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Arctic Environmental Change across the Pliocene-Pleistocene TransitionKeisling, Benjamin Andrew 17 July 2015 (has links)
Environmental change in the Arctic proceeds at an unprecedented rate. The Pliocene epoch (5-2.65 million years ago) represents an analog for future climate conditions, with pCO2 and continental configurations similar to present. Yet conditions in the Pliocene Arctic are poorly characterized because of sparse sampling. The records that do exist indicate periods of extreme warmth, as well as the first expansion of large ice-sheets in the Northern Hemisphere, took place from the end of the Pliocene into the early Pleistocene. Understanding these deposits and their implications for our future requires developing a sense of climatic evolution across the Plio-Pleistocene transition and especially during the intensification of Northern Hemisphere Glaciation (iNHG) ~2.7 million years ago. Here we reconstruct environmental change in the Arctic using a suite of organic geochemical proxies in a sedimentary archive recovered from Lake El'gygytgyn, Arctic Northeast Russia. We use the distribution of branched glycerol dialkyl glycerol tetraethers (brGDGTs) and the hydrogen isotopic composition (δD) of plant leaf-waxes (n-alkanes) to reconstruct relative temperature change across the interval spanning 2.8 to 2.4 million years ago. Our work demonstrates that, following the first major glaciation of the Northern Hemisphere, it took multiple glacial cycles for the Arctic to become synchronized with the climatic changes recorded in the deep ocean. This work has implications for understanding the role of sea-level, sea-ice, vegetation and carbon-cycle feedbacks in a changing Arctic.
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Within Lake Spatial Variability of Long-chain n-alkanes and their Hydrogen Isotopic Compositions Adirondack Mountains, NYBates, Benjamin R. 30 October 2018 (has links)
No description available.
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Advancing Leaf Carbon Isotopes as a Paleo ProxySchlanser, Kristen M. 22 October 2020 (has links)
No description available.
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Reconstructing Holocene Indian Summer Monsoon Variability Using High Resolution Sediments from the Southeastern TibetPerello, Melanie Marie 12 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The Indian summer monsoon (ISM) is the dominant hydrometeorological
phenomenon that provides the majority of precipitation to southern Asia and southeastern
Tibet specifically. Reliable projections of ISM rainfall are critical for water management
and hinge on our understanding of the drivers of the monsoon system and how these
drivers will be impacted by climate change. Because instrumental climate records are
limited in space and time, natural climate archives are required to understand how the
ISM varied in the past in response to changes in climatic boundary climate conditions.
Lake sediments are high-resolution natural paleoclimate archive that are widely
distributed across the Tibetan Plateau, making them useful for investigating long-term
precipitation trends and their response to climatic boundary conditions. To investigate
changes in monsoon intensity during the Holocene, three lakes were sampled along an
east-west transect in southeastern Tibet: Galang Co, Nir’Pa Co, and Cuobu. Paleoclimate
records from each lake were developed using isotopic (leaf wax hydrogen isotopes; δ2H),
sedimentological, and geochemical proxies of precipitation and lake levels. Sediments
were sampled at high temporal frequencies, with most proxies resolved at decadal scales,
to capture multi-decadal to millennial-scale variability in monsoon intensity and local
hydroclimate conditions. The ISM was strongest in the early Holocene as evidenced by
leaf-wax n-alkane δ2H at both Cuobu and Galang Co corresponding with Cuobu’s higher
lake levels and effective moisture. Monsoon intensity declined at Cuobu and Galang Co
around 6 ka which corresponds to reduced riverine sediment influxes at Cuobu and
deeper lake levels at Galang Co. The antiphase relationship between lake levels and
monsoon intensity at Galang Co is attributed to air temperatures and effective moisture,
with a warmer and drier local hydroclimate driving early Holocene low lake levels. The
late Holocene ISM was more variable with wet and dry periods, as seen in the Nir’Pa Co
lake level and leaf wax n-alkane δ2H record. These records demonstrate coherent drivers
of synoptic and local hydroclimate that account for Holocene ISM expression across the
southeastern Tibetan Plateau, indicating possible drivers of future monsoon expression
under climate change.
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