Quantifying hyporheic exchange at high spatial resolution using natural temperature variations along a first-order stream

Water Resources Research

Volumn 47, Issue 10, 2011, Pages

  Westhoff, M C ^a   Gooseff, M N ^b   Bogaard, T A ^a   Savenije, H H G ^a  

^a DELFT UNIVERSITY OF TECHNOLOGY   (Netherlands)

^b The Pennsylvania State University   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

DISTRIBUTED TEMPERATURE SENSING; ENERGY BALANCE MODELS; EXCHANGE FLOW RATE; EXCHANGE PARAMETERS; FIRST-ORDER STREAMS; HIGH RESOLUTION; HIGH SPATIAL RESOLUTION; HYPORHEIC EXCHANGE; HYPORHEIC ZONE; LUXEMBOURG; SMALL STREAMS; SPATIAL RESOLUTION; STREAM ECOSYSTEMS; STREAM SEGMENTS; STREAM TRACERS; TEMPERATURE CHANGES; TEMPERATURE VARIATION; TEMPORAL RESOLUTION; TRANSIENT STORAGE; TRANSPORT MODELING; WATER TEMPERATURES;

ECOSYSTEMS; IMAGE RESOLUTION; SOLUTE TRANSPORT; STREAM FLOW; TEMPERATURE; TEMPERATURE MEASUREMENT; TIME SERIES;

RIVERS;

DATA SET; ECOSYSTEM FUNCTION; ENERGY EFFICIENCY; EXPERIMENTAL STUDY; HYPORHEIC ZONE; MEASUREMENT METHOD; NUMERICAL MODEL; ONE-DIMENSIONAL MODELING; SOLUTE TRANSPORT; SPATIAL RESOLUTION; SPATIOTEMPORAL ANALYSIS; STREAM; TEMPERATURE INVERSION; WATER TEMPERATURE;

EID: 79952169846     PISSN: 00431397     EISSN: None     Source Type: Journal    
DOI: 10.1029/2010WR009767     Document Type: Article

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