Estimating the water holding capacity of the critical zone using near‐surface geophysics

Flinchum, Brady; Holbrook, W. S.; Grana, Dario; Parsekian, Andrew D.; Carr, Bradley J.; Hayes, J. L.; Jiao, Junfeng

doi:10.1002/hyp.13260

Cited by 73 publications

(98 citation statements)

References 103 publications

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“…We interpret the region between ∼14 and 17 m as saturated saprolite instead of a large fracture zone for three reasons. First, the maximum water content measured by the borehole NMR (0.34 m 3 m −3 ) is consistent with the average measured porosity of saprolite (0.34 ± 0.06 m 3 /m 3 ) based on 25 measurements collected along the ridge in the study area (Flinchum et al, 2018a, 2018b). Second, it occurs just above the casing depth (Fig.…”

Section: Discussionsupporting

confidence: 85%

“…8c). The water table measured by hand and reported by Flinchum et al (2018a) is associated with increased water content observed in six of the seven soundings (Fig. 8c).…”

Section: Discussionsupporting

confidence: 67%

“…Conceptually, saprolite is expected to have high porosity but will only produce an NMR response if there is water in the pore space. For our site, the saprolite porosity has been measured on laboratory samples up to depths of 9 m and ranges between 0.28 and 0.4 m 3 m −3 (Flinchum et al, 2018a). The weathered bedrock is expected to have water in fractures that could be either open or filled with weathering products, and these fractures would be bound by a rock matrix with significantly lower porosity than the saprolite.…”

Section: Discussionmentioning

confidence: 99%

“…1b; Novitsky et al, 2018). Underneath the ridge at our study site, the water table is between 12 and 13 m below the ground surface (Flinchum et al, 2018a). An ephemeral stream with numerous beaver ponds in the southern drainage reaches peak runoff between April and June.…”

mentioning

confidence: 87%

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Characterizing the Critical Zone Using Borehole and Surface Nuclear Magnetic Resonance

Flinchum

Holbrook²,

Parsekian³

et al. 2019

Vadose Zone Journal

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Core Ideas Unsaturated saprolite, saturated saprolite, and fractured rock have unique NMR responses. Surface NMR signals will be dominated by water in saturated saprolite. The heterogeneous nature of fractured rock results in low‐amplitude surface NMR signals. Understanding critical zone (CZ) structure below the first few meters of Earth's surface is challenging and yet important to understand hydrologic and surface processes that influence life on Earth. Nuclear magnetic resonance (NMR) is an emerging geophysical tool that can quantify the volume of groundwater and pore‐scale properties. Nuclear magnetic resonance has potential to aid in CZ studies, but it can be difficult to collect high‐quality NMR data in weathered and fractured rock. We present data from seven surface NMR soundings and six borehole NMR profiles collected on a weathered and fractured granite in the Laramie Range, Wyoming. First, we show that it is possible to collect high‐quality surface NMR data in a fractured rock. Second, we use the NMR data to delineate the weathering profile into three distinct zones—unsaturated saprolite, saturated saprolite, and fractured rock—and show that the surface NMR signal is dominated by saturated saprolite. Third, we show that lateral heterogeneity significantly reduces the surface NMR signal magnitude, which suggests that the boundary dividing saprolite and fractured rock is laterally heterogeneous. The NMR measurements, when combined with previously collected seismic refraction data, provide a unique opportunity to define the lateral heterogeneity of the boundary dividing saprolite and weathered bedrock in an eroding landscape underlain by crystalline rock.

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Section: Discussionsupporting

confidence: 85%

“…8c). The water table measured by hand and reported by Flinchum et al (2018a) is associated with increased water content observed in six of the seven soundings (Fig. 8c).…”

Section: Discussionsupporting

confidence: 67%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 87%

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Characterizing the Critical Zone Using Borehole and Surface Nuclear Magnetic Resonance

Flinchum

Holbrook²,

Parsekian³

et al. 2019

Vadose Zone Journal

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“…New methodological advances, particularly using geophysical methods (such as seismic refraction and nuclear magnetic resonance) can be used to test these models and characterise the resulting subsurface porosity structure that determines the water‐holding capacity of weathered bedrock (e.g. Flinchum et al , ; Rempe et al ., ).…”

Section: Water Resources In Weathered Bedrock Determine Plant Distribmentioning

confidence: 99%

Digging deeper: what the critical zone perspective adds to the study of plant ecophysiology

2020

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Summary The emergence of critical zone (CZ) science has provided an integrative platform for investigating plant ecophysiology in the context of landscape evolution, weathering and hydrology. The CZ lies between the top of the vegetation canopy and fresh, chemically unaltered bedrock and plays a pivotal role in sustaining life. We consider what the CZ perspective has recently brought to the study of plant ecophysiology. We specifically highlight novel research demonstrating the importance of the deeper subsurface for plant water and nutrient relations. We also point to knowledge gaps and research opportunities, emphasising, in particular, greater focus on the roles of deep, nonsoil resources and how those resources influence and coevolve with plants as a frontier of plant ecophysiological research.

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2021

Seismic Reservoir Modeling

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Estimating the water holding capacity of the critical zone using near‐surface geophysics

Cited by 73 publications

References 103 publications

Characterizing the Critical Zone Using Borehole and Surface Nuclear Magnetic Resonance

Characterizing the Critical Zone Using Borehole and Surface Nuclear Magnetic Resonance

Digging deeper: what the critical zone perspective adds to the study of plant ecophysiology

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