Sensitivity of tropical tropospheric composition to lightning NO<sub>x</sub> production as determined by replay simulations with GEOS‐5

Liaskos, C. E.; Allen, D. J.; Pickering, Kenneth

doi:10.1002/2014jd022987

Cited by 45 publications

(58 citation statements)

References 92 publications

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“…In Wild (2007) and Liaskos et al (2015) the ozone burden and mean tropospheric column ozone, respectively, scaled approximately linearly with increases in lightning emissions. Using the mean bias data in Table 1 we can calculate the mean increase in ozone column associated with each TgN emission from lightning.…”

Section: Global Annual Spatial and Temporal Ozone Distributionsmentioning

confidence: 99%

“…The solid line shows the mean annual tropopause as diagnosed using the modelled meteorology. Liaskos et al (2015) identified that, even with the same total global emissions, the magnitude and distribution of radiative forcing resulting from lightning emissions is dependent on the method for distributing the emissions horizontally and vertically. The changes in zonal-altitudinal distribution discussed in this section show that these changes could be expected as a result of changes in ozone in the upper troposphere.…”

Section: Differences In the Zonal-altitudinal Distributions Of O X Anmentioning

confidence: 99%

“…Ozone acts as a greenhouse gas in the atmosphere and is most potent in the upper troposphere where temperature differences between the atmosphere and ground are greatest (Lacis et al, 1990;Dahlmann et al, 2011). Understanding lightning NO production and ozone formation in this region is important for de-D. L. Finney et al: Modelling lightning and ozone termining changes in radiative flux resulting from changes in ozone (Liaskos et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…However, this and other existing approaches have been shown to lead to large errors in the distribution of flashes compared to lightning observations (Tost et al, 2007). Several studies have shown that the global magnitude of lightning NO x emissions is an important contributor to ozone and other trace gases, especially in the upper tropical troposphere (Labrador et al, 2005;Wild, 2007;Liaskos et al, 2015). Each of these studies uses a single horizontal distribution of lightning, so the impact of varying the lightning emission distribution is unknown.…”

Section: Introductionmentioning

confidence: 99%

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The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

et al. 2016

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Abstract. A lightning parametrisation based on upward cloud ice flux is implemented in a chemistry-climate model (CCM) for the first time. The UK Chemistry and Aerosols model is used to study the impact of these lightning nitric oxide (NO) emissions on ozone. Comparisons are then made between the new ice flux parametrisation and the commonly used, cloud-top height parametrisation. The ice flux approach improves the simulation of lightning and the temporal correlations with ozone sonde measurements in the middle and upper troposphere. Peak values of ozone in these regions are attributed to high lightning NO emissions. The ice flux approach reduces the overestimation of tropical lightning apparent in this CCM when using the cloud-top approach. This results in less NO emission in the tropical upper troposphere and more in the extratropics when using the ice flux scheme. In the tropical upper troposphere the reduction in ozone concentration is around 5-10 %. Surprisingly, there is only a small reduction in tropospheric ozone burden when using the ice flux approach. The greatest absolute change in ozone burden is found in the lower stratosphere, suggesting that much of the ozone produced in the upper troposphere is transported to higher altitudes. Major differences in the frequency distribution of flash rates for the two approaches are found. The cloud-top height scheme has lower maximum flash rates and more mid-range flash rates than the ice flux scheme. The initial O x (odd oxygen species) production associated with the frequency distribution of continental lightning is analysed to show that higher flash rates are less efficient at producing O x ; low flash rates initially produce around 10 times more O x per flash than high-end flash rates. We find that the newly implemented lightning scheme performs favourably compared to the cloud-top scheme with respect to simulation of lightning and tropospheric ozone. This alternative lightning scheme shows spatial and temporal differences in ozone chemistry which may have implications for comparison between models and observations, as well as for simulation of future changes in tropospheric ozone.

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Section: Global Annual Spatial and Temporal Ozone Distributionsmentioning

confidence: 99%

Section: Differences In the Zonal-altitudinal Distributions Of O X Anmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

et al. 2016

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“…Hegglin and Shepherd, 2009;Zeng et al, 2010) and lightning-produced ozone (e.g. Liaskos et al, 2015).…”

Section: Precursor 30mentioning

confidence: 99%

Key drivers of ozone change and its radiative forcing over the 21st century

Iglesias‐Suarez¹,

Kinnison²,

Rap³

et al. 2017

Preprint

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Over the 21st century changes in both tropospheric and stratospheric ozone are likely 15 to have important consequences for the Earth's radiative balance. In this study we investigated the radiative effects of future ozone changes, using the Community Earth System Model (CESM1), with the Whole Atmosphere Community Climate Model (WACCM), and including fully coupled radiation and chemistry schemes. Using year 2100 conditions from the Representative Concentration Pathways 8.5 (RCP8.5) 20 scenario, we quantified the individual contributions to ozone radiative forcing of (1) climate change (with and without lightning feedback), (2) reduced concentrations of ozone depleting substances (ODSs), and (3) methane increases. We calculated future ozone radiative forcing relative to year 2000 of (1) 63 ± 76 mWm -2 , (2) 129 ± 81 mWm -2 , and (3) 225 ± 85 mWm -2 , due to climate change, ODSs and 25 methane respectively. Our best estimate of net ozone forcing in this set of simulations is 420 ± 120 mWm -2 relative to year 2000, and 750 ± 230 mWm -2 relative to year 1750, with uncertainty range given by approximately ±30 %. We find that the overall long-term tropospheric ozone forcing from methane chemistry-climate feedbacks highlighting the key role of the stratosphere in determining future radiative forcing.

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Lightning channel length and flash energy determined from moments of the flash area distribution

Bruning

Thomas

2015

JGR Atmospheres

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A widely used approach in observational and modeling studies of NO x produced by lightning is to relate NO x production to the number of flashes, without regard for the distribution of lightning flash sizes. Recent studies have begun to consider channel length and flash size, which is now observable with VHF Lightning Mapping Array data. This study uses a capacitor model for flash energy based on the flash coverage area, which defines a size scale. This flash area is then filled with channel using a fractal method and compared to other methods that estimate length directly from the VHF source locations. In the presence of instrument measurement errors, area-and fractal-based estimates are shown to be more stable estimators of flash length than connect-the-dots approaches and therefore are better suited for comparison to NO x production. A geometric interpretation of using vertical profiles of VHF source density to weight the altitude distribution of total channel length is developed. An example of the time series of moments of the lightning flash size distribution is shown for an example case, and some meteorological interpretation is given.

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Sensitivity of tropical tropospheric composition to lightning NO_x production as determined by replay simulations with GEOS‐5

Cited by 45 publications

References 92 publications

The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

Key drivers of ozone change and its radiative forcing over the 21st century

Lightning channel length and flash energy determined from moments of the flash area distribution

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Sensitivity of tropical tropospheric composition to lightning NOx production as determined by replay simulations with GEOS‐5

Cited by 45 publications

References 92 publications

The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

The impact of lightning on tropospheric ozone chemistry using a new global lightning parametrisation

Key drivers of ozone change and its radiative forcing over the 21st century

Lightning channel length and flash energy determined from moments of the flash area distribution

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Sensitivity of tropical tropospheric composition to lightning NO_x production as determined by replay simulations with GEOS‐5