Parameterizing cloud top effective radii from satellite retrieved values, accounting for vertical photon transport: quantification and correction of the resulting bias in droplet concentration and liquid water path retrievals

Grosvenor, Daniel P.; Sourdeval, Odran; Wood, Robert

doi:https://doi.org/10.5194/amt-11-4273-2018

Articles | Volume 11, issue 7

https://doi.org/10.5194/amt-11-4273-2018

© Author(s) 2018. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/amt-11-4273-2018

© Author(s) 2018. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 11, issue 7

Research article

|

20 Jul 2018

Research article |

| 20 Jul 2018

Parameterizing cloud top effective radii from satellite retrieved values, accounting for vertical photon transport: quantification and correction of the resulting bias in droplet concentration and liquid water path retrievals

Daniel P. Grosvenor, Odran Sourdeval, and Robert Wood

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Final revised paper (published on 20 Jul 2018)
Preprint (discussion started on 04 Jan 2018)

Interactive discussion

Status: closed

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

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RC1: 'Grosvenor et al. (2018) AMTD, REVIEW:', Anonymous Referee #1, 07 Feb 2018
- AC1: 'Response to Reviewer #1', Daniel Grosvenor, 05 Apr 2018
RC2: 'Good paper, some revision needed though', Zhibo Zhang, 08 Mar 2018
- AC2: 'Response to Reviewer #2', Daniel Grosvenor, 05 Apr 2018

Peer-review completion

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

AR by Daniel Grosvenor on behalf of the Authors (03 May 2018) Author's response Manuscript

ED: Referee Nomination & Report Request started (04 May 2018) by Andrew Sayer

RR by Anonymous Referee #1 (17 May 2018)

Suggestions for revision or reasons for rejection

The authors properly addressed my main concerns. The paper should be accepted after minor revisions.The new error parameterization as a function of effective radius (re) has the advantage of being fully consistent in a (pseudo) adiabatic framework. Although I would have preferred it if the authors had removed the optical depth parameterization, they clearly explain that the re parameterization is more practical, and physical.
1) The new uncertainty discussion is also very informative. I am wondering if the use of a constant cw=1.81*10-6 is an additional source of error (keep in mind that in the extra-tropics and for supercooled clouds, cw should be smaller than 1.81*10-6).
2) Similarly, the fact that the simulations utilize a constant cloud thickness = 1km is inadvertently shaping the vertical profile of re and extinction. Let’s say that a typical cloud thickness for stratocumulus clouds is 400 m, this implies that the cloud top re is smaller than that for a 1000 thickness clouds for the same Nd (i.e., the cloud base/top gradient in r_e would decrease, which could have implications for the photon penetration). I understand that some simplifications need to be made, but I am wondering if something can be said about the dependence of the calculations on the physical thickness.
3) Figure 6: do the figures show the standard deviation of the bias relative to the mean bias? (the caption is a little bit difficult to understand). If so, it would be more informative to express the bias variability relative to the Nd variability, i.e. STD(Ndtrue-Ndretrieved)/STD(Ndtrue).
4) I agree with the authors that the correction could be applied to spatially homogeneous clouds. Consistent with Figure 9, Painemal&Minnis&Sun-Mack (2013, ACP) show that for homogeneous scenes and independent of their total liquid water path (estimated using a microwave satellite sensor), 3.7um re > 2.1 um re. This also suggests that entrainment and precipitation have a secondary role in explaining differences between 3.7 and 2.1um re (at least for stratocumulus clouds).
5) Abstract: I do not think VOCALS should be mentioned in the abstract (VOCALS data are not used in the article). Moreover, the correction technique is not limited to the VOCALS domain.

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ED: Publish subject to minor revisions (review by editor) (23 May 2018) by Andrew Sayer

Dear authors,

Thank you for your revised submission. I received one review of it from one of the initial reviewers, who had previously had several criticisms including the formulation in terms of optical thickness as opposed to effective radius.

That reviewer feels, and I agree, that the manuscript will be suitable for publication in AMT after some additional minor revisions. These reviewer comments are as follows:

"The authors properly addressed my main concerns. The paper should be accepted after minor revisions. The new error parameterization as a function of effective radius (re) has the advantage of being fully consistent in a (pseudo) adiabatic framework. Although I would have preferred it if the authors had removed the optical depth parameterization, they clearly explain that the re parameterization is more practical, and physical.
1) The new uncertainty discussion is also very informative. I am wondering if the use of a constant cw=1.81*10-6 is an additional source of error (keep in mind that in the extra-tropics and for supercooled clouds, cw should be smaller than 1.81*10-6).
2) Similarly, the fact that the simulations utilize a constant cloud thickness = 1km is inadvertently shaping the vertical profile of re and extinction. Let’s say that a typical cloud thickness for stratocumulus clouds is 400 m, this implies that the cloud top re is smaller than that for a 1000 thickness clouds for the same Nd (i.e., the cloud base/top gradient in r_e would decrease, which could have implications for the photon penetration). I understand that some simplifications need to be made, but I am wondering if something can be said about the dependence of the calculations on the physical thickness.
3) Figure 6: do the figures show the standard deviation of the bias relative to the mean bias? (the caption is a little bit difficult to understand). If so, it would be more informative to express the bias variability relative to the Nd variability, i.e. STD(Ndtrue-Ndretrieved)/STD(Ndtrue).
4) I agree with the authors that the correction could be applied to spatially homogeneous clouds. Consistent with Figure 9, Painemal&Minnis&Sun-Mack (2013, ACP) show that for homogeneous scenes and independent of their total liquid water path (estimated using a microwave satellite sensor), 3.7um re > 2.1 um re. This also suggests that entrainment and precipitation have a secondary role in explaining differences between 3.7 and 2.1um re (at least for stratocumulus clouds).
5) Abstract: I do not think VOCALS should be mentioned in the abstract (VOCALS data are not used in the article). Moreover, the correction technique is not limited to the VOCALS domain."

I appreciate the effort you put in to address the reviewers' comments in this version. Please let me know if you have any questions.

Best wishes,

Andrew

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AR by Daniel Grosvenor on behalf of the Authors (14 Jun 2018) Author's response Manuscript

ED: Publish as is (18 Jun 2018) by Andrew Sayer

Short summary

We provide a parameterized correction to the retrieval of cloud effective radius from satellite instruments to account for the assumption that the retrieved value is representative of that at cloud top, whereas in reality it is representative of that lower down. The error leads to errors (which we quantify) in the retrieved cloud droplet concentrations of up to 38 % for stratocumulus regions and also to liquid water path errors, both of which can be corrected using our parameterizations.