Increases in atmospheric CO₂ can augment the quantity and change the quality of plant carbon (C) inputs into grassland soils.  Soil moisture interacts with substrate characteristics and soil properties to affect decomposition and transfer of plant-derived C into soil organic matter (SOM).  Thus, predicted changes in precipitation regime coupled with changes in plant C inputs due to increasing atmospheric CO₂ could impact long-term C storage in grassland soils.  To examine the interactions between litter quality, soil properties, and soil moisture availability on grassland litter decomposition, we incubated 4 levels of litter additions (no litter, or litter from Bouteloua curtipendula grown under 280, 380, or 550 μL L^-1 CO₂) on 3 contrasting Blackland Prairie soils (Austin, Bastrop, Houston soil series) in a full factorial experiment using 5 levels of dry-rewet frequency (0x, 1x, 2x, 4x, or 8x over 112 days) and 4 levels of soil moisture (10%, 25%, 35%, 50% of water holding capacity).  Cumulative CO₂ production (μg C g^-1 dry soil) over the 112 day incubation period was measured and compared with initial litter C-to-N ratios (C:N).

Results/Conclusions Carbon mineralization from soil+litter (total C_min) was significantly affected by the four-way interaction between litter, soil type, dry-rewet frequency, and soil moisture treatments (P < 0.0001).  Cumulative CO₂ production was affected most strongly by soil type, then by soil moisture level, litter type, and dry-rewet frequency, respectively.  Total C_min was lowest in the sandy Bastrop soils and increased for Austin and Houston black clays.  Total C_min also increased significantly with increases in soil moisture level and dry-rewet frequency.  Mineralization of litter C only (i.e. cumulative CO₂ from soil+litter – cumulative CO₂ from soil only) tended to decrease in all soils for litter grown at 380 or 550 μL L^-1 CO₂ compared to 280 μL L^-1 CO₂, particularly in the wettest soils (50% WHC).  Initial C:N ratios in litter were significantly different between all CO₂ treatments, increasing with growth CO₂ concentration (63, 74, 81, respectively).  Decreasing N availability from litter with higher C:N may have limited microbial mineralization of litter C.  Thus, greater litter inputs from enhanced plant productivity under increasing atmospheric CO₂ and a longer retention time of plant-derived C due to reduced decomposition might contribute to C sequestration in grassland soils.  Potential changes in grassland soil C storage, however, will be controlled by the timing and amount of precipitation, which are predicted to change over the 21^st century.