How do storm characteristics influence concentration-discharge hysteresis in a high-elevation tropical ecosystem?

[1]  P. Crespo,et al.  Effect of weir´s theoretical discharge coefficient on discharge measurements in small Andean streams , 2022, La Granja.

[2]  A. Lintern,et al.  Synthesizing the impacts of baseflow contribution on concentration–discharge (C–Q) relationships across Australia using a Bayesian hierarchical model , 2022, Hydrology and Earth System Sciences.

[3]  J. Six,et al.  Fluvial sediment export from pristine forested headwater catchments in the Congo Basin , 2021, Geomorphology.

[4]  W. McDowell,et al.  High‐frequency multi‐solute calibration using an in situ UV–visible sensor , 2021 .

[5]  A. Alvarado,et al.  Resistance Analysis of Morphologies in Headwater Mountain Streams , 2021, Water.

[6]  Bingfang Wu,et al.  Dryland ecosystem dynamic change and its drivers in Mediterranean region , 2021 .

[7]  C. Tovar,et al.  A concerted research effort to advance the hydrological understanding of tropical páramos , 2020, Hydrological Processes.

[8]  J. Feyen,et al.  Water transport and tracer mixing in volcanic ash soils at a tropical hillslope: A wet layered sloping sponge , 2020, Hydrological Processes.

[9]  Yunmin Chen,et al.  Quantitative characterization of solute transport in fractures with different surface roughness based on ten Barton profiles , 2020, Environmental Science and Pollution Research.

[10]  J. Kirchner,et al.  Concentration–discharge relationships vary among hydrological events, reflecting differences in event characteristics , 2020, Hydrology and Earth System Sciences.

[11]  William H. McDowell,et al.  Hysteretic Response of Solutes and Turbidity at the Event Scale Across Forested Tropical Montane Watersheds , 2019, Front. Earth Sci..

[12]  S. Godsey,et al.  Dynamic stream network intermittence explains emergent dissolved organic carbon chemostasis in headwaters , 2019, Hydrological Processes.

[13]  J. McDonnell,et al.  The role of vegetation, soils, and precipitation on water storage and hydrological services in Andean Páramo catchments , 2019, Journal of Hydrology.

[14]  R. Célleri,et al.  Moisture transport and seasonal variations in the stable isotopic composition of rainfall in Central American and Andean Páramo during El Niño conditions (2015–2016) , 2019, Hydrological Processes.

[15]  J. Feyen,et al.  Spatially distributed hydro-chemical data with temporally high-resolution is needed to adequately assess the hydrological functioning of headwater catchments. , 2019, The Science of the total environment.

[16]  M. Rodríguez-Blanco,et al.  Using hysteresis analysis to infer controls on sediment-associated and dissolved metals transport in a small humid temperate catchment , 2018, Journal of Hydrology.

[17]  R. Célleri,et al.  Impact of Rain Gauges Distribution on the Runoff Simulation of a Small Mountain Catchment in Southern Ecuador , 2018, Water.

[18]  C. Soulsby,et al.  Spatio-temporal diel DOC cycles in a wet, low energy, northern catchment: Highlighting and questioning the sub-daily rhythms of catchment functioning , 2018, Journal of Hydrology.

[19]  L. Breuer,et al.  Effect of land cover and hydro‐meteorological controls on soil water DOC concentrations in a high‐elevation tropical environment , 2018, Hydrological Processes.

[20]  H. Fang,et al.  Effects of roughness and permeability on solute transfer at the sediment water interface. , 2018, Water research.

[21]  C. Hunsaker,et al.  Concentration‐discharge relationships in headwater streams of the Sierra Nevada, California , 2017 .

[22]  W. McDowell,et al.  Critical zone structure controls concentration‐discharge relationships and solute generation in forested tropical montane watersheds , 2017 .

[23]  J. Feyen,et al.  Temporal dynamics in dominant runoff sources and flow paths in the Andean Páramo , 2017 .

[24]  J. Hartmann,et al.  Catchment chemostasis revisited: Water quality responds differently to variations in weather and climate , 2017, Hydrological Processes.

[25]  Carmen Rosa Montes-Pulido,et al.  Carbono almacenado en páramo andino , 2017 .

[26]  C. Birkel,et al.  Nonlinear and threshold‐dominated runoff generation controls DOC export in a small peat catchment , 2017 .

[27]  R. Maxwell,et al.  Snowmelt controls on concentration‐discharge relationships and the balance of oxidative and acid‐base weathering fluxes in an alpine catchment, East River, Colorado , 2017 .

