TY - JOUR
T1 - Impact of stratospheric air and surface emissions on tropospheric nitrous oxide during ATom
AU - Gonzalez, Yenny
AU - Commane, Róisín
AU - Manninen, Ethan
AU - Daube, Bruce C.
AU - Schiferl, Luke D.
AU - McManus, J. Barry
AU - McKain, Kathryn
AU - Hintsa, Eric J.
AU - Elkins, James W.
AU - Montzka, Stephen A.
AU - Sweeney, Colm
AU - Moore, Fred
AU - Jimenez, Jose L.
AU - Campuzano Jost, Pedro
AU - Ryerson, Thomas B.
AU - Bourgeois, Ilann
AU - Peischl, Jeff
AU - Thompson, Chelsea R.
AU - Ray, Eric
AU - Wennberg, Paul O.
AU - Crounse, John
AU - Kim, Michelle
AU - Allen, Hannah M.
AU - Newman, Paul A.
AU - Stephens, Britton B.
AU - Apel, Eric C.
AU - Hornbrook, Rebecca S.
AU - Nault, Benjamin A.
AU - Morgan, Eric
AU - Wofsy, Steven C.
N1 - Publisher Copyright:
© 2021 Yenny Gonzalez et al.
PY - 2021/7/22
Y1 - 2021/7/22
N2 - We measured the global distribution of tropospheric N2O mixing ratios during the NASA airborne Atmospheric Tomography (ATom) mission. ATom measured concentrations of g1/4g300 gas species and aerosol properties in 647 vertical profiles spanning the Pacific, Atlantic, Arctic, and much of the Southern Ocean basins, nearly from pole to pole, over four seasons (2016-2018). We measured N2O concentrations at 1gHz using a quantum cascade laser spectrometer (QCLS). We introduced a new spectral retrieval method to account for the pressure and temperature sensitivity of the instrument when deployed on aircraft. This retrieval strategy improved the precision of our ATom QCLS N2O measurements by a factor of three (based on the standard deviation of calibration measurements). Our measurements show that most of the variance of N2O mixing ratios in the troposphere is driven by the influence of N2O-depleted stratospheric air, especially at mid- and high latitudes. We observe the downward propagation of lower N2O mixing ratios (compared to surface stations) that tracks the influence of stratosphere-troposphere exchange through the tropospheric column down to the surface. The highest N2O mixing ratios occur close to the Equator, extending through the boundary layer and free troposphere. We observed influences from a complex and diverse mixture of N2O sources, with emission source types identified using the rich suite of chemical species measured on ATom and the geographical origin calculated using an atmospheric transport model. Although ATom flights were mostly over the oceans, the most prominent N2O enhancements were associated with anthropogenic emissions, including from industry (e.g., oil and gas), urban sources, and biomass burning, especially in the tropical Atlantic outflow from Africa. Enhanced N2O mixing ratios are mostly associated with pollution-related tracers arriving from the coastal area of Nigeria. Peaks of N2O are often associated with indicators of photochemical processing, suggesting possible unexpected source processes. In most cases, the results show how difficult it is to separate the mixture of different sources in the atmosphere, which may contribute to uncertainties in the N2O global budget. The extensive data set from ATom will help improve the understanding of N2O emission processes and their representation in global models.
AB - We measured the global distribution of tropospheric N2O mixing ratios during the NASA airborne Atmospheric Tomography (ATom) mission. ATom measured concentrations of g1/4g300 gas species and aerosol properties in 647 vertical profiles spanning the Pacific, Atlantic, Arctic, and much of the Southern Ocean basins, nearly from pole to pole, over four seasons (2016-2018). We measured N2O concentrations at 1gHz using a quantum cascade laser spectrometer (QCLS). We introduced a new spectral retrieval method to account for the pressure and temperature sensitivity of the instrument when deployed on aircraft. This retrieval strategy improved the precision of our ATom QCLS N2O measurements by a factor of three (based on the standard deviation of calibration measurements). Our measurements show that most of the variance of N2O mixing ratios in the troposphere is driven by the influence of N2O-depleted stratospheric air, especially at mid- and high latitudes. We observe the downward propagation of lower N2O mixing ratios (compared to surface stations) that tracks the influence of stratosphere-troposphere exchange through the tropospheric column down to the surface. The highest N2O mixing ratios occur close to the Equator, extending through the boundary layer and free troposphere. We observed influences from a complex and diverse mixture of N2O sources, with emission source types identified using the rich suite of chemical species measured on ATom and the geographical origin calculated using an atmospheric transport model. Although ATom flights were mostly over the oceans, the most prominent N2O enhancements were associated with anthropogenic emissions, including from industry (e.g., oil and gas), urban sources, and biomass burning, especially in the tropical Atlantic outflow from Africa. Enhanced N2O mixing ratios are mostly associated with pollution-related tracers arriving from the coastal area of Nigeria. Peaks of N2O are often associated with indicators of photochemical processing, suggesting possible unexpected source processes. In most cases, the results show how difficult it is to separate the mixture of different sources in the atmosphere, which may contribute to uncertainties in the N2O global budget. The extensive data set from ATom will help improve the understanding of N2O emission processes and their representation in global models.
UR - https://www.scopus.com/pages/publications/85111164502
U2 - 10.5194/acp-21-11113-2021
DO - 10.5194/acp-21-11113-2021
M3 - Article
AN - SCOPUS:85111164502
SN - 1680-7316
VL - 21
SP - 11113
EP - 11132
JO - Atmospheric Chemistry and Physics
JF - Atmospheric Chemistry and Physics
IS - 14
ER -