Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach

This paper presents a novel approach to investigate cloud-aerosol interactions by coupling a Markov Chain Monte Carlo (MCMC) algorithm to a pseudo-adiabatic cloud parcel model. Despite the number of numerical cloud-aerosol sensitivity studies previously conducted few have used statistical analysis t...

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Main Authors: D.G. Partridge, J.A. Vrugt, P. Tunved, A.M.L. Ekman, H. Struthers, A. Sorooshian
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
Arctic
Online Access:http://hdl.handle.net/11245/1.382172
id ftunivamstpubl:oai:uvapub:382172
record_format openpolar
spelling ftunivamstpubl:oai:uvapub:382172 2023-05-15T15:17:08+02:00 Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach D.G. Partridge J.A. Vrugt P. Tunved A.M.L. Ekman H. Struthers A. Sorooshian 2012 http://hdl.handle.net/11245/1.382172 en eng 10.5194/acpd-11-20051-2011 It is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), other than for strictly personal, individual use, unless the work is under an open content licence (like Creative Commons). Atmospheric Chemistry and Physics (16807316) vol.11 (2012) p.20051-20105 article 2012 ftunivamstpubl 2015-11-19T11:35:35Z This paper presents a novel approach to investigate cloud-aerosol interactions by coupling a Markov Chain Monte Carlo (MCMC) algorithm to a pseudo-adiabatic cloud parcel model. Despite the number of numerical cloud-aerosol sensitivity studies previously conducted few have used statistical analysis tools to investigate the sensitivity of a cloud model to input aerosol physiochemical parameters. Using synthetic data as observed values of cloud droplet number concentration (CDNC) distribution, this inverse modelling framework is shown to successfully converge to the correct calibration parameters. The employed analysis method provides a new, integrative framework to evaluate the sensitivity of the derived CDNC distribution to the input parameters describing the lognormal properties of the accumulation mode and the particle chemistry. To a large extent, results from prior studies are confirmed, but the present study also provides some additional insightful findings. There is a clear transition from very clean marine Arctic conditions where the aerosol parameters representing the mean radius and geometric standard deviation of the accumulation mode are found to be most important for determining the CDNC distribution to very polluted continental environments (aerosol concentration in the accumulation mode >1000 cm−3) where particle chemistry is more important than both number concentration and size of the accumulation mode. The competition and compensation between the cloud model input parameters illustrate that if the soluble mass fraction is reduced, both the number of particles and geometric standard deviation must increase and the mean radius of the accumulation mode must increase in order to achieve the same CDNC distribution. For more polluted aerosol conditions, with a reduction in soluble mass fraction the parameter correlation becomes weaker and more non-linear over the range of possible solutions (indicative of the sensitivity). This indicates that for the cloud parcel model used herein, the relative importance of the soluble mass fraction appears to decrease if the number or geometric standard deviation of the accumulation mode is increased. This study demonstrates that inverse modelling provides a flexible, transparent and integrative method for efficiently exploring cloud-aerosol interactions efficiently with respect to parameter sensitivity and correlation. Article in Journal/Newspaper Arctic Universiteit van Amsterdam: Digital Academic Repository (UvA DARE) Arctic
institution Open Polar
collection Universiteit van Amsterdam: Digital Academic Repository (UvA DARE)
op_collection_id ftunivamstpubl
language English
description This paper presents a novel approach to investigate cloud-aerosol interactions by coupling a Markov Chain Monte Carlo (MCMC) algorithm to a pseudo-adiabatic cloud parcel model. Despite the number of numerical cloud-aerosol sensitivity studies previously conducted few have used statistical analysis tools to investigate the sensitivity of a cloud model to input aerosol physiochemical parameters. Using synthetic data as observed values of cloud droplet number concentration (CDNC) distribution, this inverse modelling framework is shown to successfully converge to the correct calibration parameters. The employed analysis method provides a new, integrative framework to evaluate the sensitivity of the derived CDNC distribution to the input parameters describing the lognormal properties of the accumulation mode and the particle chemistry. To a large extent, results from prior studies are confirmed, but the present study also provides some additional insightful findings. There is a clear transition from very clean marine Arctic conditions where the aerosol parameters representing the mean radius and geometric standard deviation of the accumulation mode are found to be most important for determining the CDNC distribution to very polluted continental environments (aerosol concentration in the accumulation mode >1000 cm−3) where particle chemistry is more important than both number concentration and size of the accumulation mode. The competition and compensation between the cloud model input parameters illustrate that if the soluble mass fraction is reduced, both the number of particles and geometric standard deviation must increase and the mean radius of the accumulation mode must increase in order to achieve the same CDNC distribution. For more polluted aerosol conditions, with a reduction in soluble mass fraction the parameter correlation becomes weaker and more non-linear over the range of possible solutions (indicative of the sensitivity). This indicates that for the cloud parcel model used herein, the relative importance of the soluble mass fraction appears to decrease if the number or geometric standard deviation of the accumulation mode is increased. This study demonstrates that inverse modelling provides a flexible, transparent and integrative method for efficiently exploring cloud-aerosol interactions efficiently with respect to parameter sensitivity and correlation.
format Article in Journal/Newspaper
author D.G. Partridge
J.A. Vrugt
P. Tunved
A.M.L. Ekman
H. Struthers
A. Sorooshian
spellingShingle D.G. Partridge
J.A. Vrugt
P. Tunved
A.M.L. Ekman
H. Struthers
A. Sorooshian
Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
author_facet D.G. Partridge
J.A. Vrugt
P. Tunved
A.M.L. Ekman
H. Struthers
A. Sorooshian
author_sort D.G. Partridge
title Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
title_short Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
title_full Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
title_fullStr Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
title_full_unstemmed Inverse modeling of cloud-aerosol interactions — Part 2: Sensitivity tests on liquid phase clouds using a Markov Chain Monte Carlo based simulation approach
title_sort inverse modeling of cloud-aerosol interactions — part 2: sensitivity tests on liquid phase clouds using a markov chain monte carlo based simulation approach
publishDate 2012
url http://hdl.handle.net/11245/1.382172
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_source Atmospheric Chemistry and Physics (16807316) vol.11 (2012) p.20051-20105
op_relation 10.5194/acpd-11-20051-2011
op_rights It is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), other than for strictly personal, individual use, unless the work is under an open content licence (like Creative Commons).
_version_ 1766347401678815232

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