In this study, we assessed the carbon (C) distribution within soil aggregates, macroaggregates (Macro), microaggregates (micro), and silt and clay (s + c) through three soil depths (0– 0.15, 0.15–0.30, and 0.30– 0.60 m) and af ter 9 years of land conversion from two annual crops continuous wheat and maize/wheat rotation to Miscanthus and giant reed, respectively. The 13 C natural abundance analysis wa s combined with physical fractionation to trace the fate of the new C that wa s derived from Miscanthus and giant reed in aggregate fractions. Macro always represented the highest proportion of the soil and the highest amount of C. In Miscanthus, the amount of C decreased from the 0–0.15 to the 0.30–0.60 m soil layer, whereas the C storage capacity of micro and s + c increased with depth. In giant reed, the distribution of the soil fractions and the associated C were more uniform in all of the layers. The new C derived from the perennial species wa s mainly concentrated in the upper layer in the Macro under Miscanthus , whereas it wa s more evenly distributed in the three layers and the fractions under giant reed. Irrespective of the fractions, in the Miscanthus plantation, the great C accumulation wa s derived from both the new C directly entering the soil and the old C that wa s preserved from mineralization. Conversely, in the giant reed plantation, C accumulation wa s only derived from the new C component. These patterns reflect the different structure of the root apparatus of the two perennial species, which were mainly concentrated in the upper layer of Miscanthus and were more evenly distributed in soil profile of the giant reed. It is likely that this is responsible for the different mechanisms of C storage and turnover.
Carbon sequestration and distribution in soil aggregate fractions under Miscanthus and giant reed in the Mediterranean area
GIOACCHINI, PAOLA;CATTANEO, FRANCESCA;BARBANTI, LORENZO;MONTECCHIO, DANIELA;CIAVATTA, CLAUDIO;MARZADORI, CLAUDIO
2016
Abstract
In this study, we assessed the carbon (C) distribution within soil aggregates, macroaggregates (Macro), microaggregates (micro), and silt and clay (s + c) through three soil depths (0– 0.15, 0.15–0.30, and 0.30– 0.60 m) and af ter 9 years of land conversion from two annual crops continuous wheat and maize/wheat rotation to Miscanthus and giant reed, respectively. The 13 C natural abundance analysis wa s combined with physical fractionation to trace the fate of the new C that wa s derived from Miscanthus and giant reed in aggregate fractions. Macro always represented the highest proportion of the soil and the highest amount of C. In Miscanthus, the amount of C decreased from the 0–0.15 to the 0.30–0.60 m soil layer, whereas the C storage capacity of micro and s + c increased with depth. In giant reed, the distribution of the soil fractions and the associated C were more uniform in all of the layers. The new C derived from the perennial species wa s mainly concentrated in the upper layer in the Macro under Miscanthus , whereas it wa s more evenly distributed in the three layers and the fractions under giant reed. Irrespective of the fractions, in the Miscanthus plantation, the great C accumulation wa s derived from both the new C directly entering the soil and the old C that wa s preserved from mineralization. Conversely, in the giant reed plantation, C accumulation wa s only derived from the new C component. These patterns reflect the different structure of the root apparatus of the two perennial species, which were mainly concentrated in the upper layer of Miscanthus and were more evenly distributed in soil profile of the giant reed. It is likely that this is responsible for the different mechanisms of C storage and turnover.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.