Formaldehyde column density measurements as a suitable pathway to estimate near-surface ozone tendencies from space

In support of future satellite missions that aim to address the current shortcomings in measuring air quality from space, NASA's Deriving Information on Surface Conditions from Column and Vertically Resolved Observations Relevant to Air Quality (DISCOVER-AQ) field campaign was designed to enable exploration of relationships between column measurements of trace species relevant to air quality at high spatial and temporal resolution. In the DISCOVER-AQ data set, a modest correlation (r(2) = 0.45) between ozone (O-3) and formaldehyde (CH2O) column densities was observed. Further analysis revealed regional variability in the O-3-CH2O relationship, with Maryland having a strong relationship when data were viewed temporally and Houston having a strong relationship when data were viewed spatially. These differences in regional behavior are attributed to differences in volatile organic compound (VOC) emissions. In Maryland, biogenic VOCs were responsible for similar to 28% of CH2O formation within the boundary layer column, causing CH2O to, in general, increase monotonically throughout the day. In Houston, persistent anthropogenic emissions dominated the local hydrocarbon environment, and no discernable diurnal trend in CH2O was observed. Box model simulations suggested that ambient CH2O mixing ratios have a weak diurnal trend (+/- 20% throughout the day) due to photochemical effects, and that larger diurnal trends are associated with changes in hydrocarbon precursors. Finally, mathematical relationships were developed from first principles and were able to replicate the different behaviors seen in Maryland and Houston. While studies would be necessary to validate these results and determine the regional applicability of the O-3-CH2O relationship, the results presented here provide compelling insight into the ability of future satellite missions to aid in monitoring near-surface air quality.

To Access Resource:

Questions? Email Resource Support Contact:

  • opensky@ucar.edu
    UCAR/NCAR - Library

Resource Type publication
Temporal Range Begin N/A
Temporal Range End N/A
Temporal Resolution N/A
Bounding Box North Lat N/A
Bounding Box South Lat N/A
Bounding Box West Long N/A
Bounding Box East Long N/A
Spatial Representation N/A
Spatial Resolution N/A
Related Links N/A
Additional Information N/A
Resource Format PDF
Standardized Resource Format PDF
Asset Size N/A
Legal Constraints

Copyright 2016 American Geophysical Union.


Access Constraints None
Software Implementation Language N/A

Resource Support Name N/A
Resource Support Email opensky@ucar.edu
Resource Support Organization UCAR/NCAR - Library
Distributor N/A
Metadata Contact Name N/A
Metadata Contact Email opensky@ucar.edu
Metadata Contact Organization UCAR/NCAR - Library

Author Schroeder, Jason R.
Crawford, James H.
Fried, Alan
Walega, James
Weinheimer, Andrew
Wisthaler, Armin
Müller, Markus
Mikoviny, Tomas
Chen, Gao
Shook, Michael
Blake, Donald R.
Diskin, Glenn
Estes, Mark
Thompson, Anne M.
Lefer, Barry L.
Long, Russell
Mattson, Eric
Publisher UCAR/NCAR - Library
Publication Date 2016-11-16T00:00:00
Digital Object Identifier (DOI) Not Assigned
Alternate Identifier N/A
Resource Version N/A
Topic Category geoscientificInformation
Progress N/A
Metadata Date 2023-08-18T19:11:19.485872
Metadata Record Identifier edu.ucar.opensky::articles:19346
Metadata Language eng; USA
Suggested Citation Schroeder, Jason R., Crawford, James H., Fried, Alan, Walega, James, Weinheimer, Andrew, Wisthaler, Armin, Müller, Markus, Mikoviny, Tomas, Chen, Gao, Shook, Michael, Blake, Donald R., Diskin, Glenn, Estes, Mark, Thompson, Anne M., Lefer, Barry L., Long, Russell, Mattson, Eric. (2016). Formaldehyde column density measurements as a suitable pathway to estimate near-surface ozone tendencies from space. UCAR/NCAR - Library. http://n2t.net/ark:/85065/d7gb25s2. Accessed 18 January 2025.

Harvest Source