Kl. Thomas et al., DIURNAL OSCILLATIONS OF GAS-PRODUCTION AND EFFLUXES (CO2 AND CH4) IN CORES FROM A PEAT BOG, Biological rhythm research, 29(3), 1998, pp. 247-259
Feat cores (15 cm diam x 30 cm deep) from Ellergower Moss, New Gallowa
y, Scotland were kept and monitored at constant temperature(10 +/-0.1
degrees C) for gas production using a 1.6 mm diam stainless steel prob
e fitted with a membrane inlet and connected to a quadrupole mass spec
trometer. In the headspace, O-2, CO2 and CH4 (measured at m/z values 3
2, 44 and 15 respectively) showed diurnal fluctuations in low-intensit
y natural daylight and under a light-dark (LD, 12:12) regime. Over the
first few cycles O-2 and CO2 increased together in the dark and decre
ased in the light, whereas CH4 showed variations in antiphase with the
other two gases. CO2 and CH4 also showed diurnal oscillations at 15 c
m depth, but these decreased together in the light whereas argon (m/z
= 40) was not varying. A highly-damped free-run of the oscillations in
gas concentrations at 15cm depth was evident for only 3 cycles in com
plete darkness and at constant temperature. This might suggest desynch
ronization between individual plants with different free-running perio
ds. A hydrocarbon signal (m/z = 26) at 15 cm depth also showed diurnal
cycles but out of phase with CO2 and CH4. We postulate a circadian co
ntrol of microbiological activities imposed by the vascular plants (Ca
rex, Eriophorum, Molinia, Calluna, Erica). Under natural conditions th
e pronounced temperature sensitivity of CO2 and CH4 emission results i
n entrainment to daily temperature cycles. The amplitudes of the rhyth
ms are greatest when temperature and light intensity changes are most
pronounced, i.e. when the fluctuations in environmental factors are mo
st potent as synchronizers (zeitgebers) and as masking factors.