Modelling present-day basal melt rates for Antarctic ice shelves using a parametrization of buoyant meltwater plumes

Lazeroms, Werner M. J.; Jenkins, Adrian; Gudmundsson, G. Hilmar; van de Wal, Roderik S. W.

doi:https://doi.org/10.5194/tc-12-49-2018

Articles | Volume 12, issue 1

https://doi.org/10.5194/tc-12-49-2018

© Author(s) 2018. This work is distributed under
the Creative Commons Attribution 3.0 License.

https://doi.org/10.5194/tc-12-49-2018

© Author(s) 2018. This work is distributed under
the Creative Commons Attribution 3.0 License.

Articles | Volume 12, issue 1

Research article

|

09 Jan 2018

Research article |

| 09 Jan 2018

Modelling present-day basal melt rates for Antarctic ice shelves using a parametrization of buoyant meltwater plumes

Werner M. J. Lazeroms, Adrian Jenkins, G. Hilmar Gudmundsson, and Roderik S. W. van de Wal

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Final revised paper (published on 09 Jan 2018)
Preprint (discussion started on 20 Apr 2017)

Interactive discussion

Status: closed

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

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RC1: 'nteractive comment on “Modelling present-day basal melt rates for Antarctic ice shelves using a parametrization of buoyant meltwater plumes” by Werner M. J. Lazeroms et al.', Tore Hattermann, 25 May 2017
- AC1: 'Author response to Reviewer #1', Werner Lazeroms, 15 Sep 2017
RC2: 'Review of Lazeroms et al. “Modelling present-day basal melt rates for Antarctic ice shelves using a parametrization of buoyant meltwater plumes”', Xylar Asay-Davis, 05 Jul 2017
- AC2: 'Author response to Reviewer #2', Werner Lazeroms, 15 Sep 2017

Peer-review completion

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

AR by Werner Lazeroms on behalf of the Authors (15 Sep 2017) Author's response Manuscript

ED: Referee Nomination & Report Request started (18 Sep 2017) by Kenichi Matsuoka

RR by Xylar Asay-Davis (28 Sep 2017)

RR by Tore Hattermann (13 Oct 2017)

Suggestions for revision or reasons for rejection

I would like to thank the authors for thorough consideration of the remarks made by both reviewers. All open questions have adequately been clarified in the author's response and appropriate measures were taken to adjust the revised version of the manuscript accordingly. I have a few minor remarks that should be implemented to round off these efforts. With that, I am looking forward for publication of this undoubtedly significant and useful contribution for assessing Antarctic ice/ocean interactions. Page and line numbers in my comments refer to the track-changed version of the revised manuscript that was attached to the previous author's response.

The general melt rate curve: Although adding some challenges for the structure of this study, it is comprehensible that the full derivation of the general melt rate curve is reserved for another publication (adding an explicit statement of this in the manuscript would add even more clarity, I think). The revised version of the manuscript clarifies the respective contributions and introduces eqn. (7) and (8) accordingly as starting point for the development presented by this study, with more background on their origin in the Appendix. To this end, I suggest that all remaining material of section 2.2 that explains that physical meaning of the different scaling factors (p 7, line 28 and onwards) is also moved to the Appendix. Although being informative, the complicated theoretical considerations somewhat deviate from the main topic of the paper and are better understood in the context of the remaining material of the Appendix (i.e. when reading the main text, it remains ambiguous that the scaling factors being discussed explicitly appear in A9). As a minor comment on terminology, on page 7, line 19, for clarity replace "edge of the ice shelf" with "ice shelf front", which is the more commonly used.

2D melting parameterization and inverting temperature for melt rates: Although the authors comply with both reviewer's comments, the following aspects only appear in their response, but should also be mentioned explicitly in the paper:

- The algorithm to determine the local slope and grounding line depth also includes (unphysical) paths along reversed slopes of the ice base (could either be included in p. 12, line 15 and following or in the discussion).

- Although stratification being mentioned as an uncertainty, its role should be clarified, i.e. that because of stratification, plumes arising from grounding lines may totally detach from the ice base, with new plumes being initiated from ambient properties at the detachment depth. In that case, the non-local relationship between the melt rate at a given ice shelf point and the grounding line breaks together. I would argue that this is the case for a significant portion of the Antarctic ice shelf area, especially near the ice fronts. It is understood that this cannot necessarily be included in a simple parameterization like this, but it should be mentioned (could either be included at the end of section 2.3 or in the discussion).

- On page 25, line 15, I suggest rephrasing to "with ocean temperatures being constructed in a plausible way". Especially beneath FRIS, temperatures are certainly not plausible, they are known to be below -2 degC for most of the cavity (various Nicholls et al. papers), which is worth telling the reader on p. 21, line 5 and following.

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ED: Publish subject to minor revisions (review by editor) (08 Nov 2017) by Kenichi Matsuoka

Dear authors,

Thanks for your thorough revisions. Both reviewers judge that your revisions satisfactory address their concerns overall. The reviewer #1 recommended accepting the manuscript as is, whereas the reviewer #2 recommended a minor revision. Amongst the comments of the reviewer #2, I leave it to you whether a majority of Section 2.2 moves to Appendix or stays as is. I see the point brought by this reviewer, but also feel that a brief explanation on various length scales is useful for non-specialists.

Together with my own review, I request the authors to revise the manuscript one more time. My current plan is to evaluate the next version by myself without sending the manuscript to reviewers, so that the decision process should not take long time in the next round. When you submit the next version, please include a mark-up manuscript showing changes from this version and a response letter. Please quote major revisions (or show corresponding page/line numbers) in the letter.

P1L7: don’t define symbols of z_gl and alpha in the abstract and replace them at L1L9.

