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Título: | Contrasting controls on tree ring isotope variation for Amazon floodplain and terra firme trees |
Autor: | Cintra, Bruno Bar?ante Ladvocat Gloor, Manuel U. Boom, Arnoud Schöngart, Jochen Locosselli, Giuliano Maselli Brienen, Roel J.W. |
Palavras-chave: | Carbon Isotope Deciduous Tree Floodplain Oxygen Isotope Seasonal Variation Seasonality Tree Ring Tropical Forest Amazonia Cedrela Odorata Macrolobium Acaciifolium Carbon Carbon-13 Oxygen Oxygen-18 Biological Model Chemistry Forest Hydrology Physiology Plant Leaf Season Tree Tropic Climate Carbon Isotopes Forests Hydrology Models, Biological Oxygen Isotopes Plant Leaves Seasons Trees Tropical Climate |
Data do documento: | 2019 |
Revista: | Tree Physiology |
É parte de: | Volume 39, Número 5, Pags. 845-860 |
Abstract: | Isotopes in tropical trees rings can improve our understanding of tree responses to climate. We assessed how climate and growing conditions affect tree-ring oxygen and carbon isotopes (δ18OTR and δ13CTR) in four Amazon trees. We analysed within-ring isotope variation for two terra firme (non-flooded) and two floodplain trees growing at sites with varying seasonality. We find distinct intra-annual patterns of δ18OTR and δ13CTR driven mostly by seasonal variation in weather and source water δ18O. Seasonal variation in isotopes was lowest for the tree growing under the wettest conditions. Tree ring cellulose isotope models based on existing theory reproduced well observed within-ring variation with possible contributions of both stomatal and mesophyll conductance to variation in δ13CTR. Climate analysis reveal that terra firme δ18OTR signals were related to basin-wide precipitation, indicating a source water δ18O influence, while floodplain trees recorded leaf enrichment effects related to local climate. Thus, intrinsically different processes (source water vs leaf enrichment) affect δ18OTR in the two different species analysed. These differences are likely a result of both species-specific traits and of the contrasting growing conditions in the floodplains and terra firme environments. Simultaneous analysis of δ13CTR and δ18OTR supports this interpretation as it shows strongly similar intra-annual patterns for both isotopes in the floodplain trees arising from a common control by leaf stomatal conductance, while terra firme trees showed less covariation between the two isotopes. Our results are interesting from a plant physiological perspective and have implications for climate reconstructions as trees record intrinsically different processes. © The Author(s) 2019. |
DOI: | 10.1093/treephys/tpz009 |
Aparece nas coleções: | Artigos |
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