Quantifying Lake Water Quality Evolution: Coupled Geochemistry, Hydrodynamics, and Aquatic Ecology in an Acidic Pit Lake

Environmental Science and Technology

Volumn 51, Issue 17, 2017, Pages 9864-9875

  Salmon, S Ursula ^a   Hipsey, Matthew R ^a   Wake, Geoffrey W ^a   Ivey, Gregory N ^a   Oldham, Carolyn E ^a  

^a UNIVERSITY OF WESTERN AUSTRALIA   (Australia)

Author keywords

[No Author keywords available]

Indexed keywords

ALKALINITY; ALUMINUM; BIOLOGY; ECOLOGY; GEOCHEMISTRY; HYDROCHEMISTRY; LAKES; QUALITY CONTROL; RESERVOIR MANAGEMENT; WATER QUALITY;

ASSESSMENT OF WATER QUALITIES; BIOLOGICAL INTERACTIONS; BUFFERING CAPACITIES; LAKE WATER QUALITY; MANAGEMENT CHALLENGES; ORDERS OF MAGNITUDE; PHYTOPLANKTON GROWTH; SOLUBILITY EQUILIBRIA;

RESERVOIRS (WATER);

IRON; LAKE WATER; FERRIC ION;

ALUMINUM; CHEMICAL PROPERTY; GEOCHEMISTRY; HYDRODYNAMICS; IRON; LAKE WATER; NITRIFICATION; OPEN PIT MINE; OXIDATION; PHYTOPLANKTON; QUALITATIVE ANALYSIS; QUANTITATIVE ANALYSIS; WATER QUALITY;

ABIOTIC STRESS; ACIDITY; AQUATIC ENVIRONMENT; ARTICLE; BIOGEOCHEMISTRY; EVOLUTION; FEEDBACK SYSTEM; HYDRODYNAMICS; OXIDATION; PH; QUANTITATIVE ANALYSIS; RIVER; SALINITY; SEDIMENT; SIMULATION; SOLUBILITY; WATER QUALITY; BIOLOGY; ECOLOGY; LAKE;

ECOLOGY; FERRIC COMPOUNDS; HYDROBIOLOGY; HYDRODYNAMICS; LAKES; WATER QUALITY;

EID: 85028962975     PISSN: 0013936X     EISSN: 15205851     Source Type: Journal    
DOI: 10.1021/acs.est.7b01432     Document Type: Article

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