Theodore A. Kennedy Emma J. Rosi-Marshall Robert O. Hall 2012 <p><span>Air–water gas exchange governs fluxes of gas into and out of aquatic ecosystems. Knowing this flux is necessary to calculate gas budgets (i.e., O</span>₂<span>) to estimate whole‐ecosystem metabolism and basin‐scale carbon budgets. Empirical data on rates of gas exchange for streams, estuaries, and oceans are readily available. However, there are few data from large rivers and no data from whitewater rapids. We measured gas transfer velocity in the Colorado River, Grand Canyon, as decline in O</span>₂<span>&nbsp;saturation deficit, 7 times in a 28‐km segment spanning 7 rapids. The O</span>₂<span>&nbsp;saturation deficit exists because of hypolimnetic discharge from Glen Canyon Dam, located 25&nbsp;km upriver from Lees Ferry. Gas transfer velocity (</span><i>k</i>₆₀₀<span>) increased with slope of the immediate reach.&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;was &lt;&nbsp;10&nbsp;cm&nbsp;h</span>^−&nbsp;1<span>&nbsp;in flat reaches, while&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;for the steepest rapid ranged 3600–7700&nbsp;cm&nbsp;h</span>^−&nbsp;1<span>, an extremely high value of&nbsp;</span><i>k</i>₆₀₀<span>. Using the rate of gas exchange per unit length of water surface elevation (</span><i>K</i>_drop<span>, m</span>^−&nbsp;1<span>), segment‐integrated&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;varied between 74 and 101&nbsp;cm&nbsp;h</span>^−&nbsp;1<span>. Using&nbsp;</span><i>K</i>_drop<span>&nbsp;we scaled&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;to the remainder of the Colorado River in Grand Canyon. At the scale corresponding to the segment length where 80% of the O</span>₂<span>&nbsp;exchanged with the atmosphere (mean length&nbsp;=&nbsp;26.1&nbsp;km),&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;varied 4.5‐fold between 56 and 272&nbsp;cm&nbsp;h</span>^−&nbsp;1<span>&nbsp;with a mean of 113&nbsp;cm&nbsp;h</span>^−&nbsp;1<span>. Gas transfer velocity for the Colorado River was higher than those from other aquatic ecosystems because of large rapids. Our approach of scaling&nbsp;</span><i>k</i>₆₀₀<span>&nbsp;based on&nbsp;</span><i>K</i>_drop<span>&nbsp;allows comparing gas transfer velocity across rivers with spatially heterogeneous morphology.</span></p> application/pdf 10.1215/21573689-1572535 en Association for the Sciences of Limnology and Oceanography Air-water oxygen exchange in a large whitewater river article