TY - JOUR
T1 - Unsteady bipolar diffusion charging in aerosol neutralisers
T2 - A non-dimensional approach to predict charge distribution equilibrium behaviour
AU - de La Verpilliere, Jean L.
AU - Swanson, Jacob J.
AU - Boies, Adam M.
N1 - Publisher Copyright:
© 2015 The Authors.
PY - 2015/8/1
Y1 - 2015/8/1
N2 - High total particle concentration and small particle size are common features of aerosols encountered in the field of aerosol-based nanotechnology that can potentially lead to non-equilibrium issues in the neutraliser upon SMPS characterisation, resulting in large errors in size distribution measurements. Experiments show that the commonly assumed n{dot operator}. t product rule fails to predict equilibrium behaviour in aerosol neutralisers under these conditions, as it does not capture the influence of total particle concentration and particle size. The aim of this work is to provide an equilibrium indicator that identifies situations where equilibrium is not reached in the neutraliser as a function of residence time, ion generation rate, total particle concentration, and particle size. Bipolar diffusion charging equations are solved numerically in a one-dimensional model first, and a non-dimensional analysis of the results is carried out in order to map equilibrium behaviour as a function of two non-dimensional groups, the non-dimensional ion concentration, and the non-dimensional neutraliser residence time. Solving the three-dimensional form of the charging equations in the geometry of the neutraliser then enables one to find good agreement in terms of equilibrium behaviour between experiments and predictions from the non-dimensional model. The three-dimensional model captures the complexity of the physics of unsteady particle charging inside a neutraliser. This work then discusses this as a new approach to non-equilibrium behaviour prediction in neutralisers, providing a tool supplementing the n{dot operator}. t product rule that can be used in practice.
AB - High total particle concentration and small particle size are common features of aerosols encountered in the field of aerosol-based nanotechnology that can potentially lead to non-equilibrium issues in the neutraliser upon SMPS characterisation, resulting in large errors in size distribution measurements. Experiments show that the commonly assumed n{dot operator}. t product rule fails to predict equilibrium behaviour in aerosol neutralisers under these conditions, as it does not capture the influence of total particle concentration and particle size. The aim of this work is to provide an equilibrium indicator that identifies situations where equilibrium is not reached in the neutraliser as a function of residence time, ion generation rate, total particle concentration, and particle size. Bipolar diffusion charging equations are solved numerically in a one-dimensional model first, and a non-dimensional analysis of the results is carried out in order to map equilibrium behaviour as a function of two non-dimensional groups, the non-dimensional ion concentration, and the non-dimensional neutraliser residence time. Solving the three-dimensional form of the charging equations in the geometry of the neutraliser then enables one to find good agreement in terms of equilibrium behaviour between experiments and predictions from the non-dimensional model. The three-dimensional model captures the complexity of the physics of unsteady particle charging inside a neutraliser. This work then discusses this as a new approach to non-equilibrium behaviour prediction in neutralisers, providing a tool supplementing the n{dot operator}. t product rule that can be used in practice.
KW - Bipolar diffusion charging
KW - Nanotechnology
KW - Neutraliser
KW - Non-equilibrium
KW - N{dot operator}t product rule
KW - Size distribution measurement
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U2 - 10.1016/j.jaerosci.2015.03.006
DO - 10.1016/j.jaerosci.2015.03.006
M3 - Article
AN - SCOPUS:84928734690
SN - 0021-8502
VL - 86
SP - 55
EP - 68
JO - Journal of Aerosol Science
JF - Journal of Aerosol Science
ER -