Paper No. 2
Presentation Time: 8:20 AM
TRACING CARBON TRANSFER FROM SOILS TO A CAVE USING STABLE CARBON ISOTOPES
The carbon isotope composition and concentration of CO2 in Cave of the Bells, southern Arizona, and in the soil at several locations above the cave was measured in order to calibrate the carbon isotope composition of speleothem calcite as a record of vegetation at the surface. Gas samples were collected from soils in a seasonal streambed, a Pleistocene stream terrace and a Holocene stream terrace and from the atmosphere at several locations inside the cave. Gas samples were collected from soils on the eastern and western slope of the hill above the cave in a previous study. Samples were collected monthly during the course of one year. The δ13C values of CO2 in the cave atmosphere varied only slightly in space and time, averaging -19.2±0.3. The δ13C values of CO2 were more variable in the soils than in the cave: -17.8±1.3 in the streambed, -15.2±1.0 in the Pleistocene terrace, -16.1±0.7 in the Holocene terrace, -14.6±1.4 in the western slope and -15.2±1.6 in the eastern slope. The δ13C value of respired CO2 (δ13Cr) was calculated for all gas samples from the measured δ13C values and CO2 concentrations. The source of cave CO2 was identified by comparing cave and soil δ13Cr values. The δ13Cr values of CO2 in the streambed averaged -24.1±0.4, which is indistinguishable from the average δ13Cr value of CO2 in the cave (-24.0±0.3). The δ13Cr values of CO2 from the other soils were higher and more variable than those of the cave and streambed, averaging -20.1±1.0 in the Pleistocene terrace, -20.9±0.8 in the Holocene terrace, -21.4±2.5 in the western slope soil and -20.2±1.8 in the eastern slope soil. The difference between cave and terrace/slope δ13Cr values and the consistent similarity between cave and streambed δ13Cr values suggests that streambed soil rather than terrace/slope soil is the source of CO2 in the cave. The preferential transfer of CO2 to the cave from the streambed versus terrace or slope soils likely occurs because groundwater recharge, carrying dissolved inorganic carbon, is focused along the streambed. The bias of cave CO2 toward a C3 vegetation signal may be controlled by focused recharge, resulting from a higher proportion of C3 plants growing in the streambed than on terraces and slopes, and may be reflected by the carbon isotope composition of calcite in speleothems from the cave.