Mass‐balance modeling of mineral weathering rates and CO<sub>2</sub> consumption in the forested, metabasaltic Hauver Branch watershed, Catoctin Mountain, Maryland, USA

Price, James E.; Rice, Karen C.; Szymanski, David W.

doi:10.1002/esp.3373

Cited by 18 publications

(4 citation statements)

References 109 publications

(270 reference statements)

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“…The input–output mass balance that lies at the core of many of these compilations is still widely used in studies of catchment‐scale weathering fluxes (Bricker et al , ; Velbel and Price, ). In one of the contributions to this special issue, for example, Price et al () describe how they used the input–output mass‐balance approach to quantify calcite weathering rates in the deep CZ.…”

Section: Observations Of the Deep Czmentioning

confidence: 99%

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Riebe

Hahm

Brantley

2016

Earth Surf Processes Landf

265

263

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The base of Earth's critical zone (CZ) is commonly shielded from study by many meters of overlying rock and regolith. Though deep CZ processes may seem far removed from the surface, they are vital in shaping it, preparing rock for infusion into the biosphere and breaking Earth materials down for transport across landscapes. This special issue highlights outstanding challenges and recent advances of deep CZ research in a series of articles that we introduce here in the context of relevant literature dating back to the 1500s. Building on several contributions to the special issue, we highlight four exciting new hypotheses about factors that drive deep CZ weathering and thus influence the evolution of life-sustaining CZ architecture. These hypotheses have emerged from recently developed process-based models of subsurface phenomena including: fracturing related to subsurface stress fields; weathering related to drainage of bedrock under hydraulic head gradients; rock damage from frost cracking due to subsurface temperature gradients; and mineral reactions with reactive fluids in subsurface chemical potential gradients. The models predict distinct patterns of subsurface weathering and CZ thickness that can be compared with observations from drilling, sampling and geophysical imaging. We synthesize the four hypotheses into an overarching conceptual model of fracturing and weathering that occurs as Earth materials are exhumed to the surface across subsurface gradients in stress, hydraulic head, temperature, and chemical potential. We conclude with a call for a coordinated measurement campaign designed to comprehensively test the four hypotheses across a range of climatic, tectonic and geologic conditions.

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Section: Observations Of the Deep Czmentioning

confidence: 99%

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Riebe

Hahm

Brantley

2016

Earth Surf Processes Landf

265

263

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“…Carbon and cations are then sequestered together in marine carbonate deposits. Siliceous lithologies account for c. 60-75% of the total CO 2 consumption via bedrock, equivalent to c. 240-1100 megatons of atmospheric carbon removed per year in various estimates (Hartmann et al, 2009;Price et al, 2013;Strefler et al, 2018). The sequestration effect increases with runoff and temperature and is magnified by topographic relief (Hartmann et al, 2009;Balagizi et al, 2015;Jagoutz et al, 2016;Li et al, 2016;Zhang et al, 2021).…”

Section: The Process: Rocksmentioning

confidence: 99%

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Wilf

Kooyman

2023

New Phytologist

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Summary Many tree genera in the Malesian uplands have Southern Hemisphere origins, often supported by austral fossil records. Weathering the vast bedrock exposures in the everwet Malesian tropics may have consumed sufficient atmospheric CO2 to contribute significantly to global cooling over the past 15 Myr. However, there has been no discussion of how the distinctive regional tree assemblages may have enhanced weathering and contributed to this process. We postulate that Gondwanan‐sourced tree lineages that can dominate higher‐elevation forests played an overlooked role in the Neogene CO2 drawdown that led to the Ice Ages and the current, now‐precarious climate state. Moreover, several historically abundant conifers in Araucariaceae and Podocarpaceae are likely to have made an outsized contribution through soil acidification that increases weathering. If the widespread destruction of Malesian lowland forests continues to spread into the uplands, the losses will threaten unique austral plant assemblages and, if our hypothesis is correct, a carbon sequestration engine that could contribute to cooler planetary conditions far into the future. Immediate effects include the spread of heat islands, significant losses of biomass carbon and forest‐dependent biodiversity, erosion of watershed values, and the destruction of tens of millions of years of evolutionary history.

