Your search keyword '"Kelly, Meredith A."' showing total 11 results

1. Holocene history of the Greenland Ice-Sheet margin in Northern Nunatarssuaq, Northwest Greenland

Author

Farnsworth, Lauren B., Kelly, Meredith A., Bromley, Gordon R. M., Axford, Yarrow, Osterberg, Erich C., Howley, Jennifer A., Jackson, Margaret S., and Zimmerman, Susan R.

Published

2018

2. Holocene climate and environmental history of East Greenland inferred from lake sediments

Author

Lusas, Amanda R., Hall, Brenda L., Lowell, Thomas V., Kelly, Meredith A., Bennike, Ole, Levy, Laura B., and Honsaker, William

Published

2017

3. Natural and anthropogenic variations in atmospheric mercury deposition during the Holocene near Quelccaya Ice Cap, Peru

Author

Beal, Samuel A., Kelly, Meredith A., Stroup, Justin S., Jackson, Brian P., Lowell, Thomas V., and Tapia, Pedro M.

Subjects

Background level, mercury record, Pre-industrial, Holocene, toxic metals, tropical climate, atmospheric deposition, purl.org/pe-repo/ocde/ford#1.05.09 [https], Mercury (metal), Cuzco [Peru], Natural sources, Lake sediments, Atmospheric mercury deposition, sediment core, Lakes, lake sediment, Quelccaya Ice Cap, Spatial extent, Peru, Reservoirs (water), Deposition, global climate, mercury (element), Tropical climates

Abstract

Mercury (Hg) is a toxic metal that is transported globally through the atmosphere. Emissions of Hg from mineral reservoirs and recycling between soil/biomass, oceans, and the atmosphere are fundamental to the global Hg cycle, yet past emissions from anthropogenic and natural sources are not fully constrained. We use a sediment core from Yanacocha, a headwater lake in southeastern Peru, to study the anthropogenic and natural controls on atmospheric Hg deposition during the Holocene. From 12.3 to 3.5 ka, Hg fluxes in the record are relatively constant (mean ± 1σ: 1.4 ± 0.6 μg m-2 a-1). Past Hg deposition does not correlate with changes in regional temperature and precipitation or with most large volcanic events that occurred regionally (~300-400 km from Yanacocha) and globally. In 1450 B.C. (3.4 ka), Hg fluxes abruptly increased and reached the Holocene-maximum flux (6.7 μg m-2 a-1) in 1200 B.C., concurrent with a ~100 year peak in Fe and chalcophile metals (As, Ag, Tl) and the presence of framboidal pyrite. Continuously elevated Hg fluxes from 1200 to 500 B.C. suggest a protracted mining-dust source near Yanacocha that is identical in timing to documented pre-Incan cinnabar mining in central Peru. During Incan and Colonial time (A.D. 1450-1650), Hg deposition remains elevated relative to background levels but lower relative to other Hg records from sediment cores in central Peru, indicating a limited spatial extent of preindustrial Hg emissions. Hg fluxes from A.D. 1980 to 2011 (4.0 ± 1.0 μg m-2 a-1) are 3.0 ± 1.5 times greater than preanthropogenic fluxes. Key Points Hg deposition did not vary with past precipitation, temperature, and volcanism Maximum Holocene Hg fluxes occurred ~3 thousand years ago Modern Hg fluxes are 3 times greater than natural fluxes.

Published

2014

4. Equilibrium line altitudes along the Andes during the Last millennium: Paleoclimatic implications.

Author

Sagredo, Esteban A., Lowell, Thomas V., Kelly, Meredith A., Rupper, Summer, Aravena, Juan Carlos, Ward, Dylan J., and Malone, Andrew G. O.

