Publications [#348036] of Emily S. Bernhardt
search .Papers Published
- Brooks, A; Ross, MRV; Nippgen, F; McGlynn, B; Bernhardt, E, Excess Nitrate Export in Mountaintop Removal Coal Mining Watersheds,
Journal of Geophysical Research: Biogeosciences, vol. 124 no. 12
(December, 2019),
pp. 3867-3880 [doi] .
(last updated on 2023/01/01)Abstract:
Throughout the Central Appalachian ecoregion, mountaintop removal coal mining (MTM) is the predominant form of land use change. The streams draining MTM impacted watersheds have been reported to contain high stream nitrate (NO3−) concentrations, yet the source and persistence of elevated NO3− remains unknown. Here we compiled data from multiple sources to conduct a regional evaluation of the impact of mining on stream NO3−, examine NO3− persistence after mining cessation, and identify potential N sources. Using water quality data from six large watersheds, we observe elevated NO3− in watersheds with the highest active mining density. At four small MTM watersheds with repeat sampling, we found that high levels of NO3− concentrations declined after mining cessation but remain elevated above reference after several decades. At MTM watersheds, we found annual mass flux of NO3− was 3.68 to 26.4 kg N ha−1 year−1, which is 1 to 2 orders of magnitude higher than a nearby forested reference watershed. Stream water NO3− isotopic ratios at these sites did not match previously suggested NO3− sources such as explosives used during mining and fertilizer applied during reclamation but were highly enriched in both δ15N and δ18O compared to the reference watershed suggesting high rates of NO3− retention. Explosive residue could account for the bulk of watershed NO3− export during active mining phases but other mining related N sources including fertilizer and rock-derived N, the construction of valley fills, and alterations in watershed NO3- cycling likely contribute to the persistence of elevated NO3− export observed in this study.