Exploring the Effect of Aspect to Inform Future Earthcasts of Climate‐Driven Changes in Weathering of Shale

Sullivan, Pamela L.; Goddéris, Yves; Shi, Yuning; Gu, Xiaoxiong; Schott, Jacques; Hasenmueller, Elizabeth A.; Kaye, Jason P.; Duffy, Christopher; Jin, Lixin; Brantley, Susan L.

doi:10.1029/2017jf004556

Cited by 22 publications

(19 citation statements)

References 54 publications

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“…Silicate weathering has been documented in the soil of the SSHCZO and accounts for some of the consumed CO 2 in the soils of Garner Run and Shale Hills (Angert et al, 2015; Jin et al, 2014). However, the rate of these weathering reactions is slow, ranging from 0.001 to 0.005 mol Si m −2 yr −1 (Sullivan et al, 2019), and at most could only consume about 0.3 mg C m −2 d −1 (Jin et al, 2014). Although model results indicate that the silicate dissolution rate is fastest in the early growing season when we observe ARQ <1, this relatively small consumption potential could not explain our observations.…”

Section: Discussionmentioning

confidence: 99%

“…This is due to the greater reactivity and higher surface area of metals in the soils of the SSHCZO than the clay minerals and quartz that largely dominate the soils in both rock types. Based on published estimates, silicate weathering at its fastest rate in Shale Hills has the potential to consume about 0.3 mg C m −2 d −1 (Sullivan et al, 2019). On the other hand, oxidation of 0.1 mmol Fe (II) kg −1 soil over a month, when assuming the reaction stoichiometry in Table 1, a soil depth of 100 cm, and bulk density of 1.2 g cm −3 , would consume about 32 mg O 2 m −2 d −1 .…”

Section: Discussionmentioning

confidence: 99%

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Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Hodges

Kim

Brantley

et al. 2019

Soil Science Soc of Amer J

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Soil CO2 and O2 cycles are coupled in some processes (e.g., respiration) but uncoupled in others (e.g., silicate weathering). One benchmark for interpreting soil biogeochemical processes affected by soil pCO2 and pO2 is to calculate the apparent respiratory quotient (ARQ). When aerobic respiration and diffusion are the dominant controls on gas concentrations, ARQ equals 1; ARQ deviates from 1 when other processes dominate soil CO2 and O2 chemistry. Here, we used ARQ to understand lithologic, hillslope, and seasonal controls on soil gases at the Susquehanna Shale Hills Critical Zone Observatory in central Pennsylvania. We measured soil pCO2 and pO2 at three depths from the soil surface to bedrock across catenas in one shale and one sandstone watershed over three growing seasons. We found that both parent lithology and hillslope position significantly affect soil gas concentrations and ARQ. Soil pCO2 was highest (>5%) and pO2 was lowest (<16%) in the valley floors. Controlling for depth, pCO2 was higher and pO2 was lower across all sites in the sandstone watershed. We attribute this pattern to higher macroporosity in sandstone lithologies, which results in greater root respiration at depth. We recorded seasonal variation in ARQ at all sites, with ARQ rising above 1 during July through September, and dipping below 1 in the early spring. We hypothesize that this seasonal fluctuation arises from anaerobic respiration in reducing microsites July through September when the soils are wet and demand for O2 is high, followed by oxidation of reduced species when the soils drain and re‐oxygenate. We estimate that this anaerobic respiration in microsites contributes 36 g C m−2 yr−1 to the soil C flux. Our results provide evidence for a conceptual model of metal cycling in temperate watersheds and point to the importance of anaerobic respiration to the carbon flux from forest soils. Core Ideas Hillslope position and lithology affect soil CO2 and O2 in humid temperate forests. The ratio of CO2 and O2 (ARQ) fluctuates over the growing season. The ARQ fluctuations indicate seasonal metal redox cycling at all hillslope positions. Anaerobic respiration is important to soil CO2 flux during the late growing season.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Hodges

Kim

Brantley

et al. 2019

Soil Science Soc of Amer J

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“…In mountain landscapes, regolith thickness is a fundamental control on water storage space and flow paths (Holbrook et al, 2014;Grant and Dietrich, 2017;Rempe and Dietrich, 2018), which together influence fluid-rock reactions (Navarre-Sitchler and Brantley, 2015) and connect ecosystems to rock-derived nutrients (Graham et al, 2010) and vital subsurface water stores (Klos et al, 2018). Studying the processes responsible for regolith architecture is therefore essential for understanding how the critical zone functions, and how it may respond to future changes (Goddéris and Brantley, 2013;Sullivan et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Strong slope‐aspect control of regolith thickness by bedrock foliation

