A numerical study of aerosol influence on mixed-phase stratiform clouds through modulation of the liquid phase

Abstract: Numerical simulations were carried out in a high-resolution two-dimensional framework to increase our understanding of aerosol indirect effects in mixed-phase stratiform clouds. Aerosol characteristics explored include insoluble particle type, soluble mass fraction, influence of aerosol-induced freezing point depression and influence of aerosol number concentration. Simulations were analyzed with a focus on the processes related to liquid phase microphysics, and ice formation was limited to droplet freezing. O… Show more

“…The same "high CCN" and "low CCN" cases, with the same initial conditions, were run with different criteria for heterogeneous freezing. Assuming freezing can only occur above water saturation, as in previous studies by de Boer et al (2010) and as observed by Ansmann et al (2008), shows no suppression of ice formation. The number concentration of ice in the "high CCN" and "low CCN" cases is the same.…”

“…However their explanation of this effect differs from the one put forward here. de Boer et al (2013) explain that the reduction in ice formation in their simulations performed with high CCN concentrations is due to a reduction in drop vol-ume, similar to the Twomey effect (Twomey, 1974). The immersion freezing parameterisation that de Boer employ is a function of drop volume and the production of ice particles through immersion freezing decreases as drop volume decreases.…”

“…Even with Morrison et al (2012)'s insight into the nature of mixed-phase Arctic clouds the ability of climate models to simulate them is lacking (Ovchinnikov et al, 2014). More research is required to fully understand the many ways aerosol composition and size distribution can influence mixed-phase clouds (de Boer et al, 2013). The number of ice crystals and liquid drops present in a cloud strongly depends on the size distribution of aerosols (Twomey, 1991;Andreae and Rosenfeld, 2008).…”

“…Therefore the competition effect needs to be addressed within the models which use these ice nucleation parameterisations. Modelling studies such as that by de Boer et al (2013) do consider the concentration of CCN as having an influence on ice formation in clouds and show that higher concentrations of CCN can reduce ice number concentration. However their explanation of this effect differs from the one put forward here.…”

“…In the literature, immersion freezing (which is a type or "mode" of freezing nucleation) has been confined to those particles that have activated in cloud drops (Hoose et al, 2010a;Pruppacher and Klett, 1997) or those drops greater than 2 µm in diameter (Paukert and Hoose, 2014). Diehl and Wurzler (2004) use a water activity, similar to the Koop et al (2000) approach, to calculate the amount of condensed water required to overcome the freezing point depression caused by soluble compounds present as an internal mixture within the INP. However de Boer et al 2013found that the freezing point depression due to soluble compounds was not important for large cloud droplets such as those found in stratiform clouds, since droplets are large enough to overcome the effect.…”

Competition for water vapour results in suppression of ice formation in mixed-phase clouds

“…The same "high CCN" and "low CCN" cases, with the same initial conditions, were run with different criteria for heterogeneous freezing. Assuming freezing can only occur above water saturation, as in previous studies by de Boer et al (2010) and as observed by Ansmann et al (2008), shows no suppression of ice formation. The number concentration of ice in the "high CCN" and "low CCN" cases is the same.…”

“…However their explanation of this effect differs from the one put forward here. de Boer et al (2013) explain that the reduction in ice formation in their simulations performed with high CCN concentrations is due to a reduction in drop vol-ume, similar to the Twomey effect (Twomey, 1974). The immersion freezing parameterisation that de Boer employ is a function of drop volume and the production of ice particles through immersion freezing decreases as drop volume decreases.…”

“…Even with Morrison et al (2012)'s insight into the nature of mixed-phase Arctic clouds the ability of climate models to simulate them is lacking (Ovchinnikov et al, 2014). More research is required to fully understand the many ways aerosol composition and size distribution can influence mixed-phase clouds (de Boer et al, 2013). The number of ice crystals and liquid drops present in a cloud strongly depends on the size distribution of aerosols (Twomey, 1991;Andreae and Rosenfeld, 2008).…”

“…Therefore the competition effect needs to be addressed within the models which use these ice nucleation parameterisations. Modelling studies such as that by de Boer et al (2013) do consider the concentration of CCN as having an influence on ice formation in clouds and show that higher concentrations of CCN can reduce ice number concentration. However their explanation of this effect differs from the one put forward here.…”

“…In the literature, immersion freezing (which is a type or "mode" of freezing nucleation) has been confined to those particles that have activated in cloud drops (Hoose et al, 2010a;Pruppacher and Klett, 1997) or those drops greater than 2 µm in diameter (Paukert and Hoose, 2014). Diehl and Wurzler (2004) use a water activity, similar to the Koop et al (2000) approach, to calculate the amount of condensed water required to overcome the freezing point depression caused by soluble compounds present as an internal mixture within the INP. However de Boer et al 2013found that the freezing point depression due to soluble compounds was not important for large cloud droplets such as those found in stratiform clouds, since droplets are large enough to overcome the effect.…”

Competition for water vapour results in suppression of ice formation in mixed-phase clouds

Modeling immersion freezing with aerosol‐dependent prognostic ice nuclei in Arctic mixed‐phase clouds

The atmosphere over sea ice