Your search keyword '"Tyler R. Jones"' showing total 2 results

1. High-frequency climate variability in the Holocene from a coastal-dome ice core in east-central Greenland

Author

Valerie Morris, Christian Holme, Vasileios Gkinis, James W. C. White, Bradley R. Markle, Bo Møllesøe Vinther, C. Max Stevens, Abigail G. Hughes, Bruce H. Vaughn, and Tyler R. Jones

Subjects

ARCTIC-OCEAN, SURFACE MASS-BALANCE, δ18O, lcsh:Environmental protection, Stratigraphy, NORTH-ATLANTIC CLIMATE, Proxy (climate), lcsh:Environmental pollution, Ice core, Sea ice, lcsh:TD169-171.8, Glacial period, TEMPERATURE, lcsh:Environmental sciences, Holocene, lcsh:GE1-350, Global and Planetary Change, geography, geography.geographical_feature_category, Global warming, Paleontology, Arctic ice pack, DIFFUSION, TRANSPORT, PRECIPITATION, lcsh:TD172-193.5, SHEET, Physical geography, STABLE WATER ISOTOPES, SEA-ICE, Geology

Abstract

An ice core drilled on the Renland ice cap in east-central Greenland contains a continuous climate record dating through the last glacial period. The Renland record is valuable because the coastal environment is more likely to reflect regional sea surface conditions compared to inland Greenland ice cores that capture synoptic variability. Here we present the δ18O water isotope record for the Holocene, in which decadal-scale climate information is retained for the last 8 kyr, while the annual water isotope signal is preserved throughout the last 2.6 kyr. To investigate regional climate information preserved in the water isotope record, we apply spectral analysis techniques to a 300-year moving window to determine the mean strength of varying frequency bands through time. We find that the strength of 15–20-year δ18O variability exhibits a millennial-scale signal in line with the well-known Bond events. Comparison to other North Atlantic proxy records suggests that the 15–20-year variability may reflect fluctuating sea surface conditions throughout the Holocene, driven by changes in the strength of the Atlantic Meridional Overturning Circulation. Additional analysis of the seasonal signal over the last 2.6 kyr reveals that the winter δ18O signal has experienced a decreasing trend, while the summer signal has predominantly remained stable. The winter trend may correspond to an increase in Arctic sea ice cover, which is driven by a decrease in total annual insolation, and is also likely influenced by regional climate variables such as atmospheric and oceanic circulation. In the context of anthropogenic climate change, the winter trend may have important implications for feedback processes as sea ice retreats in the Arctic.

Published

2020

2. Siple Dome shallow ice cores: a study in coastal dome microclimatology

Author

Trevor Popp, Tyler R. Jones, and James W. C. White

Subjects

lcsh:GE1-350, Global and Planetary Change, Atmospheric circulation, lcsh:Environmental protection, Stratigraphy, Borehole, Microclimate, Paleontology, Snow, Dome (geology), Oceanography, lcsh:Environmental pollution, Ice core, Climatology, lcsh:TD172-193.5, lcsh:TD169-171.8, Precipitation, lcsh:Environmental sciences, Geology, Orographic lift

Abstract

Ice cores at Siple Dome, West Antarctic receive the majority of their precipitation from Pacific Ocean moisture sources. Pacific climate patterns, particularly in response to the El Niño-Southern Oscillation, affect local temperature, atmospheric circulation, snow accumulation, and water isotope signals at Siple Dome. We examined borehole temperatures, accumulation, and water isotopes from a number of shallow ice cores recovered from a 60 km north–south transect of the Dome. The data (with coverage from 1920–1995) reveal a microclimate heavily influenced by ENSO and the location of the Amundsen Sea Low Pressure Area. The Dome Summit and Pacific Flank respond to La Niña conditions by warming, increased isotope ratios, higher deuterium excess, and increased snowfall. The Inland Flank responds to El Niño conditions and cold interior air masses by cooling, decreased isotope ratios, lower deuterium excess, and decreased snowfall. ENSO-type spectral signatures (2–7 yr) are present in all water isotope records, but are not similar in their power structures. A longer 300 yr wavelet analysis record from the Dome Summit shows a late 19th-century climate shift similar to that seen in South Pacific coral isotope records. Our analyses suggest that while an ENSO signal is evident at Siple Dome, the microclimate effect makes climate reconstruction problematic, a conclusion which should be considered at other West Antarctic coastal dome locations.

Published

2014