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“…As a result, the signal is likely a function of calcite weathering. This has been shown to occur in similar environments, and has been known to function as an indicator of deep weathering (White et al, 1999;Price et al, 2013;Riebe et al, 2016).…”

Section: X-ray Fluorescencementioning

confidence: 99%

Bedrock to soil: In-situ measurement and analytical techniques for initial weathering of proglacial environments

Lorentz¹

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<p>Dirt. It is more important than one might think. Soil, along with its bedrock-derived components, provides a nexus in the earth system for energy, nutrient, and atmospheric control; yet it is a finite resource. Soils are consumed, transported, and replenished by natural and anthropogenic forces. Weathering—both physical and chemical—is the key process breaking down and regenerating the ions and mineral constituents of soils, facilitating the pathways from solid bedrock to soil to the rest of the global ecosystem. Yet our understanding of weathering is incomplete and the available methods to investigate these processes are limited. Here, the fundamental processes of weathering are questioned by studying them at their origins, the rock surface. New techniques were developed in pursuit of quantifying weathering at small scales in-situ, to obtain the highest resolution measurements possible. These were carried out in the proglacial regions of two New Zealand glaciers, Brewster Glacier and Franz Josef Glacier. Proglacial bedrock environments provided a clean-slate model from which to measure incipient weathering at increasing exposure ages. To mitigate error, a holistic approach encompassing weathering signals from multiple angles was taken. Spatial characterisation was completed through the capture of structure-from-motion photogrammetry (SFM) at multiple scales of observation. The resultant three dimensional surface models had an average error of 1.06x10-1 mm. The models were characterised for weathering using roughness as a novel multi-point analysis of surface features, through two separate novel methods utilising global polynomial interpolation filtering and continuous wavelet transform analysis. Physical samples were collected from the field for cosmogenic radionuclide surface exposure age dating. Compositional analysis was performed through X-ray fluorescence, as well as electron microprobe analysis (EPMA). Nano-scale structural and compositional trends were investigated through optical analysis of backscatter electron imaging and secondary electron imaging. Non-directional roughness and volumetric analysis patterns present compelling information to support negligible weathering occurring on bedrock surfaces in proglacial environments. Lithologic variation was identified as a strong influence on the results. Compositional analysis demonstrated insignificant levels of chemical alteration between sites, corroborating the spatial modelling results. The lack of surficial weathering in highly productive weathering environments necessitates the role of additional weathering factors. Deep subsurface weathering was investigated and presents the strongest case as a major contributor to chemical denudation. Validating the presence of deep weathering in many environments critically alters the knowledge required to evaluate and predict patterns of landscape evolution. By establishing a better understanding of how bedrock weathers in-situ, the groundwork is laid for making more accurate and educated forecasts on how the earth system will respond to changes in the future.</p>

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Mass‐balance modeling of mineral weathering rates and CO₂ consumption in the forested, metabasaltic Hauver Branch watershed, Catoctin Mountain, Maryland, USA

Cited by 18 publications

References 109 publications

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Bedrock to soil: In-situ measurement and analytical techniques for initial weathering of proglacial environments

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Mass‐balance modeling of mineral weathering rates and CO2 consumption in the forested, metabasaltic Hauver Branch watershed, Catoctin Mountain, Maryland, USA

Cited by 18 publications

References 109 publications

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Controls on deep critical zone architecture: a historical review and four testable hypotheses

Do Southeast Asia's paleo‐Antarctic trees cool the planet?

Bedrock to soil: In-situ measurement and analytical techniques for initial weathering of proglacial environments

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Mass‐balance modeling of mineral weathering rates and CO₂ consumption in the forested, metabasaltic Hauver Branch watershed, Catoctin Mountain, Maryland, USA