Hemond Harold F.

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Hemond
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Harold F.
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  • Article
    A conduit dilation model of methane venting from lake sediments
    (American Geophysical Union, 2011-03-26) Scandella, Benjamin P. ; Varadharajan, Charuleka ; Hemond, Harold F. ; Ruppel, Carolyn D. ; Juanes, Ruben
    Methane is a potent greenhouse gas, but its effects on Earth's climate remain poorly constrained, in part due to uncertainties in global methane fluxes to the atmosphere. An important source of atmospheric methane is the methane generated in organic-rich sediments underlying surface water bodies, including lakes, wetlands, and the ocean. The fraction of the methane that reaches the atmosphere depends critically on the mode and spatiotemporal characteristics of free-gas venting from the underlying sediments. Here we propose that methane transport in lake sediments is controlled by dynamic conduits, which dilate and release gas as the falling hydrostatic pressure reduces the effective stress below the tensile strength of the sediments. We test our model against a four-month record of hydrostatic load and methane flux in Upper Mystic Lake, Mass., USA, and show that it captures the complex episodicity of methane ebullition. Our quantitative conceptualization opens the door to integrated modeling of methane transport to constrain global methane release from lakes and other shallow-water, organic-rich sediment systems, and to assess its climate feedbacks.
  • Article
    A differential pressure instrument with wireless telemetry for in-situ measurement of fluid flow across sediment-water boundaries
    (Molecular Diversity Preservation International, 2009-01-09) Gardner, Alan T. ; Karam, Hanan N. ; Mulligan, Ann E. ; Harvey, Charles F. ; Hammar, Terence R. ; Hemond, Harold F.
    An instrument has been built to carry out continuous in-situ measurement of small differences in water pressure, conductivity and temperature, in natural surface water and groundwater systems. A low-cost data telemetry system provides data on shore in real time if desired. The immediate purpose of measurements by this device is to continuously infer fluxes of water across the sediment-water interface in a complex estuarine system; however, direct application to assessment of sediment-water fluxes in rivers, lakes, and other systems is also possible. Key objectives of the design include both low cost, and accuracy of the order of ±0.5 mm H2O in measured head difference between the instrument’s two pressure ports. These objectives have been met, although a revision to the design of one component was found to be necessary. Deployments of up to nine months, and wireless range in excess of 300 m have been demonstrated.
  • Preprint
    Nonequilibrium clumped isotope signals in microbial methane
    ( 2015-02-09) Wang, David T. ; Gruen, Danielle S. ; Lollar, Barbara Sherwood ; Hinrichs, Kai-Uwe ; Stewart, Lucy C. ; Holden, James F. ; Hristov, Alexander N. ; Pohlman, John W. ; Morrill, Penny L. ; Konneke, Martin ; Delwiche, Kyle B. ; Reeves, Eoghan P. ; Sutcliffe, Chelsea N. ; Ritter, Daniel J. ; Seewald, Jeffrey S. ; McIntosh, Jennifer C. ; Hemond, Harold F. ; Kubo, Michael D. Y. ; Cardace, Dawn ; Hoehler, Tori M. ; Ono, Shuhei
    Methane is a key component in the global carbon cycle with a wide range of anthropogenic and natural sources. Although isotopic compositions of methane have traditionally aided source identification, the abundance of its multiply-substituted “clumped” isotopologues, e.g., 13CH3D, has recently emerged as a proxy for determining methane-formation temperatures; however, the impact of biological processes on methane’s clumped isotopologue signature is poorly constrained. We show that methanogenesis proceeding at relatively high rates in cattle, surface environments, and laboratory cultures exerts kinetic control on 13CH3D abundances and results in anomalously elevated formation temperature estimates. We demonstrate quantitatively that H2 availability accounts for this effect. Clumped methane thermometry can therefore provide constraints on the generation of methane in diverse settings, including continental serpentinization sites and ancient, deep groundwaters.
  • Article
    Ephemerality of discrete methane vents in lake sediments
    (John Wiley & Sons, 2016-05-04) Scandella, Benjamin ; Pillsbury, Liam ; Weber, Thomas C. ; Ruppel, Carolyn D. ; Hemond, Harold F. ; Juanes, Ruben
    Methane is a potent greenhouse gas whose emission from sediments in inland waters and shallow oceans may both contribute to global warming and be exacerbated by it. The fraction of methane emitted by sediments that bypasses dissolution in the water column and reaches the atmosphere as bubbles depends on the mode and spatiotemporal characteristics of venting from the sediments. Earlier studies have concluded that hot spots—persistent, high-flux vents—dominate the regional ebullitive flux from submerged sediments. Here the spatial structure, persistence, and variability in the intensity of methane venting are analyzed using a high-resolution multibeam sonar record acquired at the bottom of a lake during multiple deployments over a 9 month period. We confirm that ebullition is strongly episodic, with distinct regimes of high flux and low flux largely controlled by changes in hydrostatic pressure. Our analysis shows that the spatial pattern of ebullition becomes homogeneous at the sonar's resolution over time scales of hours (for high-flux periods) or days (for low-flux periods), demonstrating that vents are ephemeral rather than persistent, and suggesting that long-term, lake-wide ebullition dynamics may be modeled without resolving the fine-scale spatial structure of venting.