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Estimation of river discharge, propagation speed, and hydraulic geometry from space: Lena River, Siberia

2008; Wiley; Volume: 44; Issue: 3 Linguagem: Inglês

10.1029/2007wr006133

1944-7973

L. C. Smith, Tamlin M. Pavelsky,

Cryospheric studies and observations

Moderate Resolution Imaging Spectroradiometer (MODIS)–derived measurements of Lena River effective width (W e ) display a high predictive capacity (r 2 = 0.81, mean absolute error < 25%) to forecast downstream discharge conditions at Kusur station, some 8 d and ∼700 km later. Satellite‐derived mean flow propagation speed (88 km d −1 or 1.01 m s −1 ) compares well with that estimated from ground data (84 km d −1 or 0.97 m s −1 ). Scaling analysis of a ∼300 km heavily braided study reach suggests that at length scales > 60–90 km (∼2–3 time valley width), satellite‐derived W e − Q rating curves and hydraulic geometry ( b exponents) converge upon stable values ( b = 0.48), indicating transferability of the discharge retrieval method between different locations. Put another way, at length scales exceeding ∼60–90 km all subreaches display similar behavior everywhere. At finer reach length scales (e.g., 0.25–1 km), longitudinal extraction of b exponents represents the first continuous mapping of a classical hydraulic geometry parameter from space. While at least one gauging station is required for calibration, results suggest that multitemporal satellite data can powerfully enhance our understanding of water discharge and flow conveyance in remote river systems.