The effects of free-air CO2 enrichment and soil water availability on spatial and seasonal patterns of wheat root growth

Spring wheat [Triticum aestivum (L). cv. Yecora Rojo] was grown from Decemb er 1992 to May 1993 under two atmospheric CO2 concentrations, 550 mu mol mo l(-1) for high-CO2 plots, and 370 mu mol mol(-1) for control plots, using a Free-Air CO2 Enrichment (FACE) apparatus. In addition to the two levels of atmospheric CO2, there were ample and limiting levels of water supply thro ugh a subsurface trip irrigation system in a strip, split-plot design. In o rder to examine the temporal and spatial root distribution, root cores were extracted at six growth stages during the season at in-row and inter-row p ositions using a soil core device (86 mm ID, 1.0 m length). Such informatio n would help determine whether and to what extent root morphology is change d by alteration of two important factors, atmospheric CO2 and soil water, i n this agricultural ecosystem. Wheat root growth increased under elevated C O2 conditions during all observed developmental stages. A maximum of 37% in crease in total root dry mass in the FACE vs. Control plots was observed du ring the period of stem elongation. Greater root growth rates were calculat ed due to CO2 enhancement until anthesis. During the early vegetative growt h, root dry mass of the inter-row space was significantly higher for FACE t han for Control treatments suggesting that elevated CO2 promoted the produc tion of first-order lateral roots per main axis. Then, during the reproduct ive period of growth, more branching of lateral roots in the FACE treatment occurred due to water stress. Significant higher root dry mass was measure d in the inter-row space of the FACE plots where soil water supply was limi ting. These sequential responses in root growth and morphology to elevated CO2 and reduced soil water supports the hypothesis that plants grown in a h igh-CO2 environment may better compensate soil-water-stress conditions.