Your search keyword '"O. O. Ogunro"' showing total 4 results

1. A physically based framework for modeling the organic fractionation of sea spray aerosol from bubble film Langmuir equilibria

Author

Philip J. Rasch, Lynn M. Russell, Susannah M. Burrows, O. O. Ogunro, Amanda A. Frossard, and Scott Elliott

Subjects

chemistry.chemical_classification, Atmospheric Science, Langmuir, Biogeochemistry, Sea spray, Atmospheric sciences, lcsh:QC1-999, Aerosol, lcsh:Chemistry, Adsorption, lcsh:QD1-999, chemistry, Environmental chemistry, Dissolved organic carbon, Cloud condensation nuclei, Organic matter, lcsh:Physics

Abstract

The presence of a large fraction of organic matter in primary sea spray aerosol (SSA) can strongly affect its cloud condensation nuclei activity and interactions with marine clouds. Global climate models require new parameterizations of the SSA composition in order to improve the representation of these processes. Existing proposals for such a parameterization use remotely sensed chlorophyll a concentrations as a proxy for the biogenic contribution to the aerosol. However, both observations and theoretical considerations suggest that existing relationships with chlorophyll a, derived from observations at only a few locations, may not be representative for all ocean regions. We introduce a novel framework for parameterizing the fractionation of marine organic matter into SSA based on a competitive Langmuir adsorption equilibrium at bubble surfaces. Marine organic matter is partitioned into classes with differing molecular weights, surface excesses, and Langmuir adsorption parameters. The classes include a lipid-like mixture associated with labile dissolved organic carbon (DOC), a polysaccharide-like mixture associated primarily with semilabile DOC, a protein-like mixture with concentrations intermediate between lipids and polysaccharides, a processed mixture associated with recalcitrant surface DOC, and a deep abyssal humic-like mixture. Box model calculations have been performed for several cases of organic adsorption to illustrate the underlying concepts. We then apply the framework to output from a global marine biogeochemistry model, by partitioning total dissolved organic carbon into several classes of macromolecules. Each class is represented by model compounds with physical and chemical properties based on existing laboratory data. This allows us to globally map the predicted organic mass fraction of the nascent submicron sea spray aerosol. Predicted relationships between chlorophyll a and organic fraction are similar to existing empirical parameterizations, but can vary between biologically productive and nonproductive regions, and seasonally within a given region. Major uncertainties include the bubble film thickness at bursting, and the variability of organic surfactant activity in the ocean, which is poorly constrained. In addition, polysaccharides may enter the aerosol more efficiently than Langmuir adsorption would suggest. Potential mechanisms for enrichment of polysaccharides in sea spray include the formation of marine colloidal particles that may be more efficiently swept up by rising bubbles, and cooperative adsorption of polysaccharides with proteins or lipids. These processes may make important contributions to the aerosol, but are not included here. This organic fractionation framework is an initial step towards a closer linking of ocean biogeochemistry and aerosol chemical composition in Earth system models. Future work should focus on improving constraints on model parameters through new laboratory experiments or through empirical fitting to observed relationships in the real ocean and atmosphere, as well as on atmospheric implications of the variable composition of organic matter in sea spray.

Published

2014

2. Biogeochemical Equation of State for the Sea-Air Interface

Author

Oliver W. Wingenter, Heather C. Allen, Zachary Menzo, O. O. Ogunro, Georgina A. Gibson, Forrest M. Hoffman, Scott Elliott, and Amadini Jayasinghe

Subjects

Atmospheric Science, Equation of state, 010504 meteorology & atmospheric sciences, Prandtl number, ecogeography, Wind stress, Flux, 02 engineering and technology, upper ocean eddies, lcsh:QC851-999, Environmental Science (miscellaneous), Prandtl stress, Surface pressure, momentum-heat-gas-salt exchange, 01 natural sciences, bubbles, Surface tension, symbols.namesake, capillaries, marine surface tension and pressure, 0105 earth and related environmental sciences, Physics, Momentum (technical analysis), Scale (chemistry), Mechanics, 021001 nanoscience & nanotechnology, proxy compounds, symbols, lcsh:Meteorology. Climatology, food web dynamics, interfacial equation of state, global monolayer, 0210 nano-technology, surfactant macromolecules

