologically deposited shell material. Dynamic time warping algorithms were adapted to align SIMS-determined δ18O values with δ18O values predicted from continuous mooring instrument recordings of seawater temperature and salinity, in order to derive intra-annual shell growth models. The resulting growth models indicated that the prominent winter growth band was formed during a slow shell growth period lasting from December until May in Kongsfjorden and from November until mid-June in Rijpfjorden. The length of the slow growth period was most likely controlled by food availability. Shell growth rate during the growing season was significantly explained by temperature (marginal R2=0.29, p<0.001) indicating that temperature partly drives shell growth rate when the food supply is sufficient. The insights into intra-annual shell growth of Arctic bivalves and the methods developed in our study are important contributions for further development of bivalve shells as proxy archives. •Annual shell growth of two Arctic bivalve species was sampled for δ18O using SIMS.•A new digital method is described to model intra-annual shell growth.•Shell growth was fast during summer and very slow during winter.•Growth bands were formed in winter during the slow shell growth period.•Length of the slow growth period was controlled by low food availability.