Laboratory analysis of the effects of elevated atmospheric carbon dioxide on respiration in biological soil crusts

Richard W. Lane, Manoj Menon, James B. Mcquaid, David G. Adams, Andrew D. Thomas, Steve R. Hoon, Andrew J. Dougill

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16 Citations (SciVal)


Metabolic activity of Biological Soil Crusts (BSCs) is principally dependent on moisture availability, but also on temperature and light conditions. Less understood is how BSCs respond to elevated atmospheric CO2. This paper reports laboratory experimental results of elevated atmospheric CO2 on carbon fluxes for cyanobacterial BSCs. The study uses newly designed dynamic gas exchange chambers in which the internal atmosphere was controlled. CO2 flux was monitored during controlled experiments in two phases under simulated rainfall events (2 & 5 mm plus control with no wetting) each lasting 3 days with a dry period in between. Phase 1 subjected crusts to 392 ppm CO2 (representing ambient level) in dry air; in phase 2, the CO2 concentration was 801 ppm. Both phases exhibited significant efflux (respiration) of CO2 immediately after wetting, followed by substantial influx (sequestration) of CO2. Samples subject to 2 mm wetting sequestered an order of magnitude more C under elevated CO2 than at ambient CO2; for samples subject to 5 mm wetting, this increase was threefold. The findings highlight the role of BSCs in future carbon budgets by enabling greater sequestration into dryland soils even under enhanced atmospheric CO2 concentrations, following both light and heavy rainfall events
Original languageEnglish
Pages (from-to)52-59
Number of pages8
JournalJournal of Arid Environments
Early online date23 Aug 2013
Publication statusPublished - 01 Nov 2013


  • autotrophic
  • biological soil crust
  • CO2 flux double CO2
  • cyanobacteria
  • drylands
  • heterotrophic
  • Kalahari
  • photosynthesis
  • respiration
  • soil carbon sequestration


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