AUTHOR=Bingham Nina L. , Slessarev Eric W. , Homyak Peter M. , Chadwick Oliver A. 

TITLE=Rock-Sourced Nitrogen in Semi-Arid, Shale-Derived California Soils

JOURNAL=Frontiers in Forests and Global Change

VOLUME=4

YEAR=2021

URL=https://www.frontiersin.org/journals/forests-and-global-change/articles/10.3389/ffgc.2021.672522

DOI=10.3389/ffgc.2021.672522

ISSN=2624-893X

ABSTRACT=<p>Models suggest that rock-derived nitrogen (N) inputs are of global importance to ecosystem N budgets; however, field studies demonstrating the significance of rock N inputs are rare. We examined rock-derived N fluxes in soils derived from sedimentary rocks along a catena formed under a semi-arid climate. Our measurements demonstrate that there are distinct and traceable pools of N in the soil and bedrock and that the fraction of rock-derived N declines downslope along the catena. We used geochemical mass balance weathering flux measurements to estimate a rock-derived N flux of 0.145 to 0.896 kg ha<sup>–1</sup> yr<sup>–1</sup> at the ridgecrest. We also developed independent N flux estimates using a <sup>15</sup>N-based isotope mixing model. While geochemical mass-balance-based estimates fell within the 95% confidence range derived from the isotope mixing model (−1.1 to 44.3 kg ha<sup>–1</sup> yr<sup>–1</sup>), this range was large due to uncertainty in values for atmospheric <sup>15</sup>N deposition. Along the catena, N isotopes suggest a diminishing effect of rock-derived N downslope. Overall, we found that despite relatively large N pools within the saprolite and bedrock, slow chemical weathering and landscape denudation limit the influence of rock-derived N, letting atmospheric N deposition (7.1 kg ha<sup>–1</sup> yr<sup>–1</sup>) and N fixation (0.9–3.1 kg ha<sup>–1</sup> yr<sup>–1</sup>) dominate N inputs to this grassland ecosystem.</p>