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## streamwater chemistry Water was filtered upon collection (maximum pore size 0.7 μm, glass fiber filters), transported to the laboratory on ice, and frozen until analysis. Samples were analyzed for dissolved organic carbon and total dissolved nitrogen via non-dispersive infrared gas analysis and chemiluminescence, respectively, on a Shimadzu TOC/TN-L. Concentrations of major anions and cations were analyzed via ion chromatography on a Thermo ion chromatograph with AS-18 or HC-11 columns for anions and CS-16 columns for cations. Soluble reactive phosphorus was measured colorimetrically using the molybdate method on a Smartchem autoanalyzer. Ammonium was typically measured colorimetrically using the phenol hypochlorite method on a Smartchem autoanalyzer, and was additionally measured by ion chromatography. Measured concentrations less than the lowest value used in calibration were replaced with half of the limit of quantitation for each analyte (shown below). | Analyte | Limit of quantitation (uM) | |-----------------------------|----------------------------| | ammonium | 0.132 | | bromide | 0.134 | | calcium | 0.46 | | dissolved organic carbon | 8.8 | | chloride | 0.952 | | fluoride | 0.198 | | magnesium | 0.1 | | nitrate | 0.118 | | total dissolved nitrogen | 1.938 | | soluble reactive phosphorus | 0.05 | | potassium | 0.2 | | sodium | 0.204 | | sulfate | 0.314 | Water chemistry was additionally monitored during experimental nitrate fertilization in six streams. Six streams were fertilized by continuous addition of fertilizer for 12-14 d during the dry period preceding summer and winter rains (Table 1). The target nitrate concentration was 0.3 mg N/L. Dates of fertilizer addition are detailed below. | Site | Date | Fertilization | |------------|------------|---------------| | Agua Fria | 04/13/2016 | start | | Agua Fria | 04/27/2016 | end | | Agua Fria | 10/19/2016 | start | | Agua Fria | 10/31/2016 | end | | Sycamore | 04/19/2017 | start | | Sycamore | 05/03/2017 | end | | Bonita | 10/19/2018 | start | | Bonita | 11/02/2018 | end | | Eagle | 10/21/2018 | start | | Eagle | 11/04/2018 | end | | Eagle | 04/27/2019 | start | | Eagle | 05/11/2019 | end | | Bonita | 04/26/2019 | start | | Bonita | 05/18/2019 | end | | San Pedro | 04/20/2018 | start | | San Pedro | 05/04/2018 | end | | Santa Cruz | 04/19/2018 | start | | Santa Cruz | 05/03/2018 | end | | San Pedro | 10/08/2017 | start | | San Pedro | 10/22/2017 | end | | Santa Cruz | 10/07/2017 | start | | Santa Cruz | 10/21/2017 | end | ## whole-stream metabolism Whole-stream metabolism was modeled from dissolved oxygen concentration, light incident to the stream, and water temperature, all monitored at 15-min intervals. Oxygen and temperature were monitored at 1-2 stations per reach for 2-14 days, four times per year. Estimates of gross primary production, ecosystem respiration, and gas evasion were modeled using the streamMetabolizer package available for R (Appling et al. 2018). The package’s default priors were applied. Rate of gas evasion was estimated by partially pooling daily estimates within binned ranges in stream discharge, measured at the nearest USGS gauging station. The dataset includes metabolism monitored during experimental nitrate fertilization in six streams. Six streams were fertilized by continuous addition of fertilizer for 12-14 d during the dry period preceding summer and winter rains (Table 1). The target nitrate concentration was 0.3 mg N/L. Monitoring of metabolism during fertilization experiments typically included two stations within an upstream, control (unfertilized) reach; one station immediately above the fertilizer addition; and one station ~50-100 m downstream of fertilizer addition. | Site | Date | Fertilization | |------------|------------|---------------| | Agua Fria | 04/13/2016 | start | | Agua Fria | 04/27/2016 | end | | Agua Fria | 10/19/2016 | start | | Agua Fria | 10/31/2016 | end | | Sycamore | 04/19/2017 | start | | Sycamore | 05/03/2017 | end | | Bonita | 10/19/2018 | start | | Bonita | 11/02/2018 | end | | Eagle | 10/21/2018 | start | | Eagle | 11/04/2018 | end | | Eagle | 04/27/2019 | start | | Eagle | 05/11/2019 | end | | Bonita | 04/26/2019 | start | | Bonita | 05/18/2019 | end | | San Pedro | 04/20/2018 | start | | San Pedro | 05/04/2018 | end | | Santa Cruz | 04/19/2018 | start | | Santa Cruz | 05/03/2018 | end | | San Pedro | 10/08/2017 | start | | San Pedro | 10/22/2017 | end | | Santa Cruz | 10/07/2017 | start | | Santa Cruz | 10/21/2017 | end | Appling, A. P.; Hall, R. O.; Yackulic, C. B.; Arroita, M. Overcoming Equifinality: Leveraging Long Time Series for Stream Metabolism Estimation. J. Geophys. Res. Biogeosci. 