Add to ORKGWe study the competition of two different freezing mechanisms (homogeneous and heterogeneous freezing) in the same environment for cold cirrus clouds. To this goal we use the recently developed and validated ice microphysics scheme (Spichtinger and Gierens, 2009a) which distinguishes between ice classes according to their formation process. We investigate cases with purely homogeneous ice formation and compare them with cases where background ice nuclei in varying concentration heterogeneously form ice prior to homogeneous nucleation. We perform additionally a couple of sensitivity studies regarding threshold humidity for heterogeneous freezing, uplift speed, and ambient temperature, and we study the influence of random motions ...
Using the numerical cirrus cloud model developed in Part I of this study, the development of cirrus ...
A double–moment bulk microphysics scheme for modelling cirrus clouds including ex-plicit impact of a...
In order to study aerosol–cloud interactions in cirrus clouds, we apply a new multiple-mode ice micr...
International audienceWe study the competition of two different freezing mechanisms (homogeneous and...
In this paper the authors use a simplified approach to describe heterogeneous ice nu-cleation within...
A parametrization of cirrus clouds formed by homogeneous nucleation is improved so that it can be us...
This study presents a comprehensive ice cloud formation parameterization that computes the ice cryst...
[1] Cirrus clouds can form by homogeneous and heterogeneous ice nucleation mechanisms at temperature...
Cirrus ice crystals are produced heterogeneously on ice-nucleating particles (INPs) and homogeneousl...
Homogeneous nucleation of ice crystals via freezing of small supercooled solution particles represen...
At temperatures below 238 K, cirrus clouds can form by homogeneous and heterogeneous ice nucleation ...
International audienceBox model simulations of an uplifting and adiabatically cooling cloud of aeros...
We present a parameterization of cirrus cloud formation that computes the ice crystal number and siz...
This study develops an advanced physically-based parameterization of heterogeneous ice nucleation in...
[1] A physically based parameterization of cirrus cloud formation by heterogeneous freezing is devel...
Using the numerical cirrus cloud model developed in Part I of this study, the development of cirrus ...
A double–moment bulk microphysics scheme for modelling cirrus clouds including ex-plicit impact of a...
In order to study aerosol–cloud interactions in cirrus clouds, we apply a new multiple-mode ice micr...
International audienceWe study the competition of two different freezing mechanisms (homogeneous and...
In this paper the authors use a simplified approach to describe heterogeneous ice nu-cleation within...
A parametrization of cirrus clouds formed by homogeneous nucleation is improved so that it can be us...
This study presents a comprehensive ice cloud formation parameterization that computes the ice cryst...
[1] Cirrus clouds can form by homogeneous and heterogeneous ice nucleation mechanisms at temperature...
Cirrus ice crystals are produced heterogeneously on ice-nucleating particles (INPs) and homogeneousl...
Homogeneous nucleation of ice crystals via freezing of small supercooled solution particles represen...
At temperatures below 238 K, cirrus clouds can form by homogeneous and heterogeneous ice nucleation ...
International audienceBox model simulations of an uplifting and adiabatically cooling cloud of aeros...
We present a parameterization of cirrus cloud formation that computes the ice crystal number and siz...
This study develops an advanced physically-based parameterization of heterogeneous ice nucleation in...
[1] A physically based parameterization of cirrus cloud formation by heterogeneous freezing is devel...
Using the numerical cirrus cloud model developed in Part I of this study, the development of cirrus ...
A double–moment bulk microphysics scheme for modelling cirrus clouds including ex-plicit impact of a...
In order to study aerosol–cloud interactions in cirrus clouds, we apply a new multiple-mode ice micr...