Your search keyword '"Christopher D. G. Barry"' showing total 2 results

1. Conversion of Forest to Agriculture Increases Colored Dissolved Organic Matter in a Subtropical Catchment and Adjacent Coastal Environment

Author

Samir Rosado, David M. Price, Millie Goddard-Dwyer, Chris D. Evans, Claudia G. Mayorga-Adame, Alice Fitch, Adam Pinder, Richard Sanders, Dan Lapworth, Gilbert Andrews, Jason Holt, Hannah Brittain, Christopher D. G. Barry, Claire Evans, Daniel J. Mayor, Abel Carrias, Arlene Young, Bethany K. Hughes, Sarah Cryer, and Stacey L. Felgate

Subjects

Hydrology, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, business.industry, Drainage basin, Paleontology, Soil Science, Forestry, Subtropics, Coral reef, Aquatic Science, Ecology and Environment, Marine Sciences, Colored dissolved organic matter, Agriculture, Dissolved organic carbon, Environmental science, Land use, land-use change and forestry, business, Water Science and Technology

Abstract

Land-ocean dissolved organic matter (DOM) transport is a significant and changing term in global biogeochemical cycles which is increasing as a result of human perturbation, including land-use change. Knowledge of the behavior and fate of transported DOM is lacking, particularly in the tropics and subtropics where land-use change is occurring rapidly. We used Parallel Factor (PARAFAC) Analysis to investigate how land-use influenced the composition of the DOM pool along a subtropical land-use gradient (from near-pristine broadleaf forest to agri-urban settings) in Belize, Central America. Three humic-like and two protein-like components were identified, each of which was present across land uses and environments. Land-use mapping identified a strong (R2 = 0.81) negative correlation between broadleaf forest and agri-urban land. All PARAFAC components were positively associated with agri-urban land-use classes (cropland, grassland, and/or urban land), indicating that land-use change from forested to agri-urban exerts influence on the composition of the DOM pool. Humic-like DOM exhibited linear accumulation with distance downstream and behaved conservatively in the coastal zone whilst protein-like DOM exhibited nonlinear accumulation within the main river and nonconservative mixing in coastal waters, indicative of differences in reactivity. We used a hydrodynamic model to explore the potential of conservative humics to reach the region's environmentally and economically valuable coral reefs. We find that offshore corals experience short exposures (10 ± 11 days yr−1) to large (∼120%) terrigenous DOM increases, whilst nearshore corals experience prolonged exposure (113 ± 24 days yr−1) to relatively small (∼30%) terrigenous DOM increases.

Published

2021

2. Unified concepts for understanding and modelling turnover of dissolved organic matter from freshwaters to the ocean: the UniDOM model

Author

Ricardo Torres, Edwin C. Rowe, Hannelore Waska, Dennis A. Hansell, Andrew J. Wade, Andrew Tye, Thomas R. Anderson, Amy Pickard, Vassilis Kitidis, Dan Lapworth, Edward Tipping, Chris D. Evans, Bryan M. Spears, Richard Sanders, Luca Polimene, Don Monteith, Christopher D. G. Barry, Daniel J. Mayor, and Klaus Kaiser

Subjects

Flocculation, 010504 meteorology & atmospheric sciences, Terrigenous sediment, Uv absorbance, Biogeochemistry, Flux, 010501 environmental sciences, 01 natural sciences, Ecology and Environment, Environmental chemistry, Dissolved organic carbon, Environmental Chemistry, Environmental science, Ecosystem, Biogeosciences, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

The transport of dissolved organic matter (DOM) across the land-ocean-aquatic-continuum (LOAC), from freshwater to the ocean, is an important yet poorly understood component of the global carbon budget. Exploring and quantifying this flux is a significant challenge given the complexities of DOM cycling across these contrasting environments. We developed a new model, UniDOM, that unifies concepts, state variables and parameterisations of DOM turnover across the LOAC. Terrigenous DOM is divided into two pools, T1 (strongly-UV-absorbing) and T2 (non- or weakly-UV-absorbing), that exhibit contrasting responses to microbial consumption, photooxidation and flocculation. Data are presented to show that these pools are amenable to routine measurement based on specific UV absorbance (SUVA). In addition, an autochtonous DOM pool is defined to account for aquatic DOM production. A novel aspect of UniDOM is that rates of photooxidation and microbial turnover are parameterised as an inverse function of DOM age. Model results, which indicate that ~ 5% of the DOM originating in streams may penetrate into the open ocean, are sensitive to this parameterisation, as well as rates assigned to turnover of freshly-produced DOM. The predicted contribution of flocculation to DOM turnover is remarkably low, although a mechanistic representation of this process in UniDOM was considered unachievable because of the complexities involved. Our work highlights the need for ongoing research into the mechanistic understanding and rates of photooxidation, microbial consumption and flocculation of DOM across the different environments of the LOAC, along with the development of models based on unified concepts and parameterisations.

Published

2019