[28]  B. Abbott,et al.  Elemental properties, hydrology, and biology interact to shape concentration‐discharge curves for carbon, nutrients, sediment, and major ions , 2017 .

[29]  J. Feyen,et al.  Continuous versus event‐based sampling: how many samples are required for deriving general hydrological understanding on Ecuador's páramo region? , 2016 .

[30]  J. Hartmann,et al.  Differential weathering of basaltic and granitic catchments from concentration–discharge relationships , 2016 .

[31]  Marco Borga,et al.  A versatile index to characterize hysteresis between hydrological variables at the runoff event timescale , 2016 .

[32]  Jim E Freer,et al.  Technical Note: Testing an improved index for analysing storm discharge–concentration hysteresis , 2016 .

[33]  J. Freer,et al.  Using hysteresis analysis of high-resolution water quality monitoring data, including uncertainty, to infer controls on nutrient and sediment transfer in catchments. , 2016, The Science of the total environment.

[34]  M. Xenopoulos,et al.  Human activities cause distinct dissolved organic matter composition across freshwater ecosystems , 2016, Global change biology.

[35]  Luiz Eduardo Moschini,et al.  Influence of watershed land use and riparian characteristics on biological indicators of stream water quality in southeastern Brazil , 2016 .

[36]  P. Sullivan,et al.  Landscape heterogeneity drives contrasting concentration–discharge relationships in shale headwater catchments , 2015 .

[37]  J. McDonnell,et al.  Water's Way at Sleepers River watershed – revisiting flow generation in a post‐glacial landscape, Vermont USA , 2015 .

[38]  R. Célleri,et al.  Rainfall in the Andean Páramo: New Insights from High-Resolution Monitoring in Southern Ecuador , 2015 .

[39]  A. Heathwaite,et al.  Seasonal variation in phosphorus concentration–discharge hysteresis inferred from high-frequency in situ monitoring , 2015 .

[40]  H. Laudon,et al.  The river as a chemostat: fresh perspectives on dissolved organic matter flowing down the river continuum , 2015 .

[41]  A. Wade,et al.  Characterising phosphorus and nitrate inputs to a rural river using high-frequency concentration-flow relationships. , 2015, The Science of the total environment.

[42]  R. Célleri,et al.  Runoff from tropical alpine grasslands increases with areal extent of wetlands , 2015 .

[43]  R. Stallard,et al.  A Unified Assessment of Hydrologic and Biogeochemical Responses in Research Watersheds in Eastern Puerto Rico Using Runoff–Concentration Relations , 2014, Aquatic Geochemistry.

[44]  G. Hornberger,et al.  Concentration–discharge relationships in the coal mined region of the New River basin and Indian Fork sub‐basin, Tennessee, USA , 2014 .

[45]  J. McDonnell,et al.  The hydrology of the humid tropics , 2012 .

[46]  JM Quinn,et al.  Land use influences on suspended sediment yields and event sediment dynamics within two headwater catchments, Waikato, New Zealand , 2012 .

[47]  Kate Maher,et al.  The role of fluid residence time and topographic scales in determining chemical fluxes from landscapes , 2011 .

[48]  N. Basu,et al.  Hydrologic and biogeochemical functioning of intensively managed catchments: A synthesis of top‐down analyses , 2011 .

[49]  J. Feyen,et al.  Identifying controls of the rainfall–runoff response of small catchments in the tropical Andes (Ecuador) , 2011 .

[50]  David K. Stevens,et al.  Surrogate Measures for Providing High Frequency Estimates of Total Suspended Solids and Total Phosphorus Concentrations 1 , 2011 .

[51]  A. Rinaldo,et al.  Nutrient loads exported from managed catchments reveal emergent biogeochemical stationarity , 2010 .

[52]  Christopher Spence,et al.  A Paradigm Shift in Hydrology: Storage Thresholds Across Scales Influence Catchment Runoff Generation , 2010 .

[53]  R. Hatano,et al.  Hydrological process controls on nitrogen export during storm events in an agricultural watershed , 2010 .

[54]  M. Mast,et al.  Mechanisms for chemostatic behavior in catchments: Implications for CO2 consumption by mineral weathering , 2010 .

[55]  C. Neal,et al.  The value of high-resolution nutrient monitoring: A case study of the River Frome, Dorset, UK , 2009 .

[56]  W. McDowell,et al.  Salinization of urbanizing New Hampshire streams and groundwater: effects of road salt and hydrologic variability , 2009, Journal of the North American Benthological Society.

[57]  Hugh G. Smith,et al.  Interpreting sediment delivery processes using suspended sediment‐discharge hysteresis patterns from nested upland catchments, south‐eastern Australia , 2009 .

