Quantifying CO2 Distribution at the Air-Water Interface - Spatiotemporally Resolved Measurements Using Tunable Diode Laser Spectroscopy
Abstract
The transport of CO2 across the air-water interface plays a critical role in physical oceanography and carbon sequestration. One of the key challenges in understanding such transport processes is their multiscale nature - the spatial and temporal scales of gas- and liquid-phase diffusion, absorption and reaction span over several orders of magnitude, which requires high-resolution diagnostic methods to unravel their detailed dynamics. The current study presents a novel diagnostic method to quantify the CO2 distribution at the air-water interface in a spatially and temporally resolved manner. This method combines the advantages of tunable diode laser spectroscopy and rapid spatial beam scanning for precision measurement of the CO2 concentration profile above the interface. The performance of this method was examined in a series of quasi-1D demonstration experiments conducted in a custom-built miniature gas chamber, where the cross-interface diffusion and absorption of gas-phase CO2 into pure water and alkaline solutions of different pH values were continuously monitored. An effective time resolution of 5 ms and an effective spatial resolution of 1 mm were achieved. The results of the gas-phase CO2 distribution evolution agreed well with the classic one-dimensional diffusion model, which verified the accuracy of the current method. Additionally, an interesting phenomenon was observed regarding the temporal evolution of interfacial CO2 concentration at different pH levels: its depletion rate exhibited strong pH sensitivity at relatively low pH but saturated near pH = 10. This could be attributed to competition between gas-/liquid-phase diffusion and absorption/reaction occurring within the interface layer. The high temporal and spatial resolution of the current method promises to be useful in experimental studies of cross-interface gas transport under more complex flow conditions as well.