Lightning NO<sub>2</sub> simulation over the contiguous US and its effects on satellite NO<sub>2</sub> retrievals

Zhu, Qindan; Laughner, Joshua L.; Cohen, Ronald C.

doi:https://doi.org/10.5194/acp-19-13067-2019

Articles | Volume 19, issue 20

https://doi.org/10.5194/acp-19-13067-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/acp-19-13067-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 19, issue 20

Research article

|

23 Oct 2019

Research article |

| 23 Oct 2019

Lightning NO₂ simulation over the contiguous US and its effects on satellite NO₂ retrievals

Qindan Zhu, Joshua L. Laughner, and Ronald C. Cohen

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Final revised paper (published on 23 Oct 2019)
Supplement to the final revised paper
Preprint (discussion started on 09 Apr 2019)
Supplement to the preprint

Interactive discussion

Status: closed

AC: Author comment | RC: Referee comment | SC: Short comment | EC: Editor comment

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RC1: 'Review of Zhu et al.', Anonymous Referee #1, 03 May 2019
RC2: 'Review', Anonymous Referee #2, 12 May 2019
AC1: 'Author's response to both comments', Qindan Zhu, 15 Jul 2019

Peer-review completion

AR: Author's response | RR: Referee report | ED: Editor decision

AR by Qindan Zhu on behalf of the Authors (15 Jul 2019) Author's response Manuscript

ED: Referee Nomination & Report Request started (17 Jul 2019) by Andreas Richter

RR by Anonymous Referee #2 (30 Jul 2019)

Suggestions for revision or reasons for rejection

The revised paper is improved and much more clear and I can understand the authors’ argument that since more advanced lightning schemes have not been implemented in WRF-Chem, the model implementation in this work is a step forward. The discussion provided in the responses is very good, but some of the discussion should be included in the paper or supplement.

(1) The reason that I suggest deleting the statement “The model-satellite NO2 column comparison suggests 500 mol NO flash−1 is too high for the estimate of lightning NOx production rate, but demonstrates that the uncertainty in the modeled UT [NO2]/[NOx] ratio is a key limiting factor in constraining production efficiency over CONUS in the far-field approaches” in the conclusion section is not because I think far-field observations are unimportant for constraining LNOx. But how well we understand NO/NO2 ratio in the upper troposphere (with or without fresh lightning) shouldn’t be mixed with LNOx constraints. Since most of NOx is in form of NO, high-quality NO measurements are sufficient to constrain LNOx using far-field measurements.

Even if we understand and can simulate NO2/NOx ratios in the upper troposphere well, the fact is that NO2 is lower than NO and is arguably more difficult to measure. This last statement of the paper is rather odd to me. So for a third time, I’d suggest either deleting this sentence or providing detailed discussion of the need and application of having both in situ NO and NO2 measurements as constraints of LNOx.

(2) FYI, the R values listed in Table 1 of Luo et al.’s work is for 5-min flash rate comparison between the observations and model results. The correlation values in this work are for daily rates. More averaging can substantially improve R values.

(3) The authors should add some general comments on the differences between G3 and GF schemes in WRF-Chem to (1) explain the differences in the resulting LNOx distributions and (2) compare with the MM5 differences found by Zhao et al. (2009).

(4) I suggest adding more discussion details on the differences between ENTLN and NLDN flash rate observations. Some of the details are already in the response. The absolute counts of flash rates by LIS are also uncertain and it should be mentioned. Since the authors have ENTLN and NLDN datasets, doing a direct comparison with LIS data (accounting for detection efficiencies) would seem straightforward. Why is it not included in the paper?

(5) In Figure 3, the large urban VCD change is not due to lightning over Orlando. What is the reason then? The authors don’t have ENTLN data for that period, can they look at NLDN data to see how well the model simulates lightning flash distribution over urban regions? There are only 4 figures in this paper; adding more discussion cannot hurt.

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RR by Anonymous Referee #1 (09 Aug 2019)

ED: Publish subject to minor revisions (review by editor) (12 Aug 2019) by Andreas Richter

Dear Qindan Zhu,

as you will have seen, both reviewers have submitted their reports on your revised manuscript and made detailed suggestions for (minor) revisions needed before the paper can be accepted. Please consider them and change your manuscript accordingly.

In addition, as already mentioned when accepting your original manuscript for ACPD, I have some questions about the comparison to OMI data:

• In Figure 3, is the cloud fraction threshold of 0.2 used as in Figure 4? If so, please add this information to the caption

• On page 10, line 2, you cite Laughner et al., 2019 for the statement that “uncertainty due to AMF calculation for BEHR v3.0B is smaller than 30%“ I couldn’t find the corresponding statement in that paper and think that more qualification is needed – which parts of the uncertainty do you consider in this number? The way this number is used suggests that you exclude uncertainty from the vertical profile used?

• Why is it OK to assume that AMF uncertainties (which are strongly related to knowledge of surface reflection) are reduced like a random uncertainty when averaging?

• In order to better understand the reason for the large changes over urban areas when changing the lightning parametrisation it would be good to add figures showing

o Vertical profiles of NO2 for the three cases of no lightning, old parametrisation and new parametrisation as well as the scattering weights

o For the two cases of August 24 and September 10 that you discuss

• Please change the labels in Fig. 4 from “change in” to “difference in”

• Please check again if the figures really show BEHR – WRF-Chem as stated in the text and in the caption. Judging from the numbers, I would guess that in fact WRF-Chem – BEHR is shown.

• Why is the spatial pattern of lightning (Fig. 1d) not reflected in Figure 4a?

Please include a point by point reply to the suggestions made by the reviewers and my questions on the AMFs when submitting the revised (and hopefully final) version of your manuscript.

Best regards,

Andreas Richter

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AR by Qindan Zhu on behalf of the Authors (22 Aug 2019) Author's response Manuscript

ED: Publish subject to technical corrections (21 Sep 2019) by Andreas Richter

AR by Qindan Zhu on behalf of the Authors (29 Sep 2019) Author's response Manuscript

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Short summary

Lightning NO_x represents > 80 % of the NO_x source in the upper troposphere. Despite its importance, lightning NO_x is poorly understood. This work improves model performance in representing lighting NO_x and reduces the uncertainty in satellite NO₂ retrievals caused by poor representation of lightning NO_x emissions in a priori assumptions.

Lightning NO2 simulation over the contiguous US and its effects on satellite NO2 retrievals

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Interactive discussion

Peer-review completion

Lightning NO₂ simulation over the contiguous US and its effects on satellite NO₂ retrievals