Higher Apparent Gas Transfer Velocities for CO2 Compared to CH4 in Small Lakes. Pajala, G., Rudberg, D., Gålfalk, M., Melack, J. M., Macintyre, S., Karlsson, J., Sawakuchi, H. O., Schenk, J., Sieczko, A., Sundgren, I., Duc, N. T., & Bastviken, D. Environmental Science & Technology, 57(23):8578–8587, June, 2023. Publisher: American Chemical Society
Higher Apparent Gas Transfer Velocities for CO2 Compared to CH4 in Small Lakes [link]Paper  doi  abstract   bibtex   
Large greenhouse gas emissions occur via the release of carbon dioxide (CO2) and methane (CH4) from the surface layer of lakes. Such emissions are modeled from the air–water gas concentration gradient and the gas transfer velocity (k). The links between k and the physical properties of the gas and water have led to the development of methods to convert k between gases through Schmidt number normalization. However, recent observations have found that such normalization of apparent k estimates from field measurements can yield different results for CH4 and CO2. We estimated k for CO2 and CH4 from measurements of concentration gradients and fluxes in four contrasting lakes and found consistently higher (on an average 1.7 times) normalized apparent k values for CO2 than CH4. From these results, we infer that several gas-specific factors, including chemical and biological processes within the water surface microlayer, can influence apparent k estimates. We highlight the importance of accurately measuring relevant air–water gas concentration gradients and considering gas-specific processes when estimating k.
@article{pajala_higher_2023,
	title = {Higher {Apparent} {Gas} {Transfer} {Velocities} for {CO2} {Compared} to {CH4} in {Small} {Lakes}},
	volume = {57},
	issn = {0013-936X},
	url = {https://doi.org/10.1021/acs.est.2c09230},
	doi = {10.1021/acs.est.2c09230},
	abstract = {Large greenhouse gas emissions occur via the release of carbon dioxide (CO2) and methane (CH4) from the surface layer of lakes. Such emissions are modeled from the air–water gas concentration gradient and the gas transfer velocity (k). The links between k and the physical properties of the gas and water have led to the development of methods to convert k between gases through Schmidt number normalization. However, recent observations have found that such normalization of apparent k estimates from field measurements can yield different results for CH4 and CO2. We estimated k for CO2 and CH4 from measurements of concentration gradients and fluxes in four contrasting lakes and found consistently higher (on an average 1.7 times) normalized apparent k values for CO2 than CH4. From these results, we infer that several gas-specific factors, including chemical and biological processes within the water surface microlayer, can influence apparent k estimates. We highlight the importance of accurately measuring relevant air–water gas concentration gradients and considering gas-specific processes when estimating k.},
	number = {23},
	urldate = {2023-07-20},
	journal = {Environmental Science \& Technology},
	author = {Pajala, Gustav and Rudberg, David and Gålfalk, Magnus and Melack, John Michael and Macintyre, Sally and Karlsson, Jan and Sawakuchi, Henrique Oliveira and Schenk, Jonathan and Sieczko, Anna and Sundgren, Ingrid and Duc, Nguyen Thanh and Bastviken, David},
	month = jun,
	year = {2023},
	note = {Publisher: American Chemical Society},
	keywords = {\#nosource},
	pages = {8578--8587},
}
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