2018, 123 (2), 624–645. https://doi.org/10.1002/2017JG004140. ## benthic organic matter Benthic organic matter was sampled within a standardized surface area using an open-ended cylinder pressed into the streambed. Five replicate samples of each of coarse (greater than 1 mm; CBOM) and fine (less than 1 mm; FBOM) benthic organic matter were collected from each stream during the dry period (May-June) preceding the summer monsoon season. Larger CBOM was manually removed from the streambed and suspended CBOM was retrieved using an aquarium net. FBOM was sampled by stirring the sediment followed by immediate collection of two 125-mL bottles of the suspension. Samples were transported on ice to the laboratory and refrigerated until processing. CBOM was dried at 105 degrees C for three days, then weighed, and expressed as mass per area streambed. Volume of FBOM samples was measured prior to filtering through pre-combusted and weighed GF/F filters (0.7 um, glass fiber). FBOM was then dried for three days at 105 degrees C, weighed (dry mass), ashed for 4 h at 450 degrees C, then dried for 3 days at 105 degrees C and reported as ash-free dry mass. A separate subsample of FBOM was processed for carbon and nitrogen content and stable isotopes. These subsamples were dried at 60 degrees degrees degrees degrees degrees degrees degrees degrees degrees C before elemental analysis coupled to an isotope-ratio mass spectrometer. ## nutrient-diffusing substrata Nutrient diffusing substrata were prepared and deployed following Tank et al. 2006. Agar was prepared using N_H4Cl and KNO₃ (equal concentration N from each form) and KH₂PO₄ at 0.5 M. Controls included unamended agar. Agar was poured into plastic cups and capped with a fritted glass disc (surface area = 5 cm²). Four replicate cups of each nutrient treatment were affixed to steel bars and anchored to the bed of each of eleven streams. Cups were incubated for three weeks, in Jun-Jul 2017 and Nov-Dec 2018. Upon retrieval, fritted glass disks were removed from the cups and transported to the laboratory on dry ice, where they were frozen at -80 degrees C. Chlorophyll a was extracted from biomass on each fritted glass disk in hot ethanol. Samples were held in the dark until analysis. Each disk was placed in 95% ethanol and heated to 79 degrees C in a water bath for 5 minutes, followed by cooling in a refrigerator for 24 h. Absorbance of the extractant was then measured at 665 and 750 nm on a spectrophotometer. Hydrochloric acid (0.1 M) was added and samples were incubated for 90 s before reading absorbance a second time. Chlorophyll a and phaeophytin were then calculated as follows: Chlorophyll a (mg m^–2) = 28.78\*(665₀ - 665_a)\*v/(A\*l) Phaeophytin (mg m^–2) = 28.78\*[1.72\*(665_a) - 665₀]\*v/(A\*l) where 665₀ = absorbance at 665 before acid addition minus absorbance at 750 nm, 665_a = absorbance at 665 nm after acid addition minus absorbance at 750 nm, v = volume of extractant used (L), A = area of benthos sampled (m²) and l = path length of cell (1 cm). ## literature cited - Appling, A. P.; Hall, R. O.; Yackulic, C. B.; Arroita, M. Overcoming Equifinality: Leveraging Long Time Series for Stream Metabolism Estimation. J. Geophys. Res. Biogeosci. 2018, 123 (2), 624–645. https://doi.org/10.1002/2017JG004140. - APHA (American Public Health Association). 2005. Standard methods for examination of water and wastewater, 19th ed. American Public Health Association, Washington, DC. - Parker, S.P., W.B. Bowden, and M.B. Flinn. 2016. The effect of acid strength and postacidification reaction time on the determination of chlorophyll a in ethanol extracts of aquatic periphyton. Limnology and Oceanography: Methods 14:839-852. - Sartory, D.P., and J. U. Grobbelaar. 1984. Extraction of chlorophyll a from freshwater phytoplankton for spectrophotometric analysis. Hydrobiologia 114:177-187. - Tank, J.L., M.J. Bernot, E.J. Rosi-Marshall. 2006. Nitrogen limitation and uptake. In: Methods in Stream Ecology, 2nd edition, p. 213-238, F. Hauer & G. Lamberti, editors.