Efficient In‐cloud Removal of Aerosols by Deep Convection

Pengfei Yu; K. D. Froyd; Robert W. Portmann; Owen B. Toon; Saulo R.  Freitas; Charles G. Bardeen; Charles Brock; Tianyi Fan; Ru-Shan Gao; Joseph M. Katich; Agnieszka Kupc; Shang Liu; Christopher Maloney; Daniel M. Murphy; K.H. Rosenlof; Gregory P. Schill; Joshua P. Schwarz; Christina Williamson

doi:10.1029/2018GL080544

Efficient In‐cloud Removal of Aerosols by Deep Convection

Pengfei Yu (Corresponding author)
, K. D. Froyd
, Robert W. Portmann
, Owen B. Toon
, Saulo R. Freitas
, Charles G. Bardeen
, Charles Brock
, Tianyi Fan
, Ru-Shan Gao
, Joseph M. Katich
, Agnieszka Kupc
, Shang Liu
, Christopher Maloney
, Daniel M. Murphy
, K.H. Rosenlof
, Gregory P. Schill
, Joshua P. Schwarz
, Christina Williamson

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Convective systems dominate the vertical transport of aerosols and trace gases. The most recent in situ aerosol measurements presented here show that the concentrations of primary aerosols including sea salt and black carbon drop by factors of 10 to 10,000 from the surface to the upper troposphere. In this study we show that the default convective transport scheme in the National Science Foundation/Department of Energy Community Earth System Model results in a high bias of 10–1,000 times the measured aerosol mass for black carbon and sea salt in the middle and upper troposphere. A modified transport scheme, which considers aerosol activation from entrained air above the cloud base and aerosol-cloud interaction associated with convection, dramatically improves model agreement with in situ measurements suggesting that deep convection can efficiently remove primary aerosols. We suggest that models that fail to consider secondary activation may overestimate black carbon's radiative forcing by a factor of 2.

Original language	English
Pages (from-to)	1061-1069
Number of pages	9
Journal	Geophysical Research Letters
Volume	46
Issue number	2
DOIs	https://doi.org/10.1029/2018GL080544
Publication status	Published - 28 Jan 2019
Externally published	Yes

Austrian Fields of Science 2012

105904 Environmental research
103039 Aerosol physics

Keywords

CLIMATE SIMULATIONS
DISTRIBUTIONS
MODEL
PARAMETERIZATION
REPRESENTATION
SENSITIVITY
SPECTROMETER
STRATOSPHERE
TRACE GASES
TROPOSPHERIC AEROSOL
deep convection
secondary activation
convective transport
aerosol

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10.1029/2018GL080544Licence: CC BY-NC-ND 4.0

Cite this

Yu, P., Froyd, K. D., Portmann, R. W., Toon, O. B., Freitas, S. R., Bardeen, C. G., Brock, C., Fan, T., Gao, R.-S., Katich, J. M., Kupc, A., Liu, S., Maloney, C., Murphy, D. M., Rosenlof, K. H., Schill, G. P., Schwarz, J. P., & Williamson, C. (2019). Efficient In‐cloud Removal of Aerosols by Deep Convection. Geophysical Research Letters, 46(2), 1061-1069. https://doi.org/10.1029/2018GL080544

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title = "Efficient In‐cloud Removal of Aerosols by Deep Convection",

abstract = "Convective systems dominate the vertical transport of aerosols and trace gases. The most recent in situ aerosol measurements presented here show that the concentrations of primary aerosols including sea salt and black carbon drop by factors of 10 to 10,000 from the surface to the upper troposphere. In this study we show that the default convective transport scheme in the National Science Foundation/Department of Energy Community Earth System Model results in a high bias of 10–1,000 times the measured aerosol mass for black carbon and sea salt in the middle and upper troposphere. A modified transport scheme, which considers aerosol activation from entrained air above the cloud base and aerosol-cloud interaction associated with convection, dramatically improves model agreement with in situ measurements suggesting that deep convection can efficiently remove primary aerosols. We suggest that models that fail to consider secondary activation may overestimate black carbon's radiative forcing by a factor of 2.",