P1L12-14: Probably it is better to say “Our results qualitatively replicate some large-scale observed features in basal melt rates around Antarctica, not only in terms of average values but also in terms of the spatial pattern, with high melt rates typically occurring near the grounding line.” “Realistic map” doesn’t sound good for me.

P1L14: do you mean “The plume parameterization and the effective temperature field presented here…”?

P4L27, P4L32, and elsewhere: Change “ocean water” to “seawater” (or vice versa to keep it consistent throughout the paper).

P7L14-15: Small letter L is defined here as “a temperature- and geometry-dependent length scale”. However, if I understand correctly, it is referred as “the universal length scale l” at P8L23. Because many length scales are discussed in the section 2.2, it is confusing for me. When you define l at P7L14, can you also mention why it has a universal feature?

P7L15: add “l” after “length scale”

P7L28: I think that equation numbers “(9) and (8)” are incorrect. Maybe they are associated with LateX system bug but please double check equation numbers.

P8L9 and P8L13: “The” third and fourth lengths, instead of “a”?

P8L17: Equation number? Cited as (9)

P8L23: Equation number? Probably “in (7)”

P9L4: Revise “same” and “common”, as they are ambiguous. I think that the authors are trying to say “first rising to a peak at the scale distance X ~0.2, before falling and transitioning to freezing at x ~0.8. These locations are insensitive to ….”

P9L14: “In summary, the results of….”

P10L6: “The elevation of the upper ice surface Hs”. H is used for ice thickness and elevations, whereas z is defined as depth. And later, “d” is used to define grounding-line depth. It is confusing.

P10L6 and P10L10, subscript b is used to refer both bedrock and the lower surface of the ice shelf, which can be confusing. Also, “bedrock” is not accurate; seafloor is often covered with sediments, and I think that the authors want to refer “seafloor”, instead of “bedrock”.

P11L11: Define d_n, e.g. “… < zb(i,h), where d_n is the grounding-line depth.” Consider replacing d with z (or consistently use a symbol to refer all depths).

P11L12: no hyphen between depth and difference.

P13L8. Now you use “D” for the plume thickness. Again, please review all symbols used for depth, thickness, elevation etc so that readers will not be confused. Also, check subscript.

P13L10: It is unclear what Hattermann (2012) and Hattermann et al. (2014) say respectively.

P16L7: parametarization”s”, plural.

P18L2: revise. Probably “…. a suitable input of the ocean temperature field”

P18L10: Is the salinity correct? You say 34.6 here, but you used 34.65 for the 1D experiments (P15L11).

P18L17: ocean water -> seawater

P22L7: it is hard to see refreezing areas from Fig. 10 because these areas are patchy and small. Can you briefly describe where (which ice shelves) you found refreezing?

P22L12: positive melt -> melting.

P23L3: remove “important”

P24L2: do you think Rignot’s estimate of 100 m/a is accurate? I accept your general message here that models predict basal melt smaller than the observation but doubt validity of this extreme number.

P28L26: change to “DT between -0.5oC and 5.4oC is required…”

Table 1: third row in the constant parameters. The subscript should be “TS”, not “TS0”.

Table 2: Change “ocean water” to “seawater”

Table 3: explain BG2003 and DCP2016 references in the caption. Also, ocean water -> seawater.

Figure 2: Melting and refreezing parts of the curve are shown with arrows, which is confusing for me. It can be more accurately shown if the positive M domain and negative M domain are masked with different colors.

Figure 3: add “seafloor”, “ocean”, “ice” labels for clarifications.

Figs. 5 and 6: these figures and captions should be improved a lot, as it is difficult to read. How about “Geometry (a) and model results (b-d) for a flow line along the Ronne-Filchner Ice Shelf. (a) Geometry. (b) Melt rates along the flow line when DT = 0 oC. (c) same as (b) but for DT = 0.8oC. (c) Melt rates averaged along the flow line as a function of DT. See Fig. 7 for flowline locations.” Accordingly, change the order of panels. Change the x label for the current panels a and b to “Distance from the grounding line (km)”. Two curves are virtually identical especially for Fig. 5; can you mention this in the caption so that readers do not need to seek for the black curve in panel a which is below the green curve? Why different color sets are used for panel d? It is most convenient if all panels show the results using the same color set. In Fig. 6 caption, please mention that the vertical axis is about one tenth of Fig. 5. For the geometry panel, label ice, ocean, and seafloor.

Please consider combining these two figures into one two-column figure, showing panels a-d for each ice shelf in a column, because geometry is a major factor to determine the peak positions as discussed in the paper, and to see this feature it is more convenient if all figures are aligned vertically.

Fig. 7: is the box 2-3 boundary located correctly? Sigma -> standard deviation. I think that this figure is the best place to show 1D flowline for RF and Ross.

Fig. 9: Sigma -> standard deviation

Fig. 11: remove “on important areas.” so that the caption is read “… and zoomed in (a) …, (b) …., and (c)….” Also, consider showing ice sheet/shelf or ocean masks to clarify the location of the grounding line and the calving front.

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AR by Werner Lazeroms on behalf of the Authors (16 Nov 2017) Author's response Manuscript

ED: Publish as is (21 Nov 2017) by Kenichi Matsuoka

AR by Werner Lazeroms on behalf of the Authors (24 Nov 2017) Manuscript

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Short summary

Basal melting of ice shelves is a major factor in the decline of the Antarctic Ice Sheet, which can contribute significantly to sea-level rise. Here, we investigate a new basal melt model based on the dynamics of meltwater plumes. For the first time, this model is applied to all Antarctic ice shelves. The model results in a realistic melt-rate pattern given suitable data for the topography and ocean temperature, making it a promising tool for future simulations of the Antarctic Ice Sheet.