2014


Jacqueline Romero

Jacqueline Romero


Years participated in RESESS:
2014


Poster
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An Overview

Major: Geophysics
Academic Affiliation: Southern Methodist University
Research Mentors: Holly Barnard and Kamini Singha
Communication Mentor: Hannah Rose Grist


Biography

Jackie’s love for Earth Science was developed in her 8th grade science class as volcanoes, earthquakes, and weather patterns marveled her. As an undergraduate at Southern Methodist University, she rediscovered her love for the geosciences and recently declared as a Geophysics and Applied Mathematics double major. Her interests in geophysics were enhanced through her RESESS research project dealing with measuring the Electrical Resistivity of soils and relating that to moisture content. Also enhanced were her lungs, as her summer experience was replete with fieldwork at elevations alien to her native Dallas, Texas home.


Abstract

Using Electrical Resistivity Imaging to examine soil moisture and tree transpiration interactions

Determining the relationships between tree transpiration and soil moisture content is important in understanding how natural processes affect the amount of water available for human use. Electrical Resistivity (ER) imaging presents a minimally invasive method that could be used to explore subsurface flow paths of water and how these are affected by tree transpiration. We used ER to examine interactions between ponderosa pine transpiration and soil moisture throughout an 8 by 8 grid of stainless steel electrodes inserted 20cm into the soil. We collected 30-48 continuous hours of soil ER data per week for seven weeks and measured sapflow on eight nearby trees at 30 min intervals. We found diel fluctuations in soil ER with 25 ohm-m differences between peak and minimum values. These diel shifts in soil ER are strongly correlated with diurnal patterns of tree transpiration observed in sap-flow data, with correlation coefficients ranging from .86-.95. On the other hand, correlation coefficients of approximately .20 for data obtained from soil moisture sensors demonstrate that, unlike the more spatially detailed ER measurements, single point measurements are less likely to pick up subtle or deep moisture changes adjacent to the root zone of a tree. Additionally, diel fluctuations in soil ER lagged behind sapflow by an average of 4hrs, we hypothesize these lags are due to trees possibly storing water in their xylem. Thus, even though the tree begins transpiring it does not immediately draw water from the soil. Future work will include correcting ER data to ensure data are purely representative of soil moisture trends. Furthermore, the data will be transformed into subsurface images of the soil and, ideally, will show the flow patterns of water in the soil throughout the day via inversion.


Presentation