Abstract

We have recently argued that marine interfacial surface tension must have a distinctive biogeography because it is mediated by fresh surfactant macromolecules released locally through the food web. Here we begin the process of quantification for associated climate flux implications. A low dimensionality (planar) equation of state is invoked at the global scale as our main analysis tool. For the reader&rsquo, s convenience, fundamental surfactant physical chemistry principles are reviewed first, as they pertain to tangential forces that may alter oceanic eddy, ripple, and bubble fields. A model Prandtl (neutral) wind stress regime is defined for demonstration purposes. It is given the usual dependence on roughness, but then in turn on the tension reduction quantity known as surface pressure. This captures the main net influences of biology and detrital organics on global microlayer physics. Based on well-established surrogate species, tangent pressures are related to distributed ecodynamics as reflected by the current marine systems science knowledge base. Reductions to momentum and related heat-vapor exchange plus gas and salt transfer are estimated and placed on a coarse biogeographic grid. High primary production situations appear to strongly control all types of transfer, whether seasonally or regionally. Classic chemical oceanographic data on boundary state composition and behaviors are well reproduced, and there is a high degree of consistency with conventional micrometeorological wisdom. But although our initial best guesses are quite revealing, coordinated laboratory and field experiments will be required to confirm the broad hypotheses even partially. We note that if the concepts have large scale validity, they are super-Gaian. Biological control over key planetary climate-transfer modes may be accomplished through just a single rapidly renewed organic monolayer.

Published

2019

3. Evaluating Uncertainties in Marine Biogeochemical Models: Benchmarking Aerosol Precursors

Author

Oliver W. Wingenter, Scott Elliott, Nathan Collier, O. O. Ogunro, Forrest M. Hoffman, Weiwei Fu, and Clara Deal

Subjects

0106 biological sciences, Atmospheric Science, Biogeochemical cycle, Coupled model intercomparison project, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Global warming, Benchmarking, Environmental Science (miscellaneous), Radiative forcing, Atmospheric sciences, 01 natural sciences, Aerosol, Earth system science, biogeochemistry, benchmarking, biogenic volatile organic compounds, dissolved organic carbon, sea-air flux, marine aerosols, earth system modeling, Environmental science, Baseline (configuration management), 0105 earth and related environmental sciences

Abstract

The effort to accurately estimate global radiative forcing has long been hampered by a degree of uncertainty in the tropospheric aerosol contribution. Reducing uncertainty in natural aerosol processes, the baseline of the aerosol budget, thus becomes a fundamental task. The appropriate representation of aerosols in the marine boundary layer (MBL) is essential to reduce uncertainty and provide reliable information on offsets to global warming. We developed an International Ocean Model Benchmarking package to assess marine biogeochemical process representations in Earth System Models (ESMs), and the package was employed to evaluate surface ocean concentrations and the sea–air fluxes of dimethylsulfide (DMS). Model performances were scored based on how well they captured the distribution and variability contained in high-quality observational datasets. Results show that model-data biases increased as DMS enters the MBL, but unfortunately over three-quarters of the models participating in the fifth Coupled Model Intercomparison Project (CMIP5) did not have a dynamic representation of DMS. When it is present, models tend to over-predict sea surface concentrations in the productive region of the eastern tropical Pacific by almost a factor of two, and the sea–air fluxes by a factor of three. Systematic model-data benchmarking as described here will help to identify such deficiencies and subsequently lead to improved subgrid-scale parameterizations and ESM development.

Published

2018

4. Prospects for simulating macromolecular surfactant chemistry at the ocean–atmosphere boundary

Author

Oliver W. Wingenter, Scott Elliott, Xiaohong Liu, Lynn M. Russell, Clara Deal, O. O. Ogunro, Susannah M. Burrows, and Michael S. Long

Subjects

Renewable Energy, Sustainability and the Environment, Chemistry, Public Health, Environmental and Occupational Health, chemistry.chemical_element, Sea spray, Kelvin equation, Aerosol, Atmosphere, Boundary layer, symbols.namesake, Oceanography, Chemical physics, Phase (matter), Monolayer, symbols, Carbon, General Environmental Science

Abstract

Biogenic lipids and polymers are surveyed for their ability to adsorb at the water–air interfaces associated with bubbles, marine microlayers and particles in the overlying boundary layer. Representative ocean biogeochemical regimes are defined in order to estimate local concentrations for the major macromolecular classes. Surfactant equilibria and maximum excess are then derived based on a network of model compounds. Relative local coverage and upward mass transport follow directly, and specific chemical structures can be placed into regional rank order. Lipids and denatured protein-like polymers dominate at the selected locations. The assigned monolayer phase states are variable, whether assessed along bubbles or at the atmospheric spray droplet perimeter. Since oceanic film compositions prove to be irregular, effects on gas and organic transfer are expected to exhibit geographic dependence as well. Moreover, the core arguments extend across the sea–air interface into aerosol–cloud systems. Fundamental nascent chemical properties including mass to carbon ratio and density depend strongly on the geochemical state of source waters. High surface pressures may suppress the Kelvin effect, and marine organic hygroscopicities are almost entirely unconstrained. While bubble adsorption provides a well-known means for transporting lipidic or proteinaceous material into sea spray, the same cannot be said of polysaccharides. Carbohydrates tend to be strongly hydrophilic so that their excess carbon mass is low despite stacked polymeric geometries. Since sugars are abundant in the marine aerosol, gel-based mechanisms may be required to achieve uplift. Uncertainties distill to a global scale dearth of information regarding two dimensional kinetics and equilibria. Nonetheless simulations are recommended, to initiate the process of systems level quantification.

Published

2014