Abstract
Isoprene is the atmosphere’s most important non-methane organic compound, with key impacts on atmospheric oxidation, ozone, and organic aerosols. In-situ isoprene measurements are sparse, and satellite-based constraints have employed an indirect approach using its oxidation product formaldehyde, which is affected by non-isoprene sources plus uncertainty and spatial smearing in the isoprene-formaldehyde relationship. Direct global isoprene measurements are therefore needed to better understand its sources, sinks, and atmospheric impacts. Here we show that the isoprene spectral signatures are detectable from space using the satellite-borne Cross-track Infrared Sounder (CrIS), develop a full-physics retrieval methodology for quantifying isoprene abundances from these spectral features, and apply the algorithm to CrIS measurements over Amazonia. The results are consistent with model output and in-situ data, and establish the feasibility of direct global space-based isoprene measurements. Finally, we demonstrate the potential for combining space-based measurements of isoprene and formaldehyde to constrain atmospheric oxidation over isoprene source regions.
Highlights
Isoprene is the atmosphere’s most important non-methane organic compound, with key impacts on atmospheric oxidation, ozone, and organic aerosols
The Cross-track Infrared Sounder (CrIS) instrument was launched on-board the Suomi-National Polar-Orbiting Partnership (NPP) satellite into a sun-synchronous orbit on October 28, 2011, and conducts cross-track scanning with 2200 km swath width, providing near-global coverage twice daily
We present a full-physics algorithm that can precisely and accurately retrieve atmospheric isoprene abundances while properly accounting for the relevant spectral interferences
Summary
Isoprene is the atmosphere’s most important non-methane organic compound, with key impacts on atmospheric oxidation, ozone, and organic aerosols. Direct global isoprene measurements are needed to better understand its sources, sinks, and atmospheric impacts. The results are consistent with model output and in-situ data, and establish the feasibility of direct global space-based isoprene measurements. We demonstrate the potential for combining space-based measurements of isoprene and formaldehyde to constrain atmospheric oxidation over isoprene source regions. Formaldehyde (HCHO), as a high-yield isoprene oxidation product that is observable from space, has been widely used as a proxy for investigating isoprene emissions[9,10,11]. Formaldehyde is produced from other VOCs, and is not a unique marker for isoprene This presents particular challenges over fire regions, and over populated areas with their substantial anthropogenic VOC sources. The use of formaldehyde as an isoprene proxy is hindered by incomplete knowledge of the non-linear chemistry linking isoprene and OH13, and of the NOx-dependence governing the formaldehyde yield and its production timescale[14]
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