A. D. McGuire J.W. Harden F. S. Chapin III I. H. Myers-Smith 2007 <p><span>We measured CO</span>₂<span>&nbsp;and CH</span>₄<span>&nbsp;exchange from the center of a&nbsp;</span><i>Sphagnum</i><span>‐dominated permafrost collapse, through an aquatic moat, and into a recently burned black spruce forest on the Tanana River floodplain in interior Alaska. In the anomalously dry growing season of 2004, both the collapse and the surrounding burned area were net sinks for CO</span>₂<span>, with a mean daytime net ecosystem exchange of −1.4&nbsp;</span><i>μ</i><span>mol CO</span>₂<span>&nbsp;m</span>⁻²<span>&nbsp;s</span>⁻¹<span>, while the moat was a CH</span>₄<span>&nbsp;source with a mean flux of 0.013&nbsp;</span><i>μ</i><span>mol CH</span>₄<span>&nbsp;m</span>⁻²<span>&nbsp;s</span>⁻¹<span>. Regression analyses identified temperature as the dominant factor affecting intragrowing season variation in CO</span>₂<span>&nbsp;exchange and soil moisture as the primary control influencing CH</span>₄<span>&nbsp;emissions. CH</span>₄<span>&nbsp;emissions during the wettest portion of the growing season were four times higher than during the driest periods. If temperatures continue to warm, peatland vegetation will likely expand with permafrost degradation, resulting in greater carbon accumulation and methane emissions for the landscape as a whole.</span></p> application/pdf 10.1029/2007JG000423 en American Geophysical Union Influence of disturbance on carbon exchange in a permafrost collapse and adjacent burned forest article