Soil moisture increment as a controlling variable of the Birch effect . Interactions with the pre-wetting soil moisture and litter addition

Abstract

The Birch effect is a pulse in soil C and N mineralization caused by the wetting of dry soils, but the role of the soil moisture increment (Delta SWC) is still poorly understood. We quantified the relationship between Delta SWC and the Birch effect, and its interactions with pre-wetting soil moisture (preSWC) and substrate supply. Two soils (clay loam and sandy loam) under a Pinus halepensis forest were subjected to rewetting in laboratory treatments combining different Delta SWC and preSWC values, with or without additional substrate (5 mg g(-1) P. halepensis needles). Respiration flush (Delta R), changes in microbial biomass C (MBC) and net N mineralization (NMIN) were measured. Overall, we found a relationship with the form: Delta R = a Delta SWC + b, where the slope (a) was significant only when pre-wetting water potential was below a threshold value in the range of -100 to -1,200 kPa. However, the threshold alone does not fully describe the role of preSWC in slope variability. Substrate addition modified the Delta SWC sensitivity of Birch effect, enhancing it in the clay loam and suppressing it in the sandy loam. The intensity of the wetting is a dominant factor regulating Birch effect, and Delta SWC is useful for its quantification.This work was supported by a fellowship from Generalitat Valenciana, Conselleria de Educacion, Formacion y Empleo awarded to L. Lado-Monserrat (BFPI/2008/041). Thanks are due to Antonio del Campo for help in data analyses and to Antonio Lloret for laboratory work. The authors wish to thank Joana Oliver for invaluable laboratory support. The authors also thank two anonymous reviewers and Professor Stephan Glatzel from the University of Rostock, Germany, for the critical review of the manuscript.Lado Monserrat, L.; Lull Noguera, C.; Bautista Carrascosa, MI.; Lidón Cerezuela, AL.; Herrera Fernandez, R. (2014). Soil moisture increment as a controlling variable of the Birch effect . 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