Max Berkelhammer John A. Barron Byron A. Steinman Bruce P. Finney Mark B. Abbott Lesleigh Anderson 2016 <p><span>Lake sediment oxygen isotope records (calcium carbonate-&delta;</span>¹⁸<span>O) in the western North American Cordillera developed during the past decade provide substantial evidence of Pacific ocean&ndash;atmosphere forcing of hydroclimatic variability during the Holocene. Here we present an overview of 18 lake sediment &delta;</span>¹⁸<span>O records along with a new compilation of lake water &delta;</span>¹⁸<span>O and &delta;</span>²<span>H that are used to characterize lake sediment sensitivity to precipitation-&delta;</span>¹⁸<span>O in contrast to fractionation by evaporation. Of the 18 records, 14 have substantial sensitivity to evaporation. Two records reflect precipitation-&delta;</span>¹⁸<span>O since the middle Holocene, Jellybean and Bison Lakes, and are geographically positioned in the northern and southern regions of the study area. Their comparative analysis indicates a sequence of time-varying north&ndash;south precipitation-&delta;</span>¹⁸<span>O patterns that is evidence for a highly non-stationary influence by Pacific ocean&ndash;atmosphere processes on the hydroclimate of western North America. These observations are discussed within the context of previous research on North Pacific precipitation-&delta;</span>¹⁸<span>O based on empirical and modeling methods. The Jellybean and Bison Lake records indicate that a prominent precipitation-&delta;</span>¹⁸<span>O dipole (enriched-north and depleted-south) was sustained between ~&nbsp;3.5 and 1.5&nbsp;ka, which contrasts with earlier Holocene patterns, and appears to indicate the onset of a dominant tropical control on North Pacific ocean&ndash;atmosphere dynamics. This remains the state of the system today. Higher frequency reversals of the north&ndash;south precipitation-&delta;</span>¹⁸<span>O dipole between ~&nbsp;2.5 and 1.5&nbsp;ka, and during the Medieval Climate Anomaly and the Little Ice Age, also suggest more varieties of Pacific ocean&ndash;atmosphere modes than a single Pacific Decadal Oscillation (PDO) type analogue. Results indicate that further investigation of precipitation-&delta;</span>¹⁸<span>O patterns on short (observational) and long (Holocene) time scales is needed to improve our understanding of the processes that drive regional precipitation-&delta;</span>¹⁸<span>O responses to Pacific ocean&ndash;atmosphere variability, which in turn, will lead to a better understanding of internal Pacific ocean&ndash;atmosphere variability and its response to external climate forcing mechanisms.</span></p> application/pdf 10.1016/j.gloplacha.2015.12.021 en Elsevier Science Pub. Co. Lake oxygen isotopes as recorders of North American Rocky Mountain hydroclimate: Holocene patterns and variability at multi-decadal to millennial time scales article