CONICET | Buscador de Institutos y Recursos Humanos

Arid ecosystems receive precipitation pulses of different sizes that may differentially affect nitrogen(N) losses and N turnover during the growing season. We designed a rainfall manipulationexperiment in the Patagonian steppe, southern Argentina, where we simulated different precipi-tation patterns by adding the same amount of water in evenly spaced three-small rainfall events orin one-single large rainfall event, three times during a growing season. We measured the effect ofthe size of rainfall pulses on N mineralization and N losses by denitriﬁcation, ammonia volatilization, and nitrate and ammonia leaching. Irrigation pulses stimulated N mineralization (P < 0.05), with small and frequent pulses showing higher responses than large pulses (P < 0.10). Irrigation effects were transient and did not result in changes in seasonal net N mineralization suggesting a longterm substrate limitation. Water pulses stimulated gaseous N losses by denitriﬁcation, with large pulses showing higher responses than small pulses (P < 0.05), but did not stimulate ammonia volatilization. Nitrate leaching also was higher after large than after small precipitation events (P < 0.05). Small events produced higher N transformations and lower N losses by denitriﬁcation and nitrate leaching than large events, which would produce higher N availability for plant growth. Climate change is expected to increase the frequency of extreme precipitation events and the proportion of large to small rainfall events. Our results suggest that these changes would result in reduced N availability and a competitive advantage for deep-rooted species that prefer nitrate over ammonia. Similarly, the ammonium:nitrate ratio might decrease because large events foster nitrate losses but not ammonium losses.