Your search keyword '"Aron, Phoebe"' showing total 3 results

1. Variability and Controls on δ18O, d‐excess, and ∆′17O in Southern Peruvian Precipitation.

Author

Aron, Phoebe G., Poulsen, Christopher J., Fiorella, Richard P., Levin, Naomi E., Acosta, Rene P., Yanites, Brian J., and Cassel, Elizabeth J.

Subjects

HYDROLOGIC cycle, CLIMATE change, METEOROLOGICAL precipitation, OXYGEN isotopes, PALEOALTIMETRY

Abstract

The isotopic composition of precipitation is used to trace water cycling and climate change, but interpretations of the environmental information recorded in central Andean precipitation isotope ratios are hindered by a lack of multi‐year records, poor spatial distribution of observations, and a predominant focus on Rayleigh distillation. To better understand isotopic variability in central Andean precipitation, we present a three‐year record of semimonthly δ18Op and δ2Hp values from 15 stations in southern Peru and triple oxygen isotope data, expressed as ∆′17Op, from 32 precipitation samples. Consistent with previous work, we find that elevation correlates negatively with δ18Op and that seasonal δ18Op variations are related to upstream rainout and local convection. Spatial δ18Op variations and atmospheric back trajectories show that both eastern‐ and western‐derived air masses bring precipitation to southern Peru. Seasonal d‐excessp cycles record moisture recycling and relative humidity at remote moisture sources, and both d‐excessp and ∆′17Op clearly differentiate evaporated and non‐evaporated samples. These results begin to establish the natural range of unevaporated ∆′17Op values in the central Andes and set the foundation for future paleoclimate and paleoaltimetry studies in the region. This study highlights the hydrologic understanding that comes from a combination of δ18Op, d‐excessp, and ∆′17Op data and helps identify the evaporation, recycling, and rainout processes that drive water cycling in the central Andes. Key Points: The isotopic composition of central Andean precipitation records upstream precipitation, local convection, and remote moisture sourcesPrecipitation on the flank of the western central Andes is sourced from the Pacific Ocean∆'17O can separate evaporated and non‐evaporated samples and provides key baseline information for Andean paleoclimate and paleoaltimetry [ABSTRACT FROM AUTHOR]

Published

2021

2. An isotopic approach to partition evapotranspiration in a mixed deciduous forest.

Author

Aron, Phoebe G., Poulsen, Christopher J., Fiorella, Richard P., Matheny, Ashley M., and Veverica, Timothy J.

Subjects

MIXED forests, WATER storage, EVAPOTRANSPIRATION, HYDROLOGIC cycle, DECIDUOUS forests, STABLE isotopes, WEATHER

Abstract

Transpiration (T) is perhaps the largest fluxes of water from the land surface to the atmosphere and is susceptible to changes in climate, land use and vegetation structure. However, predictions of future transpiration fluxes vary widely and are poorly constrained. Stable water isotopes can help expand our understanding of land–atmosphere water fluxes but are limited by a lack of observations and a poor understanding of how the isotopic composition of transpired vapour (δT) varies. Here, we present isotopic data of water vapour, terrestrial water and plant water from a deciduous forest to understand how vegetation affects water budgets and land–atmosphere water fluxes. We measured subdiurnal variations of δ18OT from three tree species and used water isotopes to partition T from evapotranspiration (ET) to quantify the role of vegetation in the local water cycle. We find that δ18OT deviated from isotopic steady‐state during the day but find no species‐specific patterns. The ratio of T to ET varied from 53% to 61% and was generally invariant during the day, indicating that diurnal evaporation and transpiration fluxes respond to similar atmospheric and micrometeorological conditions at this site. Finally, we compared the isotope‐inferred ratio of T to ET with results from another ET partitioning approach that uses eddy covariance and sap flux data. We find broad midday agreement between these two partitioning techniques, in particular, the absence of a diurnal cycle, which should encourage future ecohydrological isotope studies. Isotope‐inferred estimates of transpiration can inform land surface models and improve our understanding of land–atmosphere water fluxes. [ABSTRACT FROM AUTHOR]

Published

2020

3. Tracing Water Cycling and Variability in Forests and Mountainous Regions with Stable Water Isotopes

Author

Aron, Phoebe

Subjects

water cycle, water isotopes, forest, mountains

Abstract

Water is one of the most important substances on Earth and links carbon and energy cycles within the climate system. Global precipitation is predicted to increase as the atmosphere continues to warm, but the rate, timing, and magnitude of local and regional terrestrial hydrologic change are still uncertain. This dissertation presents new understanding of ecosystem and regional scale water cycling from observations of stable oxygen and hydrogen isotope ratios in water. These ratios, referred to as stable water isotopes, are useful hydrologic tracers because they integrate and record information about processes such as evaporation, transpiration, condensation, crystallization, and hydrologic mixing that drive the water cycle. Understanding stable water isotope variation helps trace these processes and offers insight into how the hydrologic system may respond in warmer conditions. This dissertation presents new stable water isotope data to study water cycling in deciduous forests (Chapters 2 and 3) and in the central Andes in South America (Chapter 4). Chapter 5 presents and explains variation in the triple oxygen isotope system, which until recently had not been applied to hydrologic problems and can add important information about water cycling. These chapters include new observations of high temporal resolution water vapor isotopes and a global dataset of precipitation and surface water isotope variability that is built on citizen science and crowdsourced sample collection. Results and implications from this dissertation help constrain local and regional scale uncertainties in the terrestrial hydrologic cycle. Chapters 2 and 3 focus on ecosystem scale forest hydrology and use water vapor isotopes to quantify the role of plants in local and regional water cycles. Chapter 2 presents a comparison of water vapor isotopes in two adjacent deciduous forest sites in northern lower Michigan and shows that structural disturbances in forest canopies can affect boundary layer mixing and increase ecosystem-atmosphere gas exchange. Chapter 3 presents a new technique to measure the isotopic composition of transpired water vapor from trees and quantitatively partition land-atmosphere water fluxes. This method is developed and applied to study forest hydrology and can also be used in non-forested ecosystems to explain the diurnal variation of water vapor isotopes and estimate land-atmosphere water fluxes from vegetation other than trees. Chapters 4 and 5 increase the spatial and temporal scales of inquiry and focus on the isotopic composition of precipitation and surface water. Chapter 4 presents a three-year record of bimonthly precipitation isotope data from a network of 19 stations in southern Peru. This chapter shows that precipitation on the western flank of the central Andes is sourced from the Pacific Ocean and that precipitation patterns on the Altiplano and Eastern Cordillera are related to local topography, synoptic-scale convection, and moisture recycling as airmasses move across the Amazon Basin. Chapter 5 presents an introduction to meteoric water triple oxygen isotopes and explains the hydrologic processes in tropical, temperate, and polar regions that drive variation in this isotope system. This chapter serves as a practical guide and point of reference for researchers who might want to use triple oxygen isotope data in hydrologic and paleohydrologic studies. Together, these chapters demonstrate the utility of stable water isotopes to trace terrestrial water cycling and help better understand how forest and mountain hydrology may change in the coming decades.

Published

2020