Agricultural intensification and urban expansion affect the seasonal flow regime in southern Ontario watersheds

The mosaic of urban, agricultural and natural covers that typifies most developed landscapes makes it challenging to identify the primary causes of stream flow perturbation in mixed landcover watersheds. This is especially true in southern Ontario, Canada, where approximately 1/3 of the Canadian population lives in urban areas surrounded by agriculture. Whilst previous studies have examined the impacts of urban or agricultural landcover on stream flow separately, they are rarely considered together. Furthermore, major expansions in tile‐drained (TD) cropland in Ontario over the past several decades could affect the flow regime; however, this has never been examined. This study assessed the effect of landcover on flow regime at 19 proximal watersheds that varied in agriculture (0%–87%), natural (2%–97%) and urban landcover (2%–96%) using the Richards–Baker index (RBI), the coefficient of variation (CV) and a Baseflow index (BFI). Urbanized watersheds were consistently the most flashy (highest RBI and CV), regardless of season, whereas agricultural watersheds had moderately flashy conditions that varied between the growing (GS) and non‐growing seasons (NGS). Natural watersheds were the least flashy and had the highest BFI. Watersheds dominated by TD cropland were flashier during the NGS compared with un‐tiled agricultural watersheds. Furthermore, TD‐streams were warmer in the NGS and cooler in the GS, such that the former could affect ice breakup. A 50‐year analysis at three watersheds showed statistically significant increases in flashiness and decreases in BFI at an urbanizing watershed. In contrast, watersheds that remained agricultural or natural underwent small but significant declines in flashiness and increases in baseflow, potentially due to increases in precipitation and forest maturation. Our results suggest that continued expansions of urban and TD cropland may increase NGS flashiness. In contrast, enhanced soil moisture storage provided by TD could decrease the potential for flooding in the GS in southern Ontario. Southern Ontario watersheds have faced changing landcovers due to urban expansion and agricultural intensification, which affect hydrologic regimes. This research quantified flashiness in streams across a wide range of land covers through both a short‐term and long‐term analysis. Watersheds with more urban cover or tile drainage showed higher flashiness values in the short‐term analysis, and urban expansion increased stream flashiness o