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Coupling an aerosol box model with one-dimensional flow : A tool for understanding observations of new particle formation events

Kivekäs, Niku LU ; Carpman, Jimmie ; Roldin, Pontus LU ; Leppä, Johannes ; O'Connor, Ewan ; Kristensson, Adam LU and Asmi, Eija (2016) In Tellus. Series B: Chemical and Physical Meteorology 68(1).
Abstract

Field observations of new particle formation and the subsequent particle growth are typically only possible at a fixed measurement location, and hence do not follow the temporal evolution of an air parcel in a Lagrangian sense. Standard analysis for determining formation and growth rates requires that the time-dependent formation rate and growth rate of the particles are spatially invariant; air parcel advection means that the observed temporal evolution of the particle size distribution at a fixed measurement location may not represent the true evolution if there are spatial variations in the formation and growth rates. Here we present a zerodimensional aerosol box model coupled with one-dimensional atmospheric flow to describe the... (More)

Field observations of new particle formation and the subsequent particle growth are typically only possible at a fixed measurement location, and hence do not follow the temporal evolution of an air parcel in a Lagrangian sense. Standard analysis for determining formation and growth rates requires that the time-dependent formation rate and growth rate of the particles are spatially invariant; air parcel advection means that the observed temporal evolution of the particle size distribution at a fixed measurement location may not represent the true evolution if there are spatial variations in the formation and growth rates. Here we present a zerodimensional aerosol box model coupled with one-dimensional atmospheric flow to describe the impact of advection on the evolution of simulated new particle formation events. Wind speed, particle formation rates and growth rates are input parameters that can vary as a function of time and location, using wind speed to connect location to time. The output simulates measurements at a fixed location; formation and growth rates of the particle mode can then be calculated from the simulated observations at a stationary point for different scenarios and be compared with the 'true' input parameters. Hence, we can investigate how spatial variations in the formation and growth rates of new particles would appear in observations of particle number size distributions at a fixed measurement site. We show that the particle size distribution and growth rate at a fixed location is dependent on the formation and growth parameters upwind, even if local conditions do not vary. We also show that different input parameters used may result in very similar simulated measurements. Erroneous interpretation of observations in terms of particle formation and growth rates, and the time span and areal extent of new particle formation, is possible if the spatial effects are not accounted for.

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author
; ; ; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Interpretation of measurements, New particle formation, Spatial variation
in
Tellus. Series B: Chemical and Physical Meteorology
volume
68
issue
1
article number
29706
publisher
Taylor & Francis
external identifiers
  • scopus:85010934005
ISSN
1600-0889
DOI
10.3402/tellusb.v68.29706
language
English
LU publication?
yes
id
ed7afb91-6064-419b-a1d7-0d9ecba96296
date added to LUP
2019-05-03 13:53:56
date last changed
2022-01-31 19:29:02
@article{ed7afb91-6064-419b-a1d7-0d9ecba96296,
  abstract     = {{<p>Field observations of new particle formation and the subsequent particle growth are typically only possible at a fixed measurement location, and hence do not follow the temporal evolution of an air parcel in a Lagrangian sense. Standard analysis for determining formation and growth rates requires that the time-dependent formation rate and growth rate of the particles are spatially invariant; air parcel advection means that the observed temporal evolution of the particle size distribution at a fixed measurement location may not represent the true evolution if there are spatial variations in the formation and growth rates. Here we present a zerodimensional aerosol box model coupled with one-dimensional atmospheric flow to describe the impact of advection on the evolution of simulated new particle formation events. Wind speed, particle formation rates and growth rates are input parameters that can vary as a function of time and location, using wind speed to connect location to time. The output simulates measurements at a fixed location; formation and growth rates of the particle mode can then be calculated from the simulated observations at a stationary point for different scenarios and be compared with the 'true' input parameters. Hence, we can investigate how spatial variations in the formation and growth rates of new particles would appear in observations of particle number size distributions at a fixed measurement site. We show that the particle size distribution and growth rate at a fixed location is dependent on the formation and growth parameters upwind, even if local conditions do not vary. We also show that different input parameters used may result in very similar simulated measurements. Erroneous interpretation of observations in terms of particle formation and growth rates, and the time span and areal extent of new particle formation, is possible if the spatial effects are not accounted for.</p>}},
  author       = {{Kivekäs, Niku and Carpman, Jimmie and Roldin, Pontus and Leppä, Johannes and O'Connor, Ewan and Kristensson, Adam and Asmi, Eija}},
  issn         = {{1600-0889}},
  keywords     = {{Interpretation of measurements; New particle formation; Spatial variation}},
  language     = {{eng}},
  month        = {{01}},
  number       = {{1}},
  publisher    = {{Taylor & Francis}},
  series       = {{Tellus. Series B: Chemical and Physical Meteorology}},
  title        = {{Coupling an aerosol box model with one-dimensional flow : A tool for understanding observations of new particle formation events}},
  url          = {{http://dx.doi.org/10.3402/tellusb.v68.29706}},
  doi          = {{10.3402/tellusb.v68.29706}},
  volume       = {{68}},
  year         = {{2016}},
}