Irrigated mountain meadow fertilizer application timing effects on overland flow water quality

Nonpoint-source pollution from agricultural activities is currently the leading cause of degradation of waterways in the United States. Applying best management practices to flood-irrigated mountain meadows may improve agricultural runoff and return flow water quality. Prior research has focused on fertilizer use for increased hay yields, while few studies have investigated the environmental implications of this practice. We examined the effects of fertilizer application timing on overland flow water quality from an irrigated mountain meadow near Gunnison, Colorado. Application of 40 kg phosphorus (P) and 19 kg nitrogen (N) ha(-1) using monoammonium phosphate (11-52-0, N-P-K) fertilizer to plots in the fall significantly reduced concentrations of reactive P and ammonium N in irrigation overland flow compared with early or late spring fertilization. Reactive P loading was 9 to almost 16 times greater when fertilizer was applied in the early or late spring, respectively, compared with in the fall. Ammonium N followed a similar trend with early spring loading more than 18 times greater and late spring loading more than 34 times greater than loads from fall-fertilized plots. Losses of 45% of the applied P and more than 17% of the N were measured in runoff when fertilizer was applied in the late spring. These results, coupled with those from previous studies, suggest that mountain meadow hay producers should apply fertilizer in the fall, especially P-based fertilizers, to improve hay yields, avoid economic losses from loss of applied fertilizers, and reduce the potential for impacts to water quality.     

Effect of water table on willows grown in amended mine tailing

Survival and growth characteristics of two montane riparian willow species, Geyer willow (Salix geyeriana Andersson) and mountain willow (Salix monticola Bebb), grown in amended fluvial mine tailing were investigated in a greenhouse study. Willow stem cuttings were planted in lysimeters that simulated a 60-cm amended tailing profile with three static water depths (20, 40, and 60 cm) and a fluctuating water table for a total of four water table treatments. Species and water table treatments affected plant biomass and chemical composition of the soil and plant tissue. Mountain willow leaf, stem, and root biomass were 62, 95, and 164% greater, respectively, than for Geyer willow. Averaging across species, the fluctuating water table negatively affected leaf and stem biomass compared with the 20- and 60-cm water table treatments. Manganese was the only metal in plant tissue to strongly respond to water table treatments. Manganese concentrations in mountain willow leaf tissue were approximately twofold higher in the two most saturated water table treatments (20 cm and fluctuating) than in the least saturated water table treatment (60 cm). This trend was consistent with chemical analyses of the growth media, which reflected higher bioavailable Mn in the saturated tailing profile compared with the unsaturated profile. Results from this study indicate that mountain willow is a more vigorous and possibly more metal-tolerant species than Geyer willow when grown in amended mine tailing and that a fluctuating water table negatively affects willow growth.