Your search keyword '"Paul J. Valdes"' showing total 6 results

1. Seasonal Temperatures in West Antarctica During the Holocene

Author

Tyler R Jones, Kurt M Cuffey, William H G Roberts, Bradley R Markle, Eric J Steig, C Max Stevens, Paul J Valdes, T J Fudge, Michael Sigl, Abigail G Hughes, Valerie Morris, Bruce H Vaughn, Joshua Garland, Bo M Vinther, Kevin S Rozmiarek, Chloe A Brashear, and James W C White

Subjects

Meteorology and Climatology

Abstract

The recovery of long-term climate proxy records with seasonal resolution is rare because of natural smoothing processes, discontinuities, and limitations in measurement resolution. Yet insolation forcing, a primary driver of multi-millennial-scale climate change, acts through seasonal variations with direct impacts on seasonal climate. Whether the sensitivity of seasonal climate to insolation matches theoretical predictions has not been assessed over long timescales. Here, we analyze a continuous record of water-isotope ratios from the West Antarctic Ice Sheet (WAIS) Divide ice core to reveal summer and winter temperature changes through the last 11,000 years. Summer temperatures in West Antarctica increased through the early-to-mid Holocene, reached a peak at 4.1 ka, and then decreased to the present. Climate model simulations show that these variations primarily reflect changes in maximum summer insolation, confirming the general connection between seasonal insolation and warming, and demonstrating the importance of insolation intensity rather than seasonally integrated insolation or season duration. Winter temperatures varied less overall, consistent with predictions from insolation forcing, but also fluctuated in the early Holocene, likely owing to changes in meridional heat transport. The magnitudes of summer and winter temperature changes constrain the lowering of the WAIS surface since the early Holocene to less than 162 m, and most likely less than 58 m, consistent with geological constraints elsewhere in West Antarctica.

Published

2023

2. Scleromochlus and the early evolution of Pterosauromorpha

Author

Davide, Foffa, Emma M, Dunne, Sterling J, Nesbitt, Richard J, Butler, Nicholas C, Fraser, Stephen L, Brusatte, Alexander, Farnsworth, Daniel J, Lunt, Paul J, Valdes, Stig, Walsh, and Paul M, Barrett

Subjects

Fossils, Animals, Models, Biological, Ecosystem, Phylogeny, Dinosaurs

Abstract

Pterosaurs, the first vertebrates to evolve powered flight, were key components of Mesozoic terrestrial ecosystems from their sudden appearance in the Late Triassic until their demise at the end of the Cretaceous

Published

2021

3. Deglacial rapid sea level rises caused by ice-sheet saddle collapses

Author

Lauren Gregoire, Paul J. Valdes, and Antony J. Payne

Subjects

geography, quaternary, Time Factors, Multidisciplinary, geography.geographical_feature_category, Oceans and Seas, Meltwater pulse 1A, ice-sheet, Antarctic sea ice, sea level, Global Warming, Arctic ice pack, Ice-sheet model, Oceanography, North America, General Circulation Model, Sea ice, Cryosphere, Computer Simulation, Ice Cover, Ice sheet, Meltwater, climate, Laurentide, Geology

Abstract

A simulation of ice sheet retreat reveals two meltwater pulses coinciding with MWP-1A and the ‘8,200-year’ event, caused by saddle collapses between ice domes. During the last deglaciation, the retreating ice sheets occasionally released massive amounts of fresh water. These 'meltwater pulses' are often implicated as important influences on abrupt climate change, but the underlying triggering mechanisms are not clear. Here Lauren Gregoire et al. show that 'saddle zones' that connect adjacent high domes on ice sheets can be lowered by ongoing warming to an elevation at which they rapidly degrade, leading to separate domes and a meltwater pulse that is consistent with geological observations. Although the mechanism itself is not novel, the authors establish that two important sudden-cooling events — meltwater pulse 1A and the '8,200-year' event — were probably caused by saddle separation. The last deglaciation (21 to 7 thousand years ago) was punctuated by several abrupt meltwater pulses, which sometimes caused noticeable climate change1,2. Around 14 thousand years ago, meltwater pulse 1A (MWP-1A), the largest of these events, produced a sea level rise of 14–18 metres over 350 years3. Although this enormous surge of water certainly originated from retreating ice sheets, there is no consensus on the geographical source or underlying physical mechanisms governing the rapid sea level rise4,5,6. Here we present an ice-sheet modelling simulation in which the separation of the Laurentide and Cordilleran ice sheets in North America produces a meltwater pulse corresponding to MWP-1A. Another meltwater pulse is produced when the Labrador and Baffin ice domes around Hudson Bay separate, which could be associated with the ‘8,200-year’ event, the most pronounced abrupt climate event of the past nine thousand years7. For both modelled pulses, the saddle between the two ice domes becomes subject to surface melting because of a general surface lowering caused by climate warming. The melting then rapidly accelerates as the saddle between the two domes gets lower, producing nine metres of sea level rise over 500 years. This mechanism of an ice ‘saddle collapse’ probably explains MWP-1A and the 8,200-year event and sheds light on the consequences of these events on climate.

