Response of soil carbon dioxide efflux to temporal repackaging of rainfall into fewer, larger events in a semiarid grassland

• Published in: Frontiers in environmental science Vol. 10
• Main Authors: Roby, Matthew C., Scott, Russell L., Biederman, Joel A., Smith, William K., Moore, David J. P.
• Format: Journal Article
• Language: English
• Published: Frontiers Media S.A 21.09.2022
• Subjects: pulse; rainfall intensification; semiarid; soil efflux; soil moisture; soil respiration
• ISSN: 2296-665X; 2296-665X
• DOI: 10.3389/fenvs.2022.940943

Changing rainfall patterns will alter soil water availability to plants and microbes and likely impact soil CO 2 efflux (F s ) in semiarid ecosystems. However, our understanding of the response of F s to compound changes in rainfall event size and frequency remains relatively limited. To address this knowledge gap, we examined how compound changes in rainfall size and frequency impact F s in a semiarid grassland by deploying automated soil chambers at a rainfall manipulation experiment. All plots within the experiment received equal total summer growing season precipitation that was temporally repackaged into regular events of inversely varied size and frequency, with event sizes ranging from 5 to 50 mm and dry intervals ranging from 3.5 to 21 days. We found that repackaging rainfall into few/large events with long dry intervals decreased seasonal cumulative F s . Repackaging influenced key aspects of pulses including mean, maximum, and antecedent (day before irrigation) values of soil moisture and F s and their rate of decline during drying intervals. Soil moisture explained substantial variation in F s (R 2 > 0.84) for all treatments; however, the sensitivity of F s to soil moisture decreased in the few/large regime compared to the reference and many/small regimes. Dynamics in plant phenology (quantified by plot greenness) and soil temperature interacted with soil moisture to influence the seasonal evolution of F s pulses and cumulative efflux. Our findings demonstrate that soil moisture and vegetation responses to changes in rainfall size and frequency impact soil CO 2 efflux pulses and seasonal emissions in semiarid grasslands. These results, coupled with the knowledge that CO 2 efflux pulses play an outsized role in dryland carbon exchange, indicate the possibility of future climate-mediated shifts in the carbon cycling of semiarid ecosystems.