Photochemical production of ozone in the upper troposphere in association with cumulus convection over Indonesia

Kita, K.; Kawakami, S.; Miyazaki, Y.; Higashi, Youichirou; Kondo, Yutaka; Nishi, Noriyuki; Koike, M.; Blake, D. R.; Machida, Toshinobu; Sano, Takeshi; Hu, Wenjie; Ko, Malcolm K. W.; Ogawa, T.

doi:10.1029/2001jd000844

Cited by 35 publications

(49 citation statements)

References 47 publications

(67 reference statements)

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“…For storms with an inflow characterized by urban environments generally higher values were deduced during ABLE 2B (16.5-17.2 ppbv d −1 ) (Pickering et al, 1992a). Higher values were also observed for convective transport from biomass burning plumes during ABLE 2A over South America (7.4-8.5 ppbv d −1 ) (Pickering et al, 1992b), while smaller values of the order of 1-1.5 ppbv d −1 have been observed over tropical oceans (Pickering et al, 1993;Schultz et al, 1999;Kita et al, 2003;Koike et al, 2007). During HOOVER II an eastward moving mesoscale convective system developed over the southern part of Germany on 19 July 2007.…”

Section: The Influence Of Deep Convection On Noprmentioning

confidence: 67%

Chemical processes related to net ozone tendencies in the free troposphere

et al. 2017

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Abstract. Ozone (O 3 ) is an important atmospheric oxidant, a greenhouse gas, and a hazard to human health and agriculture. Here we describe airborne in situ measurements and model simulations of O 3 and its precursors during tropical and extratropical field campaigns over South America and Europe, respectively. Using the measurements, net ozone formation/destruction tendencies are calculated and compared to 3-D chemistry-transport model simulations. In general, observation-based net ozone tendencies are positive in the continental boundary layer and the upper troposphere at altitudes above ∼ 6 km in both environments. On the other hand, in the marine boundary layer and the middle troposphere, from the top of the boundary layer to about 6-8 km altitude, net O 3 destruction prevails. The ozone tendencies are controlled by ambient concentrations of nitrogen oxides (NO x ). In regions with net ozone destruction the available NO x is below the threshold value at which production and destruction of O 3 balance. While threshold NO values increase with altitude, in the upper troposphere NO x concentrations are generally higher due to the integral effect of convective precursor transport from the boundary layer, downward transport from the stratosphere and NO x produced by lightning. Two case studies indicate that in fresh convective outflow of electrified thunderstorms net ozone production is enhanced by a factor 5-6 compared to the undisturbed upper tropospheric background. The chemistry-transport model MATCH-MPIC generally reproduces the pattern of observation-based net ozone tendencies but mostly underestimates the magnitude of the net tendency (for both net ozone production and destruction).

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Section: The Influence Of Deep Convection On Noprmentioning

confidence: 67%

Chemical processes related to net ozone tendencies in the free troposphere

et al. 2017

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“…The comparison of the oxygen isotopic anomaly of sulfate aerosols with the OEI reveals that higher . A significant increase of total ozone during ENSO-III (1997-1998) was accompanied by decreased precipitation, producing extensive forest fires in Indonesia, Australia, and South America (46,47). The influence of ENSOs on total columnar ozone has been attributed to the variation in the tropopause height driven by changes of tropical deep convection and alteration of Brewer-Dobson circulation (14,48).…”

Section: Discussionmentioning

confidence: 99%

Tales of volcanoes and El-Niño southern oscillations with the oxygen isotope anomaly of sulfate aerosol