Published

2012

4. Late Holocene methane rise caused by orbitally controlled increase in tropical sources

Author

Paul J. Valdes, David J. Beerling, Sarah Nelson, Pierre Friedlingstein, and Joy S. Singarayer

Subjects

Time Factors, Earth, Planet, Rain, Atmospheric sciences, Methane, chemistry.chemical_compound, Ice core, Deglaciation, Human Activities, Ice Cover, Glacial period, History, Ancient, Holocene, Tropical Climate, Multidisciplinary, Atmosphere, Hydroxyl Radical, Atmospheric methane, Agriculture, Oryza, Models, Theoretical, Plant Leaves, Oceanography, chemistry, Wetlands, Interglacial, Environmental science, Seasons, Quaternary

Abstract

Considerable debate surrounds the source of the apparently ‘anomalous’1 increase of atmospheric methane concentrations since the mid-Holocene (5,000 years ago) compared to previous interglacial periods as recorded in polar ice core records2. Proposed mechanisms for the rise in methane concentrations relate either to methane emissions from anthropogenic early rice cultivation1, 3 or an increase in natural wetland emissions from tropical4 or boreal sources5, 6. Here we show that our climate and wetland simulations of the global methane cycle over the last glacial cycle (the past 130,000 years) recreate the ice core record and capture the late Holocene increase in methane concentrations. Our analyses indicate that the late Holocene increase results from natural changes in the Earth's orbital configuration, with enhanced emissions in the Southern Hemisphere tropics linked to precession-induced modification of seasonal precipitation. Critically, our simulations capture the declining trend in methane concentrations at the end of the last interglacial period (115,000–130,000 years ago) that was used to diagnose the Holocene methane rise as unique. The difference between the two time periods results from differences in the size and rate of regional insolation changes and the lack of glacial inception in the Holocene. Our findings also suggest that no early agricultural sources are required to account for the increase in methane concentrations in the 5,000 years before the industrial era.

Published

2011

5. Constant elevation of southern Tibet over the past 15 million years

Author

Mike Widdowson, Nigel Harris, Shuang-Xing Guo, Robert A. Spicer, Paul J. Valdes, Alexei B. Herman, Jack A. Wolfe, and Simon P. Kelley

Subjects

geography, Multidisciplinary, Altitude, Plateau, geography.geographical_feature_category, Atmospheric circulation, Lithosphere, Moist static energy, Elevation, Physical geography, Monsoon, Cenozoic, Geology

Abstract

The uplift of the Tibetan plateau, an area that is 2,000 km wide, to an altitude of about 5,000 m has been shown to modify global climate and to influence monsoon intensity. Mechanical and thermal models for homogeneous thickening of the lithosphere make specific predictions about uplift rates of the Tibetan plateau, but the precise history of the uplift of the plateau has yet to be confirmed by observations. Here we present well-preserved fossil leaf assemblages from the Namling basin, southern Tibet, dated to approximately 15 Myr ago, which allow us to reconstruct the temperatures within the basin at that time. Using a numerical general circulation model to estimate moist static energy at the location of the fossil leaves, we reconstruct the elevation of the Namling basin 15 Myr ago to be 4,689 +/- 895 m or 4,638 +/- 847 m, depending on the reference data used. This is comparable to the present-day altitude of 4,600 m. We conclude that the elevation of the southern Tibetan plateau probably has remained unchanged for the past 15 Myr.

Published

2002

6. Damping seasonal variations

Author

Paul J. Valdes

Subjects

Multidisciplinary, Geology

Published

1994