Van ‘t Hoff et al. presented a multi-model analysis of the impact of a future supersonic aircraft fleet on upper troposphere and stratospheric composition.  Overall, it is a good paper and the results provide valuable information for future consideration of deployment of commercial supersonic aircraft.  However, I have some major comments, as well as some minor comments, that need to be addressed before the paper is accepted for publication. Here are the specifics. 

Major comments: 

1. Section 2.2.  The vertical resolution of these models in the upper troposphere and lower stratosphere, could be a critical configuration setup in understanding the aviation impact differences, e.g. Table 3 and Figure 2.  Could you elaborate the vertical resolution of each model? For example, how many layers in the critical region (200 hPa – 50 hPa), average layer thickness? 

1. One of the most interesting findings from this work is the distinctive responses in NOx, O3, and H2O in EMAC which is an online vs the other three models with nudged meteorology.  As the authors mentioned in the text, this is likely due to the meteorological/dynamical feedback induced by the composition changes in H2O and O3.  One major weakness of this work is that while the authors have presented many figures showing the chemical responses both in the main text and in supplement, I couldn’t find any showing the dynamical changes, e.g. temperature, U/V/omega, other transport terms, in EMAC due to supersonic aircraft emissions w.r.t. the control run. It would be useful to include these results as they will help to elucidate the changes in H2O, NOx, NOy, and ozone in different parts of the atmosphere. 

1. Section 3.6.  This is a good discussion section, but I would suggest, instead of “modeling consideration”, make it a more comprehensive discussion to include the following aspects: i) what are the key findings from this paper? Ii) how these findings agree/differ from previous work (Grewe et al., 2007; Zhang et al., 2023; Eastham et al 2022; Matters et al., 2022), qualitatively and quantitatively? iii) what are the implications in differences in offline CTMs vs. online meteorology (as in EMAC)? For example, does the results in this work suggest that models with offline meteorology are possibly not the optimal way to assess supersonic aircraft emissions impact as the offline setup is inadequate in capturing full responses. Or alternatively, you can state what are the key impacts that can be captured by offline CTM and what are the key impacts that occur in atmosphere but missing in offline CTM representation. 

1. Other than the technical documentation of composition changes, what is the bigger implication of this study? Can the authors add a few sentences in the conclusion section about the implication?  As presented throughout the paper, the adoption of A1 scenario supersonic aircraft fleet leads to very small changes in H2O (1-2%), NOx (1-3%), O3 (a few tenths percent, <1DU).  The A3 lower cruise scenario impact is even smaller.  Does this suggest it is reasonable to consider supersonic aircraft fleet in the future? 

Minor comments: 

1. Title and elsewhere in the text.  It is more common to use “multimodel intercomparison” instead of “intermodal comparison”.  Consider revise. 

1. L17 & L96. Other than EMAC, I would not agree to use the word “state-of-the-art” to describe the remaining three models, especially in the context of this paper here.  The CTM capability does not allow to examine the meteorological feedback of the composition change induced by the aircraft emissions.  You can use a softened word such as “comprehensive atmospheric models”. 

1. L19-20.  Here and in most of the places through the text, you are presenting the ozone changes in % unit.  It would be much more helpful to me if you express these changes in dobson unit (DU), or at least include the DU changes in parenthesis, which is the common unit used in literature.   

1. L28.  While it isn’t wrong to use “intercontinental transport”, to not be confused with intercontinental transport of air mass or pollutants (which is another major topic in the composition community), I would suggest you use “intercontinental transportation” instead.   

1. L141.  Should be Burkholder et al. 

1. L196-199.  Please clarify what is the physical water vapour tracer vs. full water vapour tracer, how are they treated differently in the model. 

1. L208.  Missing parenthesis after 2011. 

1. L215.  What do you mean by “fixing it the troposphere”? Relaxed to climatology, or nudge with ERA-Interim data? 

1. L237.  Change “Firstly” to First.  Also if you are listing First, shouldn’t you also use Second and Third, etc. ? I don’t see any in the following sentences. 

1. L238-239.  This sentence seemed to be out of place.  Probably better suited somewhere in Section 2.2.  

1. L245 and thereafter – the use of term “hemispheric fraction”.  As you defined in the text, this is the ratio of the perturbation between the two hemispheres, not the fraction.  By mathematical definition, a fraction is a numerical quantity that represent the portion/part of the whole thing and varies between 0.0 and 1.0.  Please use a more accurate term to describe this.  

1. L247.  Can you actually learn about interhemispheric transport, or is it just the NH --> SH transport since aviation emissions are pre-dominantly emitted in the NH, particularly in the NH mid-latitudes?   

1. Section 3.1.  I find this section is a little hard to follow as the authors are frequently hoping back and forth from model mean responses to inter-model differences, and vs. previous results from Grewe et al. (2007).  May be consider re-arrange the discussion in the following order: model mean impact, including H2O, NOx, Ozone in A1 scenario, A2 scenario and A3 scenario--> how do the A1 results compare with Grewe et al. (2007).  You may want to mention model spread here, but I find it distracting if you discuss the details of why one model is different from the others.  You can move the discussions into the later sections. 

1. L 257.  I am not convinced that the authors presented conclusive evidence to suggest that a smaller NH/SH ratio is due to reduced hemispheric exchange.  Did you check the changes in H2O lifetime?  Short H2O lifetime could lead more faster removal of H2O (from aviation emissions) when it is en route from the NH to SH? There are other possible explanations as well. 

1. L277.  What is the reason behind a net-decrease in H2O in the SH? Is it due to temperature perturbation? Is it due to transport responses from the composition changes? You may consider analyze the model temperature fields, vertical and horizontal transport terms to understand the causes. 

1. Figure 2. Are the dash-dotted lines model tropopause from each model? Please clarify in the figure caption.  

1. L312. I am not sure you should refer to the inter-model differences as “discrepancies”, large variances may be? By discrepancy, you are implying something is unexpected or some models may be inadequately wrong.  

1. L314. Change “afterwards” to (section xx). 

1. L315-327.  See my comment above on model vertical resolution discussion. 

1. Figure 3.  I would suggest you use the same value range for x-axis on all three panels.  This way one can clearly identify the magnitude of differences in H2O changes.  

1. L322. Results from model are not Observed! Models are not observations.  You may use alternative words such as shown, found, identified, etc. 

1. L329.  “This is reflected ...” What is reflected?  Please be specific. 

1. L354. Change “fit” to “agree with” 

1. L385. Delete “be”.  Also slow down was used twice in this sentence. 

1. L392. As I have stated in previous comments, it would be useful to look at the meteorological changes in EMAC to confirm whether the unique responses in EMAC is due to online meteorology. 

1. L400. Change to “These effects combined”  

1. Figure 8 caption: change “changes in percentage of the ozone columns” --> “changes in ozone columns (in percentage)”.  

1. L475. Delete “also” 

1. L564.  Consider use “internal variability” than “noise”.  

1. L547-548.  While I agree it would be nice to have models use similar or save vertical grid/resolution, the adoption of vertical grids is a decision made by each modeling groups in consideration of all factors, including numerical recipes.  This recommendation/suggest is just an overkill.  I would suggest delete this sentence. As an alternative approach, you may mention that differences in vertical grids can be a major contributing source of stratospheric H2O lifetime.