Shaheen

Abauanza

Jackson

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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The ability of sulfate aerosols to reflect solar radiation and simultaneously act as cloud condensation nuclei renders them central players in the global climate system. The oxidation of S(IV) compounds and their transport as stable S(VI) in the Earth's system are intricately linked to planetary scale processes, and precise characterization of the overall process requires a detailed understanding of the linkage between climate dynamics and the chemistry leading to the product sulfate. This paper reports a high-resolution, 22-y (1980-2002) record of the oxygen-triple isotopic composition of sulfate (SO 4 ) aerosols retrieved from a snow pit at the South Pole. Observed variation in the O-isotopic anomaly of SO 4 aerosol is linked to the ozone variation in the tropical upper troposphere/ lower stratosphere via the Ozone El-Niño Southern Oscillations (ENSO) Index (OEI). Higher Δ 17 O values (3.3‰, 4.5‰, and 4.2‰) were observed during the three largest ENSO events of the past 2 decades. Volcanic events inject significant quantities of SO 4 aerosol into the stratosphere, which are known to affect ENSO strength by modulating stratospheric ozone levels (OEI = 6 and Δ 17 O = 3.3‰, OEI = 11 and Δ 17 O = 4.5‰) and normal oxidative pathways. Our high-resolution data indicated that Δ 17 O of sulfate aerosols can record extreme phases of naturally occurring climate cycles, such as ENSOs, which couple variations in the ozone levels in the atmosphere and the hydrosphere via temperature driven changes in relative humidity levels. A longer term, higher resolution oxygen-triple isotope analysis of sulfate aerosols from ice cores, encompassing more ENSO periods, is required to reconstruct paleo-ENSO events and paleotropical ozone variations.

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“…Over the Southern Pacific, biomass burning dominates the supply of NO x in the lower troposphere but LNO x dominates NO x in the upper troposphere and both make similar contributions to O 3 production (Staudt et al, 2002). During the 1997 Indonesian fire episode, LNO x appears to be more important for O 3 formation than the release of NO x from biomass fires (Duncan et al, 2003;Kita et al, 2003). Several studies (Martin et al, 2002b;Edwards et al, 2003;Jenkins et al, 2003;Chatfield et al, 2004) have explored the Atlantic "ozone paradox" (Thompson et al, 2000a), with high O 3 over the Atlantic south of the Equator during the Northern African biomass burning season in DecemberFebruary (Weller et al, 1996;Thompson, 2004).…”

Section: Other Trace Species From Lightningmentioning

confidence: 99%

The global lightning-induced nitrogen oxides source

2007

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Abstract. The knowledge of the lightning-induced nitrogen oxides (LNO x ) source is important for understanding and predicting the nitrogen oxides and ozone distributions in the troposphere and their trends, the oxidising capacity of the atmosphere, and the lifetime of trace gases destroyed by reactions with OH. This knowledge is further required for the assessment of other important NO x sources, in particular from aviation emissions, the stratosphere, and from surface sources, and for understanding the possible feedback between climate changes and lightning. This paper reviews more than 3 decades of research. The review includes laboratory studies as well as surface, airborne and satellite-based observations of lightning and of NO x and related species in the atmosphere. Relevant data available from measurements in regions with strong LNO x influence are identified, including recent observations at midlatitudes and over tropical continents where most lightning occurs. Various methods to model LNO x at cloud scales or globally are described. Previous estimates are re-evaluated using the global annual mean flash frequency of 44±5 s −1 reported from OTD satellite data. From the review, mainly of airborne measurements near thunderstorms and cloud-resolving models, we conclude that a "typical" thunderstorm flash produces 15 (2-40)×10 25 NO molecules per flash, equivalent to 250 mol NO x or 3.5 kg of N mass per flash with uncertainty factor from 0.13 to 2.7. Mainly as a result of global model studies for various LNO x parameterisations tested with related observations, the best estimate of the annual global LNO x nitrogen mass source and its uncertainty range is (5±3) Tg a −1 in this study. In spite of a smaller global flash rate, the best estimate is essentially the same as in some earlier reviews, implying larger flash-specific NO x emissions. The paper estimates the LNO x accuracy required for various applications and lays out strategies for improving estimates in the future. An accuracy of Correspondence to: U. Schumann (ulrich.schumann@dlr.de) about 1 Tg a −1 or 20%, as necessary in particular for understanding tropical tropospheric chemistry, is still a challenging goal.

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Photochemical production of ozone in the upper troposphere in association with cumulus convection over Indonesia

Cited by 35 publications

References 47 publications

Chemical processes related to net ozone tendencies in the free troposphere

Chemical processes related to net ozone tendencies in the free troposphere

Tales of volcanoes and El-Niño southern oscillations with the oxygen isotope anomaly of sulfate aerosol

The global lightning-induced nitrogen oxides source

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