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    The Relative Impact of Ice Fall Speeds and Microphysics Parameterization Complexity on Supercell Evolution

    Source: Monthly Weather Review:;2019:;volume 147:;issue 007::page 2403
    Author:
    Falk, Nicholas M.
    ,
    Igel, Adele L.
    ,
    Igel, Matthew R.
    DOI: 10.1175/MWR-D-18-0417.1
    Publisher: American Meteorological Society
    Abstract: AbstractThe use of bin or bulk microphysics schemes in model simulations frequently produces large changes in the simulated storm and precipitation characteristics, but it is still unclear which aspects of these schemes give rise to these changes. In this study, supercell simulations using either a bin or a double-moment bulk microphysics scheme are conducted with the Regional Atmospheric Modeling System (RAMS). The two simulations produce very different storm morphologies. An additional simulation is run for each scheme in which the diameter?fall speed relationships for ice hydrometeors are modified to be similar to those used by the other scheme. When fall speed relationships are homogenized, the two parameterization schemes simulate similar storm morphology. Therefore, despite the use of largely dissimilar approaches to parameterizing microphysics, the difference in storm morphology is found to be related to the choice of diameter?fall speed relationships for ice hydrometeors. This result is investigated further to understand why. Higher fall speeds lead to higher mixing ratios of hydrometeors at low levels and thus more melting. Consequently, stronger downdrafts and cold pools exist in the high fall speed storms, and these stronger cold pools lead to storm splitting and the intensification of a left mover. The results point to the importance of hydrometeor fall speed on the evolution of supercells. It is also suggested that caution be used when comparing the response of a cloud model to different classes of microphysics schemes since the assumptions made by the schemes may be more important than the scheme class itself.
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      The Relative Impact of Ice Fall Speeds and Microphysics Parameterization Complexity on Supercell Evolution

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    contributor authorFalk, Nicholas M.
    contributor authorIgel, Adele L.
    contributor authorIgel, Matthew R.
    date accessioned2019-10-05T06:55:52Z
    date available2019-10-05T06:55:52Z
    date copyright5/6/2019 12:00:00 AM
    date issued2019
    identifier otherMWR-D-18-0417.1.pdf
    identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4263868
    description abstractAbstractThe use of bin or bulk microphysics schemes in model simulations frequently produces large changes in the simulated storm and precipitation characteristics, but it is still unclear which aspects of these schemes give rise to these changes. In this study, supercell simulations using either a bin or a double-moment bulk microphysics scheme are conducted with the Regional Atmospheric Modeling System (RAMS). The two simulations produce very different storm morphologies. An additional simulation is run for each scheme in which the diameter?fall speed relationships for ice hydrometeors are modified to be similar to those used by the other scheme. When fall speed relationships are homogenized, the two parameterization schemes simulate similar storm morphology. Therefore, despite the use of largely dissimilar approaches to parameterizing microphysics, the difference in storm morphology is found to be related to the choice of diameter?fall speed relationships for ice hydrometeors. This result is investigated further to understand why. Higher fall speeds lead to higher mixing ratios of hydrometeors at low levels and thus more melting. Consequently, stronger downdrafts and cold pools exist in the high fall speed storms, and these stronger cold pools lead to storm splitting and the intensification of a left mover. The results point to the importance of hydrometeor fall speed on the evolution of supercells. It is also suggested that caution be used when comparing the response of a cloud model to different classes of microphysics schemes since the assumptions made by the schemes may be more important than the scheme class itself.
    publisherAmerican Meteorological Society
    titleThe Relative Impact of Ice Fall Speeds and Microphysics Parameterization Complexity on Supercell Evolution
    typeJournal Paper
    journal volume147
    journal issue7
    journal titleMonthly Weather Review
    identifier doi10.1175/MWR-D-18-0417.1
    journal fristpage2403
    journal lastpage2415
    treeMonthly Weather Review:;2019:;volume 147:;issue 007
    contenttypeFulltext
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