Subjects

PALEOCLIMATOLOGY, ALPINE glaciers, ALTITUDES, METEOROLOGICAL precipitation, GLACIERS

Abstract

Deciphering the climate changes that influenced the glacial fluctuations of the last millennium requires documenting the spatial and temporal patterns of these glacial events. Here, we estimate the change in equilibrium line altitudes (ELAs) between the most prominent glacial advance of the last millennium and the present for four alpine glaciers located in different climatic regimes along the Andes. For each glacier, we reconstruct scenarios of climatic conditions (temperature and precipitation anomalies) that accommodate the observed ELA changes. We focus on the following glaciers: an alpine glacier in the Cordillera Vilcanota (13°S), Tapado glacier (30°S), Cipreses glacier (34°S), and Tranquilo glacier (47°S). Our results show that the range of possible temperature and precipitation anomalies that accommodate the observed ELA changes overlap significantly at three of the four sites (i.e. Vilcanota, Cipreses, and Tranquilo). Only Tapado glacier exhibits a set of climate anomalies that differs from the other three sites. Assuming no change in precipitation, the estimated ELA changes require a cooling of at least 0.7°C in the Cordillera Vilcanota, 1.0°C at Tapado glacier, 0.6°C at Cipreses glacier, and 0.7°C at Tranquilo glacier. Conversely, assuming no change in temperature, the estimated ELA changes are explained by increases in precipitation exceeding 0.52 m yr-1 (64% of the annual precipitation) in the Cordillera Vilcanota, 0.3 1 m yr-1 (89%) at Tapado glacier, 0.22 m yr-1 (27%) at Cipreses glacier, and 0.3 m yr-1 (27%) at Tranquilo glacier. By mapping the ELA changes and modeling the potential climate forcing across diverse climate settings, we aim to contribute toward documenting the spatial variability of climate conditions during the last millennium, a key step to decipher the mechanisms underlying the glacial fluctuation that occurred during this period. [ABSTRACT FROM AUTHOR]

Published

2017

5. Changes in glacial meltwater alter algal communities in lakes of Scoresby Sund, Renland, East Greenland throughout the Holocene: Abrupt reorganizations began 1000 years before present.

Author

Slemmons, Krista E. H., Medford, Aaron, Hall, Brenda L., Stone, Jeffery R., McGowan, Suzanne, Lowell, Thomas, Kelly, Meredith, and Saros, Jasmine E.

Subjects

ALGAL communities, GLACIAL melting, HOLOCENE paleoecology, MELTWATER, ALGAL pigments

Abstract

We investigated the response of lake algal communities to changes in glacial meltwater from the Renland Ice Cap (Greenland) through the Holocene to assess whether influxes always elicit consistent responses or novel responses. We measured sedimentary algal pigments in two proximal lakes, snow-fed Raven and glacier- and snow-fed Bunny Lake, and diatom community structure and turnover in Bunny Lake. Diatom data were not available in Raven Lake. We also modeled lake-level change in Bunny Lake to identify how glacial meltwater may have altered diatom habitat availability through time. Through a series of glacier advances and retreats over the Holocene, the algal response in Bunny Lake was relatively constant until approximately 1015 yr BP, after which there were major changes in sedimentary algal remains. Algal pigment concentrations sharply declined, and diatom species richness increased. Diatom community structure underwent three reorganizations. Until 1015 yr BP, assemblages were dominated by Pinnularia braunii and Aulacoseira pffaffiana. However, approximately 1015-480 yr BP, these species declined and Tabellaria flocculosa and Hannaea arcus became a significant component of the assemblage. Approximately 440 yr BP, A. pfaffiana increased along with species indicating elevated nitrogen. In contrast, the algal pigment records from nearby snow-fed Raven Lake showed different and minimal change through time. Our results suggest that changes in the magnitude and composition of meltwater in our two study lakes were unique over the last 1000 yr BP and elicited a non-linear threshold response absent during other periods of glacier advance and retreat. Deciphering the degree to which glaciers structure algal communities over time has strong implications for lakes as glaciers continue to recede. [ABSTRACT FROM AUTHOR]

Published

2017

6. Holocene fluctuations of Bregne ice cap, Scoresby Sund, east Greenland: a proxy for climate along the Greenland Ice Sheet margin.

Author

Levy, Laura B., Kelly, Meredith A., Lowell, Thomas V., Hall, Brenda L., Hempel, Laura A., Honsaker, William M., Lusas, Amanda R., Howley, Jennifer A., and Axford, Yarrow L.