Leone

Holbrook

Riebe

et al. 2020

Earth Surf Processes Landf

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The porous near‐surface layer of the Earth's crust – the critical zone – constitutes a vital reservoir of water for ecosystems, provides baseflow to streams, guides recharge to deep aquifers, filters contaminants from groundwater, and regulates the long‐term evolution of landscapes. Recent work suggests that the controls on regolith thickness include climate, tectonics, lithology, and vegetation. However, the relative paucity of observations of regolith structure and properties at landscape scales means that theoretical models of critical zone structure are incompletely tested. Here we present seismic refraction and electrical resistivity surveys that thoroughly characterize subsurface structure in a small catchment in the Santa Catalina Mountains, Arizona, USA, where slope‐aspect effects on regolith structure are expected based on differences in vegetation. Our results show a stark contrast in physical properties and inferred regolith thickness on opposing slopes, but in the opposite sense of that expected from environmental models and observed vegetation patterns. Although vegetation (as expressed by normalized difference vegetation index [NDVI]) is denser on the north‐facing slope, regolith on the south‐facing slope is four times thicker (as indicated by lower seismic velocities and resistivities). This contrast cannot be explained by variations in topographic stress or conventional hillslope morphology models. Instead, regolith thickness appears to be controlled by metamorphic foliation: regolith is thicker where foliation dips into the topography, and thinner where foliation is nearly parallel to the surface. We hypothesize that, in this catchment, hydraulic conductivity and infiltration capacity control weathering: infiltration is hindered and regolith is thin where foliation is parallel to the surface topography, whereas water infiltrates deeper and regolith is thicker where foliation intersects topography at a substantial angle. These results suggest that bedrock foliation, and perhaps by extension sedimentary layering, can control regolith thickness and must be accounted for in models of critical zone development. © 2020 John Wiley & Sons, Ltd.

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“…Throughout the periglacial periods during the last 1 My, the depth of frost‐cracking under the shaded N‐facing hillside remained greater than under the S‐facing side, allowing deeper hydrogeochemically driven weathering of the subsurface under the more shaded side of the catchment. This climate‐driven hydrogeochemical asymmetry can thus explain the asymmetry in erosional efficiency, hillslope, clay content, and base cation content (Sullivan et al., 2019; West et al., 2019).…”

Section: Discussionmentioning

confidence: 99%

3D Seismic Anatomy of a Watershed Reveals Climate‐Topography Coupling That Drives Water Flowpaths and Bedrock Weathering

et al. 2021

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Processes that transform bedrock into the porous regolith include fracturing, dissolution, precipitation, mechanical disaggregation, plant-and animal-related processes, and biogeochemical breakdown (e.g., Riebe et al., 2017).Regolith is important because it provides nutrients that support terrestrial life and porosity that stores groundwater (e.g., Graham et al., 2010;Riebe et al., 2017). Regolith is thinned by erosion, which physically removes material from the land surface, sometimes flattening and sometimes creating relief, shaping Earth's surface morphology and its Critical Zone (CZ) (Brantley et al., 2007). Recently, a few models have been presented that explain how the thickness of regolith responds to long-term changes in tectonics and climate (e.g., Dunne, 1990;Riebe et al., 2017;West, 2012).

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Exploring the Effect of Aspect to Inform Future Earthcasts of Climate‐Driven Changes in Weathering of Shale

Cited by 22 publications

References 54 publications

Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Strong slope‐aspect control of regolith thickness by bedrock foliation

3D Seismic Anatomy of a Watershed Reveals Climate‐Topography Coupling That Drives Water Flowpaths and Bedrock Weathering

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Exploring the Effect of Aspect to Inform Future Earthcasts of Climate‐Driven Changes in Weathering of Shale

Cited by 22 publications

References 54 publications

Soil CO2 and O2 Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Soil CO2 and O2 Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Strong slope‐aspect control of regolith thickness by bedrock foliation

3D Seismic Anatomy of a Watershed Reveals Climate‐Topography Coupling That Drives Water Flowpaths and Bedrock Weathering

Contact Info

Product

Resources

About

Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations

Soil CO₂ and O₂ Concentrations Illuminate the Relative Importance of Weathering and Respiration to Seasonal Soil Gas Fluctuations