Stochastic nucleation processes and substrate abundance explain time-dependent freezing in supercooled droplets

Daniel A. Knopf; Peter A. Alpert; Assaf Zipori; Naama Reicher; Yinon Rudich

doi:10.1038/s41612-020-0106-4

Stochastic nucleation processes and substrate abundance explain time-dependent freezing in supercooled droplets

Daniel A. Knopf, Peter A. Alpert, Assaf Zipori, Naama Reicher, Yinon Rudich

Department of Earth and Planetary Sciences

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Atmospheric immersion freezing (IF), a heterogeneous ice nucleation process where an ice nucleating particle (INP) is immersed in supercooled water, is a dominant ice formation pathway impacting the hydrological cycle and climate. Implementation of IF derived from field and laboratory data in cloud and climate models is difficult due to the high variability in spatio-temporal scales, INP composition, and morphological complexity. We demonstrate that IF can be consistently described by a stochastic nucleation process accounting for uncertainties in the INP surface area. This approach accounts for time-dependent freezing, a wide range of surface areas and challenges phenomenological descriptions typically used to interpret IF. The results have an immediate impact on the current description, interpretation, and experiments of IF and its implementation in models. The findings are in accord with nucleation theory, and thus should hold for any supercooled liquid material that nucleates in contact with a substrate.

Original language	English
Article number	2
Number of pages	9
Journal	npj Climate and Atmospheric Science
Volume	3
Issue number	1
DOIs	https://doi.org/10.1038/s41612-020-0106-4
State	Published Online - 17 Jan 2020

All Science Journal Classification (ASJC) codes

Global and Planetary Change
Environmental Chemistry
Atmospheric Science

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10.1038/s41612-020-0106-4License: CC BY

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title = "Stochastic nucleation processes and substrate abundance explain time-dependent freezing in supercooled droplets",

abstract = "Atmospheric immersion freezing (IF), a heterogeneous ice nucleation process where an ice nucleating particle (INP) is immersed in supercooled water, is a dominant ice formation pathway impacting the hydrological cycle and climate. Implementation of IF derived from field and laboratory data in cloud and climate models is difficult due to the high variability in spatio-temporal scales, INP composition, and morphological complexity. We demonstrate that IF can be consistently described by a stochastic nucleation process accounting for uncertainties in the INP surface area. This approach accounts for time-dependent freezing, a wide range of surface areas and challenges phenomenological descriptions typically used to interpret IF. The results have an immediate impact on the current description, interpretation, and experiments of IF and its implementation in models. The findings are in accord with nucleation theory, and thus should hold for any supercooled liquid material that nucleates in contact with a substrate.",

author = "Knopf, {Daniel A.} and Alpert, {Peter A.} and Assaf Zipori and Naama Reicher and Yinon Rudich",

note = "This work was funded by the U.S. Department of Energy, Office of Science (BER), Atmospheric System Research (DE-SC0016370) and NASA award NNX17AJ12G. This work was partly funded by the Ice Nuclei Research Unit (INUIT) of the German DFG, and Israel Science Foundation (grant #213/16). Y.R. and N.R. acknowledge the support from The Helen Kimmel Center for Planetary Sciences, and the de Botton Center for Marine Sciences. P.A. acknowledges support from the European Union{\textquoteright}s Horizon 2020 research and innovation program under the Marie Sk{\l}odowska-Curie grant agreement No. 701647. Contributions A.Z. conducted ice nucleation experiments and analyses. P.A.A. developed ice nucleation simulation and performed data analyses. N.R. developed the WISDOM setup and contributed to the discussion, D.A.K. and Y.R. oversaw this project, envisioned analyses, and led the writing of the manuscript. All authors contributed to the writing of the manuscript.",

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T1 - Stochastic nucleation processes and substrate abundance explain time-dependent freezing in supercooled droplets

AU - Knopf, Daniel A.

AU - Alpert, Peter A.

AU - Zipori, Assaf

AU - Reicher, Naama

AU - Rudich, Yinon

N1 - This work was funded by the U.S. Department of Energy, Office of Science (BER), Atmospheric System Research (DE-SC0016370) and NASA award NNX17AJ12G. This work was partly funded by the Ice Nuclei Research Unit (INUIT) of the German DFG, and Israel Science Foundation (grant #213/16). Y.R. and N.R. acknowledge the support from The Helen Kimmel Center for Planetary Sciences, and the de Botton Center for Marine Sciences. P.A. acknowledges support from the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No. 701647. Contributions A.Z. conducted ice nucleation experiments and analyses. P.A.A. developed ice nucleation simulation and performed data analyses. N.R. developed the WISDOM setup and contributed to the discussion, D.A.K. and Y.R. oversaw this project, envisioned analyses, and led the writing of the manuscript. All authors contributed to the writing of the manuscript.

PY - 2020/1/17

Y1 - 2020/1/17

N2 - Atmospheric immersion freezing (IF), a heterogeneous ice nucleation process where an ice nucleating particle (INP) is immersed in supercooled water, is a dominant ice formation pathway impacting the hydrological cycle and climate. Implementation of IF derived from field and laboratory data in cloud and climate models is difficult due to the high variability in spatio-temporal scales, INP composition, and morphological complexity. We demonstrate that IF can be consistently described by a stochastic nucleation process accounting for uncertainties in the INP surface area. This approach accounts for time-dependent freezing, a wide range of surface areas and challenges phenomenological descriptions typically used to interpret IF. The results have an immediate impact on the current description, interpretation, and experiments of IF and its implementation in models. The findings are in accord with nucleation theory, and thus should hold for any supercooled liquid material that nucleates in contact with a substrate.

AB - Atmospheric immersion freezing (IF), a heterogeneous ice nucleation process where an ice nucleating particle (INP) is immersed in supercooled water, is a dominant ice formation pathway impacting the hydrological cycle and climate. Implementation of IF derived from field and laboratory data in cloud and climate models is difficult due to the high variability in spatio-temporal scales, INP composition, and morphological complexity. We demonstrate that IF can be consistently described by a stochastic nucleation process accounting for uncertainties in the INP surface area. This approach accounts for time-dependent freezing, a wide range of surface areas and challenges phenomenological descriptions typically used to interpret IF. The results have an immediate impact on the current description, interpretation, and experiments of IF and its implementation in models. The findings are in accord with nucleation theory, and thus should hold for any supercooled liquid material that nucleates in contact with a substrate.

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DO - 10.1038/s41612-020-0106-4

M3 - مقالة

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JF - npj Climate and Atmospheric Science

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Stochastic nucleation processes and substrate abundance explain time-dependent freezing in supercooled droplets

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