Maxwell–Stefan diffusion: a framework for predicting condensed phase diffusion and phase separation in atmospheric aerosol

Fowler, Kathryn; Connolly, Paul J.; Topping, David O.; O'Meara, Simon

doi:https://doi.org/10.5194/acp-18-1629-2018

Articles | Volume 18, issue 3

https://doi.org/10.5194/acp-18-1629-2018

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

Special issue:

BACCHUS – Impact of Biogenic versus Anthropogenic emissions...

https://doi.org/10.5194/acp-18-1629-2018

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

Articles | Volume 18, issue 3

Research article

|

05 Feb 2018

Research article |

| 05 Feb 2018

Maxwell–Stefan diffusion: a framework for predicting condensed phase diffusion and phase separation in atmospheric aerosol

Kathryn Fowler, Paul J. Connolly, David O. Topping, and Simon O'Meara

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Final revised paper (published on 05 Feb 2018)
Preprint (discussion started on 06 Jun 2017)

Interactive discussion

Status: closed

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

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RC1: 'Review of Fowler et al.', Anonymous Referee #1, 15 Sep 2017
RC2: 'Review for Fowler et al', Anonymous Referee #2, 02 Nov 2017
AC1: 'Response to reviewer comments', Kathryn Fowler, 10 Nov 2017

Peer-review completion

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

AR by Kathryn Fowler on behalf of the Authors (10 Nov 2017) Author's response Manuscript

ED: Publish as is (28 Nov 2017) by Yafang Cheng

Short summary

This is the first time the Maxwell–Stefan framework has been applied to an atmospheric aerosol core–shell model and shows that there is a complex interplay between the viscous and solubility effects on aerosol composition. Understanding aerosol composition is essential to accurately model their interactions within atmospheric systems. We use simple binary systems to demonstrate how viscosity and solubility both play a role in affecting the rate of diffusion through aerosol particles.