Continuously Monitoring the Micrometeorology of a Natural Cave System: Hollow Ridge Speleoclimatology
Abstract
A study of cave microclimatology has been underway since October 2007 in a protected karst cave system near Marianna Florida. We are monitoring cave air, drip water and climatology at Hollow Ridge Cave to help calibrate isotopic and chemical paleoproxies incorporated into actively growing speleothems in Northwest Florida. Multiple monitoring stations positioned in the interior and above the overburden of this 1000 m long cave continuously record temperature (T), relative humidity (RH), barometric pressure (BP), drip rates (precipitation), acoustic airflow (wind) direction and velocity, 222Rn activities and CO2 concentrations. Air samples for 13CO2 analyses are collected periodically along the cave axis. Positively correlated 13CO2 vs. 1/ CO2 indicate soil gas (δ13C= -22 ‰) is the dominant CO2 source. Rn-222 is likely sourced from decay of 226Ra (U-series) in the limestone bedrock. In general, this cave inhales and exhales diurnally. All cave parameters reflect the intensity and longitudinal gradients of each breath modulated by frontal passages and seasonal changes. The diurnal amplitudes of T, RH, 222Rn and CO2 are highest nearest the entrance and almost disappear at the back of the cave, which mostly senses small amplitude frontal and seasonal changes. Radon-222 (20-340 dpm/L) and CO2 (400-1500 ppm) rise and fall coherently. Both gases are higher in the poorly ventilated portions of the cave, but each shows temporal and spatial patterns that reflect different sources - emanation from the enclosing limestone vs. soil gas and dripwater infusion from above. A flooding event due to a rise of the adjacent Chipola River inadvertently sealed the cave entrances, allowing 222Rn to grow in nearly to secular equilibrium (steady-state) in the air trapped inside the cave. Rn-222 peaked at 1200 dpm/L, over three-fold higher than previously measured, while CO2 peaked at 1400 ppm, similar to the highest CO2 values observed during normal conditions. As airflow was fully restricted, decay of 222Rn is balanced only by 222Rn emanation into the cave. Assuming 222Rn emanation into the cave is constant and represented by the secular equilibrium value, we use a simple radon- deficiency model to estimate air exchange rates (fractional tidal air volumes) and CO2 exhalation rates to compare wet (rainy) and dry periods. Daily air exchange rates vary from 18 to 26% of the cave volume. Radon/ CO2 ratios are four-times higher during wet periods than during dry periods, indicating stronger CO2 sources during dry periods. This suggests the cave ventilation system may be entraining soil gas CO2 from overhead fissures when the overlying soil cap is not waterlogged. This is counter to presumptions that wet periods with faster drips and more CO2 degassing from dripwater might increase cave air CO2 levels.
- Publication:
-
AGU Spring Meeting Abstracts
- Pub Date:
- May 2008
- Bibcode:
- 2008AGUSMPP21A..07K
- Keywords:
-
- 0330 Geochemical cycles (1030);
- 3344 Paleoclimatology (0473;
- 4900);
- 3394 Instruments and techniques;
- 4914 Continental climate records;
- 4958 Speleothems