The work for this project demonstrated that eddy flux measurements of oxygenated organic trace vapors using state-of-the-art chemical ionization mass spectrometers are feasible - from forest towers (described in detail in our peer-reviewed publication), as well as from aircraft (manuscripts in preparation). These efforts will be helpful for users of same or similar instrumentation when performing future eddy flux measurements.
For the HI-SCALE aircraft campaign, an additional instrumental technique (ionization using benzene ions) was tested, characterized and deployed - the first time for high-frequency airborne measurements. This method has shown promise for future applications for the highly sensitive quantification of mixing ratios of traces gases important to air chemistry, yet not accessible to many other, more common modes of operation (or only at relatively low sensitivity); that is in addition to the wide range of oxygenated organics and acids the instrument has already been very sensitive to. Examples are a wide range of alkenes (e.g. isoprene), aromatic organics, ammonia, or dimethyl sulfide (manuscript in preparation).
The HI-SCALE campaign measurements overall were very successful. However, data analysis is still on-going and the wider impacts of the results remain to be seen. The analysis has been promising, and we expect new discoveries regarding how in detail isoprene oxidation in various air masses affect aerosol and cloud formation, in particular for the US Southern Great Plains, and ensuing improvements in models that aim at predicting cloud formation on regional and larger scales and climatic impacts. By the team's outreach efforts and our aim to publish in widely visible high-impact journals, we try for our findings to reach and be of interest to legislators and policy makers dealing with issues in air quality, energy and climate.