Subjects

*ICE caps, *HOLOCENE paleoclimatology, *ICE sheets, *SHIELDS (Geology), *CLIMATE change, *MAGNETIC susceptibility

Abstract

Abstract: The Greenland Ice Sheet is a major component of the Arctic cryosphere and the magnitude of its response to future climate changes remains uncertain. Longer-term records of climate near the ice sheet margin provide information about natural climate variability and can be used to understand the causes of past changes in the Greenland Ice Sheet. As a proxy for Holocene climate near the ice sheet margin, we reconstruct the fluctuations of Bregne ice cap in the Scoresby Sund region of central east Greenland. Bregne is a small ice cap (2.5 km2 in area) and responds sensitively to summer temperatures. We employ a multi-proxy approach to reconstruct the ice cap fluctuations using geomorphic mapping, 10Be ages of boulders and bedrock and lake sediment records. Past extents of Bregne ice cap are marked by moraines and registered by sediments in downvalley lakes. 10Be ages of bedrock and boulders outboard of the moraines indicate that Bregne ice cap was within ∼250 m of its present-day limit by at least 10.7 ka. Multi-proxy data from sediments in Two Move lake, located downvalley from Bregne ice cap, indicate that the ice cap likely completely disappeared during early and middle Holocene time. Increasing magnetic susceptibility and percent clastic material from ∼6.5 to ∼1.9 cal ka BP in Two Move lake sediments suggest progressively colder conditions and increased snow accumulation on the highlands west of the lake. Laminated silt deposited at ∼2.6 cal ka BP and ∼1.9 cal ka BP to present registers the onset and persistence of Bregne ice cap during the late Holocene. 10Be ages of boulders on an unweathered, unvegetated moraine in the Bregne ice cap forefield range from 0.74 to 9.60 ka. The youngest 10Be age (0.74 ka) likely represents the age of the moraine whereas older ages may be due to 10Be inherited from prior periods of exposure. This late Holocene moraine marks the second largest advance of the ice cap since deglaciation of the region at the end of the last ice age. The oldest moraine in the forefield dates to ≤2.6 cal ka BP. The fluctuations of Bregne ice cap were likely influenced by Northern Hemisphere summer insolation throughout the Holocene and abrupt late Holocene cold events. [Copyright &y& Elsevier]

Published

2014

7. Age of the Ørkendalen moraines, Kangerlussuaq, Greenland: constraints on the extent of the southwestern margin of the Greenland Ice Sheet during the Holocene

Author

Levy, Laura B., Kelly, Meredith A., Howley, Jennifer A., and Virginia, Ross A.

Subjects

*ICE sheets, *HOLOCENE Epoch, *MORAINES, *CLIMATOLOGY, *GEOMORPHOLOGY

Abstract

Abstract: Although Greenland ice core records register relatively stable Holocene climate conditions, the lower elevation margins of the Greenland Ice Sheet (GrIS) experienced significant Holocene fluctuations. These fluctuations include ice sheet recession during the Holocene Thermal Maximum (9–5 ka) and advance during the Little Ice Age (LIA; ∼A.D. 1350–1880). Determining the extent and timing of these fluctuations is important for understanding the response of the GrIS to interglacial climate conditions both warmer and colder than at present and for developing accurate ice sheet models. Sets of moraines marking past extents of the southwestern GrIS margin occur in the Kangerlussuaq region. We focus on the Ørkendalen moraines, a prominent moraine set located within 2 km of the modern ice margin and just outboard of the LIA moraines. We present the first 10Be ages of the Ørkendalen moraines indicating they were deposited at 6.8 ± 0.3 ka. The geomorphic relationship between the Ørkendalen and LIA moraines indicates that the ice sheet margin was inboard of its Ørkendalen extent between ∼6.8 ka and the culmination of the LIA. The age of the Ørkendalen moraines provides an important constraint on the extent of the southwestern GrIS during the middle Holocene. [Copyright &y& Elsevier]

Published

2012

8. Middle to late Holocene chronology of the western margin of the Greenland Ice Sheet: A comparison with Holocene temperature and precipitation records.

Author

Levy, Laura B., Kelly, Meredith A., Applegate, Patrick A., Howley, Jennifer A., and Virginia, Ross A.

