Marine latitude/altitude OH distributions: Comparison of Pacific Ocean observations with models

Authors

D. Davis, Georgia Institute of Technology
G. Grodzinsky, Georgia Institute of Technology
G. Chen, Georgia Institute of Technology
J. Crawford, NASA Langley Research Center
F. Eisele, Georgia Institute of Technology
L. Mauldin, National Center for Atmospheric Research
D. Tanner, Georgia Institute of Technology
C. Cantrell, National Center for Atmospheric Research
W. Brune, Pennsylvania State University
D. Tan, Pennsylvania State University
I. Faloona, Pennsylvania State University
B. Ridley, National Center for Atmospheric Research
D. Montzka, National Center for Atmospheric Research
J. Walega, National Center for Atmospheric Research
F. Grahek, National Center for Atmospheric Research
S. Sandholm, Georgia Institute of Technology
G. Sachse, NASA Langley Research Center
S. Vay, NASA Langley Research Center
B. Anderson, NASA Langley Research Center
M. Avery, NASA Langley Research Center
B. Heikes, University of Rhode Island
J. Snow, University of Rhode Island
D. O'Sullivan, US Naval Academy
R. Shetter, National Center for Atmospheric Research
B. Lefer, National Center for Atmospheric Research
D. Blake, University of California, Irvine
N. Blake, University of California, Irvine
M. Carroll, University of Michigan, Ann Arbor
Y. Wang, Georgia Institute of Technology

Document Type

Article

Date of Original Version

12-16-2001

Abstract

Reported here are tropical/subtropical Pacific basin OH observational data presented in a latitude/altitude geographical grid. They cover two seasons of the year (spring and fall) that reflect the timing of NASA's PEM-Tropics A (1996) and B (1999) field programs. Two different OH sensors were used to collect these data, and each instrument was mounted on a different aircraft platform (i.e., NASA's P-3B and DC-8). Collectively, these chemical snapshots of the central Pacific have revealed several interesting trends. Only modest decreases (factors of 2 to 3) were found in the levels of OH with increasing altitude (0-12 km). Similarly, only modest variations were found (factors of 1.5 to 3.5) when the data were examined as a function of latitude (30° N to 30° S). Using simultaneously recorded data for CO, O3, H2O, NO, and NMHCs, comparisons with current models were also carried out. For three out of four data subsets, the results revealed a high level of correspondence. On average, the box model results agreed with the observations within a factor of 1.5. The comparison with the three-dimensional model results was found to be only slightly worse. Overall, these results suggest that current model mechanisms capture the major photochemical processes controlling OH quite well and thus provide a reasonably good representation of OH levels for tropical marine environments. They also indicate that the two OH sensors employed during the PEM-Tropics B study generally saw similar OH levels when sampling a similar tropical marine environment. However, a modest altitude bias appears to exist between these instruments. More rigorous instrument intercomparison activity would therefore seem to be justified. Further comparisons of model predictions with observations are also recommended for nontropical marine environments as well as those involving highly elevated levels of reactive non-methane hydrocarbons. Copyright 2001 by the American Geophysical Union.

Publication Title, e.g., Journal

Journal of Geophysical Research Atmospheres

Volume

106

Issue

D23

Citation/Publisher Attribution

Davis, D., G. Grodzinsky, G. Chen, J. Crawford, F. Eisele, L. Mauldin, D. Tanner, C. Cantrell, W. Brune, D. Tan, I. Faloona, B. Ridley, D. Montzka, J. Walega, F. Grahek, S. Sandholm, G. Sachse, S. Vay, B. Anderson, M. Avery, B. Heikes, J. Snow, D. O'Sullivan, R. Shetter, B. Lefer, D. Blake, N. Blake, M. Carroll, and Y. Wang. "Marine latitude/altitude OH distributions: Comparison of Pacific Ocean observations with models." Journal of Geophysical Research Atmospheres 106, D23 (2001). doi: 10.1029/2001JD900141.