keywords = "CLIMATE SIMULATIONS, DISTRIBUTIONS, MODEL, PARAMETERIZATION, REPRESENTATION, SENSITIVITY, SPECTROMETER, STRATOSPHERE, TRACE GASES, TROPOSPHERIC AEROSOL, deep convection, secondary activation, convective transport, aerosol",

author = "Pengfei Yu and Froyd, \{K. D.\} and Portmann, \{Robert W.\} and Toon, \{Owen B.\} and Freitas, \{Saulo R.\} and Bardeen, \{Charles G.\} and Charles Brock and Tianyi Fan and Ru-Shan Gao and Katich, \{Joseph M.\} and Agnieszka Kupc and Shang Liu and Christopher Maloney and Murphy, \{Daniel M.\} and K.H. Rosenlof and Schill, \{Gregory P.\} and Schwarz, \{Joshua P.\} and Christina Williamson",

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year = "2019",

month = jan,

day = "28",

doi = "10.1029/2018GL080544",

language = "English",

volume = "46",

pages = "1061--1069",

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T1 - Efficient In‐cloud Removal of Aerosols by Deep Convection

AU - Yu, Pengfei

AU - Froyd, K. D.

AU - Portmann, Robert W.

AU - Toon, Owen B.

AU - Freitas, Saulo R.

AU - Bardeen, Charles G.

AU - Brock, Charles

AU - Fan, Tianyi

AU - Gao, Ru-Shan

AU - Katich, Joseph M.

AU - Kupc, Agnieszka

AU - Liu, Shang

AU - Maloney, Christopher

AU - Murphy, Daniel M.

AU - Rosenlof, K.H.

AU - Schill, Gregory P.

AU - Schwarz, Joshua P.

AU - Williamson, Christina

PY - 2019/1/28

Y1 - 2019/1/28

N2 - Convective systems dominate the vertical transport of aerosols and trace gases. The most recent in situ aerosol measurements presented here show that the concentrations of primary aerosols including sea salt and black carbon drop by factors of 10 to 10,000 from the surface to the upper troposphere. In this study we show that the default convective transport scheme in the National Science Foundation/Department of Energy Community Earth System Model results in a high bias of 10–1,000 times the measured aerosol mass for black carbon and sea salt in the middle and upper troposphere. A modified transport scheme, which considers aerosol activation from entrained air above the cloud base and aerosol-cloud interaction associated with convection, dramatically improves model agreement with in situ measurements suggesting that deep convection can efficiently remove primary aerosols. We suggest that models that fail to consider secondary activation may overestimate black carbon's radiative forcing by a factor of 2.

AB - Convective systems dominate the vertical transport of aerosols and trace gases. The most recent in situ aerosol measurements presented here show that the concentrations of primary aerosols including sea salt and black carbon drop by factors of 10 to 10,000 from the surface to the upper troposphere. In this study we show that the default convective transport scheme in the National Science Foundation/Department of Energy Community Earth System Model results in a high bias of 10–1,000 times the measured aerosol mass for black carbon and sea salt in the middle and upper troposphere. A modified transport scheme, which considers aerosol activation from entrained air above the cloud base and aerosol-cloud interaction associated with convection, dramatically improves model agreement with in situ measurements suggesting that deep convection can efficiently remove primary aerosols. We suggest that models that fail to consider secondary activation may overestimate black carbon's radiative forcing by a factor of 2.

KW - CLIMATE SIMULATIONS

KW - DISTRIBUTIONS

KW - MODEL

KW - PARAMETERIZATION

KW - REPRESENTATION

KW - SENSITIVITY

KW - SPECTROMETER

KW - STRATOSPHERE

KW - TRACE GASES

KW - TROPOSPHERIC AEROSOL

KW - deep convection

KW - secondary activation

KW - convective transport

KW - aerosol

UR - https://www.scopus.com/pages/publications/85060638069

U2 - 10.1029/2018GL080544

DO - 10.1029/2018GL080544

M3 - Article

SN - 0094-8276

VL - 46

SP - 1061

EP - 1069

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 2

ER -

Efficient In‐cloud Removal of Aerosols by Deep Convection

Abstract

Austrian Fields of Science 2012

Keywords

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