Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes

A 1D numerical reaction-transport model (RTM) that is a coupled system of partial differential equations is created to simulate prominent physical and biogeochemical processes and interactions in limnological environments. The prognostic variables considered are temperature, horizontal velocity, sal...

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Main Author: Stojanovic, Severin
Language:en
Published: 2011
Subjects:
Online Access:http://hdl.handle.net/10393/20231
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-OOU.-en#10393-202312013-01-11T13:33:11ZNumerical Reaction-transport Model of Lake Dynamics and Their Eutrophication ProcessesStojanovic, Severinlimnologyreaction-transportmodellingmodelinglakeeutrophicationnumericalturbulencefluidhydrodynamictrophicself-consistent trophic state indexsctsireaction transportA 1D numerical reaction-transport model (RTM) that is a coupled system of partial differential equations is created to simulate prominent physical and biogeochemical processes and interactions in limnological environments. The prognostic variables considered are temperature, horizontal velocity, salinity, and turbulent kinetic energy of the water column, and the concentrations of phytoplankton, zooplankton, detritus, phosphate (H3PO4), nitrate (NO3-), ammonium (NH4+), ferrous iron (Fe2+), iron(III) hydroxide (Fe(OH)3(s)), and oxygen (O2) suspended within the water column. Turbulence is modelled using the k-e closure scheme as implemented by Gaspar et al. (1990) for oceanic environments. The RTM is used to demonstrate how it is possible to investigate limnological trophic states by considering the problem of eutrophication as an example. A phenomenological investigation of processes leading to and sustaining eutrophication is carried out. A new indexing system that identifies different trophic states, the so-called Self-Consistent Trophic State Index (SCTSI), is proposed. This index does not rely on empirical measurements that are then compared to existing tables for classifying limnological environments into particular trophic states, for example, the concentrations of certain species at certain depths to indicate the trophic state, as is commonly done in the literature. Rather, the index is calculated using dynamic properties of only the limnological environment being considered and examines how those properties affect the sustainability of the ecosystem. Specifically, the index is calculated from a ratio of light attenuation by the ecosystem’s primary biomass to that of total light attenuation by all particulate species and molecular scattering throughout the entire water column. The index is used to probe various simulated scenarios that are believed to be relevant to eutrophication: nutrient loading, nutrient limitation, overabundance of phytoplankton, solar-induced turbulence, and wind-induced turbulence.2011-09-22T15:25:59Z2011-09-22T15:25:59Z20112011-09-22http://hdl.handle.net/10393/20231en
collection NDLTD
language en
sources NDLTD
topic limnology
reaction-transport
modelling
modeling
lake
eutrophication
numerical
turbulence
fluid
hydrodynamic
trophic
self-consistent trophic state index
sctsi
reaction transport
spellingShingle limnology
reaction-transport
modelling
modeling
lake
eutrophication
numerical
turbulence
fluid
hydrodynamic
trophic
self-consistent trophic state index
sctsi
reaction transport
Stojanovic, Severin
Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
description A 1D numerical reaction-transport model (RTM) that is a coupled system of partial differential equations is created to simulate prominent physical and biogeochemical processes and interactions in limnological environments. The prognostic variables considered are temperature, horizontal velocity, salinity, and turbulent kinetic energy of the water column, and the concentrations of phytoplankton, zooplankton, detritus, phosphate (H3PO4), nitrate (NO3-), ammonium (NH4+), ferrous iron (Fe2+), iron(III) hydroxide (Fe(OH)3(s)), and oxygen (O2) suspended within the water column. Turbulence is modelled using the k-e closure scheme as implemented by Gaspar et al. (1990) for oceanic environments. The RTM is used to demonstrate how it is possible to investigate limnological trophic states by considering the problem of eutrophication as an example. A phenomenological investigation of processes leading to and sustaining eutrophication is carried out. A new indexing system that identifies different trophic states, the so-called Self-Consistent Trophic State Index (SCTSI), is proposed. This index does not rely on empirical measurements that are then compared to existing tables for classifying limnological environments into particular trophic states, for example, the concentrations of certain species at certain depths to indicate the trophic state, as is commonly done in the literature. Rather, the index is calculated using dynamic properties of only the limnological environment being considered and examines how those properties affect the sustainability of the ecosystem. Specifically, the index is calculated from a ratio of light attenuation by the ecosystem’s primary biomass to that of total light attenuation by all particulate species and molecular scattering throughout the entire water column. The index is used to probe various simulated scenarios that are believed to be relevant to eutrophication: nutrient loading, nutrient limitation, overabundance of phytoplankton, solar-induced turbulence, and wind-induced turbulence.
author Stojanovic, Severin
author_facet Stojanovic, Severin
author_sort Stojanovic, Severin
title Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
title_short Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
title_full Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
title_fullStr Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
title_full_unstemmed Numerical Reaction-transport Model of Lake Dynamics and Their Eutrophication Processes
title_sort numerical reaction-transport model of lake dynamics and their eutrophication processes
publishDate 2011
url http://hdl.handle.net/10393/20231
work_keys_str_mv AT stojanovicseverin numericalreactiontransportmodeloflakedynamicsandtheireutrophicationprocesses
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