Your search keyword '"Keller, Elizabeth D."' showing total 3 results

1. Precipitation isoscapes for New Zealand: enhanced temporal detail using precipitation-weighted daily climatology.

Author

Baisden WT, Keller ED, Van Hale R, Frew RD, and Wassenaar LI

Subjects

Deuterium analysis, Meteorology, New Zealand, Oxygen Isotopes analysis, Seasons, Climate, Environmental Monitoring methods, Models, Theoretical, Rain chemistry, Snow chemistry

Abstract

Predictive understanding of precipitation δ(2)H and δ(18)O in New Zealand faces unique challenges, including high spatial variability in precipitation amounts, alternation between subtropical and sub-Antarctic precipitation sources, and a compressed latitudinal range of 34 to 47 °S. To map the precipitation isotope ratios across New Zealand, three years of integrated monthly precipitation samples were acquired from >50 stations. Conventional mean-annual precipitation δ(2)H and δ(18)O maps were produced by regressions using geographic and annual climate variables. Incomplete data and short-term variation in climate and precipitation sources limited the utility of this approach. We overcome these difficulties by calculating precipitation-weighted monthly climate parameters using national 5-km-gridded daily climate data. This data plus geographic variables were regressed to predict δ(2)H, δ(18)O, and d-excess at all sites. The procedure yields statistically-valid predictions of the isotope composition of precipitation (long-term average root mean square error (RMSE) for δ(18)O = 0.6 ‰; δ(2)H = 5.5 ‰); and monthly RMSE δ(18)O = 1.9 ‰, δ(2)H = 16 ‰. This approach has substantial benefits for studies that require the isotope composition of precipitation during specific time intervals, and may be further improved by comparison to daily and event-based precipitation samples as well as the use of back-trajectory calculations.

Published

2016

2. Global environmental consequences of twenty-first-century ice-sheet melt

Author

Golledge, Nicholas R., Keller, Elizabeth D., Gomez, Natalya, Naughten, Kaitlin A., Bernales, Jorge, Trusel, Luke D., and Edwards, Tamsin L.

Subjects

Models, Observations, Environmental aspects, Ice sheets -- Environmental aspects -- Analysis -- Models -- Observations, Surface-ice melting -- Observations -- Models, Climate change -- Environmental aspects, Oceans, Climate

Abstract

Author(s): Nicholas R. Golledge [sup.1] [sup.2] , Elizabeth D. Keller [sup.2] , Natalya Gomez [sup.3] , Kaitlin A. Naughten [sup.4] , Jorge Bernales [sup.5] , Luke D. Trusel [sup.6] , [...], Government policies currently commit us to surface warming of three to four degrees Celsius above pre-industrial levels by 2100, which will lead to enhanced ice-sheet melt. Ice-sheet discharge was not explicitly included in Coupled Model Intercomparison Project phase 5, so effects on climate from this melt are not currently captured in the simulations most commonly used to inform governmental policy. Here we show, using simulations of the Greenland and Antarctic ice sheets constrained by satellite-based measurements of recent changes in ice mass, that increasing meltwater from Greenland will lead to substantial slowing of the Atlantic overturning circulation, and that meltwater from Antarctica will trap warm water below the sea surface, creating a positive feedback that increases Antarctic ice loss. In our simulations, future ice-sheet melt enhances global temperature variability and contributes up to 25 centimetres to sea level by 2100. However, uncertainties in the way in which future changes in ice dynamics are modelled remain, underlining the need for continued observations and comprehensive multi-model assessments.Increased meltwater from the Greenland and Antarctic ice sheets will slow the Atlantic overturning circulation and warm the subsurface ocean around Antarctica, further increasing Antarctic ice loss.

Published

2019

3. Back to the Future: Using Long-Term Observational and Paleo-Proxy Reconstructions to Improve Model Projections of Antarctic Climate

Author

Bracegirdle, Thomas J., Colleoni, Florence, Abram, Nerilie J., Bertler, Nancy A. N., Dixon, Daniel A., England, Mark, Favier, Vincent, Fogwill, Chris J., Fyfe, John C., Goodwin, Ian, Goosse, Hugues, Hobbs, Will, Jones, Julie M., Keller, Elizabeth D., Khan, Alia L., Phipps, Steven J., Raphael, Marilyn N., Russell, Joellen, Sime, Louise, Thomas, Elizabeth R., van den Broeke, Michiel R., Wainer, Ilana, Sub Dynamics Meteorology, Marine and Atmospheric Research, Sub Dynamics Meteorology, Marine and Atmospheric Research, and UCL - SST/ELI/ELIC - Earth & Climate

Subjects

010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, Proxy (climate), Ice core, Paleoclimatology, paleoclimate, Antarctic climate, QE, 14. Life underwater, PMIP, Southern Ocean, climate, 0105 earth and related environmental sciences, projections, GE, PALEOCLIMATOLOGIA, lcsh:QE1-996.5, Oceanic climate, CMIP, lcsh:Geology, Geography, 13. Climate action, General Circulation Model, Climatology, General Earth and Planetary Sciences, Climate model, Observational study, Antarctic

Abstract

Quantitative estimates of future Antarctic climate change are derived from numerical global climate models. Evaluation of the reliability of climate model projections involves many lines of evidence on past performance combined with knowledge of the processes that need to be represented. Routine model evaluation is mainly based on the modern observational period, which started with the establishment of a network of Antarctic weather stations in 1957/58. This period is too short to evaluate many fundamental aspects of the Antarctic and Southern Ocean climate system, such as decadal-to-century time-scale climate variability and trends. To help address this gap, we present a new evaluation of potential ways in which long-term observational and paleo-proxy reconstructions may be used, with a particular focus on improving projections. A wide range of data sources and time periods is included, ranging from ship observations of the early 20th century to ice core records spanning hundreds to hundreds of thousands of years to sediment records dating back 34 million years. We conclude that paleo-proxy records and long-term observational datasets are an underused resource in terms of strategies for improving Antarctic climate projections for the 21st century and beyond. We identify priorities and suggest next steps to addressing this.

Published

2019