Subjects

HOLOCENE Epoch

Abstract

The response of the Greenland Ice Sheet to future climate change is relatively unconstrained. Determining the extents and rates of ice-margin fluctuations during the Holocene provides a longer-term perspective on ice-sheet changes and offers an analogue of how the ice-sheet may respond to future changes. Here, we present sixteen new 10Be ages of boulders on moraines, boulders perched on bedrock, and bedrock surfaces that mark the timing of ice-margin fluctuations during the Holocene in the Kangerlussuaq region of southern west Greenland. We show that the Keglen moraines date to 8.0 ± 0.3 ka (n = 6) and that the average ice-margin retreat rate slowed from about 49 to 13 m yr−1 after about 8.0 ka, likely in response to the ice margin retreating onto land at the head of the fjord Kangerlussuaq at this time. The average retreat rate further slowed to less than 1 m yr−1 between 6.8 ka and 4.2 cal kyr BP, a time when nearby paleoclimate records document warm summers and increased precipitation. Finally, we show that the historical advances of the ice margin occurred during the past 200 years, likely in response to cooler summer temperatures. [ABSTRACT FROM AUTHOR]

Published

2018

9. Holocene temperatures and isotopes of precipitation in Northwest Greenland recorded in lacustrine organic materials.

Author

Lasher, G. Everett, Axford, Yarrow, McFarlin, Jamie M., Kelly, Meredith A., Osterberg, Erich C., and Berkelhammer, Max B.

Subjects

*LAKE hydrology, *OXYGEN isotopes, *LAKE sediments, *HOLOCENE Epoch, *ISOTOPE geology, *ARCTIC climate

Abstract

Reconstructions of Holocene lake water isotopic composition based upon subfossil aquatic organic material offer new insights into Arctic climate. We present quantitative estimates of warmth during the Holocene Thermal Maximum in northwest Greenland, inferred from oxygen isotopes of chironomid head capsules and aquatic moss preserved in lake sediments. δ 18 O values of chironomids from surface sediments of multiple Greenland lakes indicate that these subfossil remains record the δ 18 O values of the lake water in which they grow. Our lake water δ 18 O reconstruction is supported by downcore agreement with δ 18 O values in aquatic moss and chironomid remains. δ 18 O of both organic materials from Secret Lake decrease after 4 ka (ka = thousands of years ago) by 3‰ into the Neoglacial. We argue that lake water at Secret Lake primarily reflects precipitation δ 18 O values, which is strongly correlated with air temperature in NW Greenland, and that this signal is biased towards summer and early autumn conditions. Other factors may have influenced Secret Lake δ 18 O values through the Holocene, including evaporation of lake water and changing seasonality and source of precipitation. The maximum early Holocene summer and early autumn-biased temperature anomaly at Secret Lake is 2.5–4 °C warmer than present from 7.7 (the beginning of our record) to ∼6 ka. The maximum late Holocene cold anomaly (which includes the Little Ice Age) is 1.5–3 °C colder than present. These ranges of possible temperature anomalies reflect uncertainty in the δ 18 O – temperature relationship for precipitation at the study site through the Holocene. [ABSTRACT FROM AUTHOR]

Published

2017

10. The dynamics of warming during the last deglaciation in high-elevation regions of Eastern Equatorial Africa.

Author

Garelick, Sloane, Russell, James, Richards, Adin, Smith, Jamila, Kelly, Meredith, Anderson, Nathan, Jackson, Margaret S., Doughty, Alice, Nakileza, Bob, Ivory, Sarah, Dee, Sylvia, and Marshall, Charlie

Subjects

*LAST Glacial Maximum, *GLACIAL melting, *TEMPERATURE lapse rate, *RADIATIVE forcing, *ICE cores