[58]  J. Kirchner,et al.  Concentration–discharge relationships reflect chemostatic characteristics of US catchments , 2009 .

[59]  A. Butturini,et al.  Diversity and temporal sequences of forms of DOC and NO3-discharge responses in an intermittent stream : Predictable or random succession? , 2008 .

[60]  Yolanda Madrid,et al.  Water sampling : Traditional methods and new approaches in water sampling strategy , 2007 .

[61]  G. Petts,et al.  Turbidity dynamics during spring storm events in an urban headwater river system: the Upper Tame, West Midlands, UK. , 2006, The Science of the total environment.

[62]  Y. Lucas,et al.  Transfer of nutrients and labile metals from the continent to the sea by a small Mediterranean river. , 2006, Chemosphere.

[63]  Dale W. Johnson,et al.  Suspended sediment dynamics associated with snowmelt runoff in a small mountain stream of Lake Tahoe (Nevada) , 2005 .

[64]  P. Johnes,et al.  Physico-chemical controls on phosphorus cycling in two lowland streams. Part 2--the sediment phase. , 2004, The Science of the total environment.

[65]  James W. Kirchner,et al.  The fine structure of water‐quality dynamics: the (high‐frequency) wave of the future , 2004 .

[66]  Y. Tardy,et al.  Geochemistry applied to the watershed survey: hydrograph separation, erosion and soil dynamics. A case study: the basin of the Niger River, Africa , 2004 .

[67]  William H. McDowell,et al.  Biogeochemical Hot Spots and Hot Moments at the Interface of Terrestrial and Aquatic Ecosystems , 2003, Ecosystems.

[68]  Jonathan D. Phillips,et al.  Sources of nonlinearity and complexity in geomorphic systems , 2003 .

[69]  P. Podwojewski,et al.  Runoff and soil erosion under rainfall simulation of Andisols from the Ecuadorian Páramo: effect of tillage and burning , 2001 .

[70]  G. Hornberger,et al.  Modelling transport of dissolved silica in a forested headwater catchment: the effect of hydrological and chemical time scales on hysteresis in the concentration–discharge relationship , 2001 .

[71]  Keith Richards,et al.  Turbidity and suspended sediment dynamics in small catchments in the Nepal Middle Hills , 2000 .

[72]  C. D. Ollier,et al.  Geomorphic and tectonic evolution of the Ecuadorian Andes , 2000 .

[73]  Bernard Bobée,et al.  Towards operational guidelines for over-threshold modeling , 1999 .

[74]  Pascale M. Biron,et al.  The effects of antecedent moisture conditions on the relationship of hydrology to hydrochemistry in a small forested watershed , 1999 .

[75]  P. Sklenář,et al.  Distribution patterns of páramo plants in Ecuador , 1999 .

[76]  Chris D. Evans,et al.  Causes of concentration/discharge hysteresis and its potential as a tool for analysis of episode hydrochemistry , 1998 .

[77]  P. Ramsay,et al.  The growth form composition of plant communities in the ecuadorian páramos , 1997, Plant Ecology.

[78]  J. Syvitski,et al.  Geomorphic/Tectonic Control of Sediment Discharge to the Ocean: The Importance of Small Mountainous Rivers , 1992, The Journal of Geology.

[79]  A. Robson,et al.  Towards predicting future episodic changes in stream chemistry , 1991 .

[80]  P. Wood,et al.  Controls of variation in suspended sediment concentration in the River Rother, West Sussex, England , 1977 .

[81]  H. J. Walker,et al.  Suspended Load in the Colville River, Alaska, 1962 , 1967 .

[82]  C. A. Barboza,et al.  Influence of land cover, catchment morphometry and rainfall on water quality and material transport of headwaters and low-order streams of a tropical mountainous watershed , 2022, CATENA.

[83]  R. D. Moore Introduction to Salt Dilution Gauging for Streamflow Measurement Part 2 : Constant-rate Injection , 2008 .

[84]  J. O'kane Hysteresis in hydrology , 2005 .

[85]  Michael Steinmann,et al.  Neogene stratigraphy and Andean geodynamics of southern Ecuador , 2002 .

[86]  W. McDowell,et al.  Export of carbon, nitrogen, and major ions from three tropical montane watersheds , 1994 .

[87]  G. Williams Sediment concentration versus water discharge during single hydrologic events in rivers , 1989 .

[88]  Yang Wu,et al.  Hydrological characteristics of the Changjiang and its relation to sediment transport to the sea , 1985 .