Abstract

Tropical mountain environments, such as the Rwenzori Mountains in equatorial Africa, are thought to be particularly sensitive to climate change. Ongoing warming in the Rwenzori is impacting local environments and communities through glacial retreat, fires, and flooding. Paleoclimate reconstructions from elsewhere in Africa suggest considerable warming accompanied glacier retreat during the last glacial termination, from ∼21 thousand years before present (ka) through the early to mid-Holocene. Quantifying these changes has been difficult but could help to assess future impacts in the Rwenzori. Here, we present a ∼21 thousand-year (kyr) temperature reconstruction based on the relative abundance of branched glycerol dialkyl glycerol tetraethers (brGDGTs) from Lake Mahoma (2,990 m above sea level; m asl) in the Rwenzori Mountains, Uganda. Our record, paired with existing Rwenzori glacial moraine 10Be exposure ages, suggests that deglacial warming and glacial retreat began by ∼20 ka and accelerated at ∼18–18.5 ka. The timing of the onset of rapid warming matches the timing of the post-glacial rise in radiative forcing from atmospheric greenhouse gases (GHGs) from Antarctic ice cores (Brook et al., 1996; Marcott et al., 2014; Monnin et al., 2004; Schilt et al., 2010). Our temperature reconstruction registers ∼4.9 °C warming from the Last Glacial Maximum (LGM) to the late Holocene. This increase is larger than the average ∼2-4 °C warming observed in records from lower elevation sites in tropical East Africa, but similar to that observed at other high-elevation sites in this region. The increased warming at higher elevations thus confirms that the temperature lapse rate steepened during the LGM over this region. Our results also indicate ∼3 °C of warming during the mid-Holocene relative to the late Holocene. This suggests that the freezing-level height rose above Rwenzori summit elevations at that time, likely causing complete deglaciation of the Rwenzori Mountains from ∼5 to 7 ka. The mid-Holocene is thus a potential analog for the glacial and environmental changes that these mountains are likely to experience in the coming decades. Overall, the timing and magnitude of temperature change observed in our record has important implications for climate model projections of future warming in tropical Africa. • We produce a 21 kyr temperature record from alpine Lake Mahoma, Uganda. • Rwenzori glaciers and vegetation are very sensitive to past temperature change. • ∼3 °C warming during middle Holocene caused complete deglaciation in Rwenzori. • Regional temperature records indicate a steeper tropical lapse rate during the LGM. • Tropical lapse rate shoaled and stabilized during the middle and late Holocene. [ABSTRACT FROM AUTHOR]

Published

2022

11. Holocene glacial history of Renland Ice Cap, East Greenland, reconstructed from lake sediments.

Author

Medford, Aaron K., Hall, Brenda L., Lowell, Thomas V., Kelly, Meredith A., Levy, Laura B., Wilcox, Paul S., and Axford, Yarrow

Subjects

*ICE caps, *LAKE sediments, *CRYOSPHERE, *HOLOCENE Epoch, *SEA ice, *GLACIERS, *CLIMATE change, *SEDIMENTATION & deposition

Abstract

Shrinking glaciers, melting permafrost, and reduced sea ice all indicate rapid contraction of the Arctic cryosphere in response to present-day climate warming, a trajectory that is expected to continue, if not accelerate. The reaction of the Arctic cryosphere to past periods of climate variation can afford insight into its present and future behavior. Here, we examine a ∼12,000 year record of glacier fluctuations and meltwater variation associated with the Renland Ice Cap, East Greenland, that extends from the early Holocene thermal optimum through the cooling of the Little Ice Age to present. Sediment records from glacially fed lakes indicate rapid early Holocene deglaciation, with ice extent likely slightly smaller than at present by ∼9500 yr BP. Glacial activity resulted in occasional deposition of rock flour in the studied lakes in the early Holocene until at least ∼7500 yr BP. Rock flour is absent for much of the period ∼7000-4000 yr BP, suggesting ice extent generally was smaller than at present. However, thin layers of blue-gray clay throughout this period may indicate millennial-scale ice expansions, with Renland Ice Cap briefly reaching extents during cold phases that may have been similar to today. Glacial sediment deposition occurred again in the late Holocene at ∼3200–3400 yr BP and was followed by a brief glacial episode at ∼1340 yr BP and then a major event beginning shortly after ∼1050 yr BP. We infer that rock flour deposition in the lakes in the last millennium corresponds with advance of Renland glaciers to their Little Ice Age positions, marked by a fresh, gray drift limit. Radiocarbon dates of in situ plant remains adjacent to the present ice cap indicate a short relatively warm period ∼500 yr ago, when ice was within its AD 2011 limit, followed by glacier readvance. The general pattern of ice fluctuations in Renland is similar to that at other ice caps in the region, but also has important differences, including the preservation of a possible mid-Holocene record at times when lower-elevation ice caps in the Scoresby Sund region may have been absent. This finding reinforces the concept that examination of multiple geographic and geomorphologic settings is necessary for a full understanding of ice variations in a region. • Sediments from glacially fed lakes constrain the Holocene history of Renland Ice Cap. • Ice extent was similar to or smaller than at present by ∼10,000 yr BP. • Millennial-scale glacier fluctuations occurred throughout the Holocene. • Examination of multiple geographic settings is necessary for a full understanding of ice variations in a region. [ABSTRACT FROM AUTHOR]

Published

2021