Simulation of Heavy Precipitation and the Production of Graupel Related to the Passage of a Cold Front over the Australian Snowy Mountains

Artur Gevorgyan; Luis Ackermann; Yi Huang; Steven Siems; Michael Manton

doi:10.1175/MWR-D-21-0080.1

Simulation of Heavy Precipitation and the Production of Graupel Related to the Passage of a Cold Front over the Australian Snowy Mountains

Artur Gevorgyan, Luis Ackermann, Yi Huang, Steven Siems, Michael Manton

School of Earth Atmosphere and Environment

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

2 Citations (Scopus)

Abstract

The case study of a heavy precipitation event associated with the passage of cold front over the Australian Snowy Mountains (ASM) on 3 August 2018 has been examined using the observational data from an intensive field campaign and high-resolution (1 km) Weather Research and Forecasting (WRF) simulation. We divided this event into prefrontal, cold front, and postfrontal periods. The cold front and postfrontal periods were characterized by higher production of graupel, while relatively low graupel was produced in the prefrontal period. Overall, aggregation along with deposition are likely the main growth mechanisms of snow in the prefrontal clouds, while heavy rain was produced below the melting level over windward slopes of the ASM. The simulated melting level is lower compared to the observations, which is consistent with model cold bias. Stronger orographic uplift and frontal forcing were mainly responsible for the enhanced supercooled liquid water (SLW) production over the ASM in the cold front period. A drop in elevation of the freezing level and increase in low-level relative humidity further enhanced the SLW production. The production of graupel through riming processes was highly efficient in the cold front period given the high concentration of ice-phase hydrometeors in the frontal clouds and the development of clouds comprising supercooled liquid water. The orographic updrafts and embedded convection were the main dynamical processes generating postfrontal SLW clouds and graupel. Ice initiation processes were activated once SLW cloud tops reached 2158C level followed by graupel production through riming processes.

Original language	English
Pages (from-to)	3229-3249
Number of pages	21
Journal	Monthly Weather Review
Volume	150
Issue number	12
DOIs	https://doi.org/10.1175/MWR-D-21-0080.1
Publication status	Published - Dec 2022

Keywords

Cloud microphysics
Mesoscale models
Numerical analysis/modeling

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10.1175/MWR-D-21-0080.1

Cite this

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title = "Simulation of Heavy Precipitation and the Production of Graupel Related to the Passage of a Cold Front over the Australian Snowy Mountains",

abstract = "The case study of a heavy precipitation event associated with the passage of cold front over the Australian Snowy Mountains (ASM) on 3 August 2018 has been examined using the observational data from an intensive field campaign and high-resolution (1 km) Weather Research and Forecasting (WRF) simulation. We divided this event into prefrontal, cold front, and postfrontal periods. The cold front and postfrontal periods were characterized by higher production of graupel, while relatively low graupel was produced in the prefrontal period. Overall, aggregation along with deposition are likely the main growth mechanisms of snow in the prefrontal clouds, while heavy rain was produced below the melting level over windward slopes of the ASM. The simulated melting level is lower compared to the observations, which is consistent with model cold bias. Stronger orographic uplift and frontal forcing were mainly responsible for the enhanced supercooled liquid water (SLW) production over the ASM in the cold front period. A drop in elevation of the freezing level and increase in low-level relative humidity further enhanced the SLW production. The production of graupel through riming processes was highly efficient in the cold front period given the high concentration of ice-phase hydrometeors in the frontal clouds and the development of clouds comprising supercooled liquid water. The orographic updrafts and embedded convection were the main dynamical processes generating postfrontal SLW clouds and graupel. Ice initiation processes were activated once SLW cloud tops reached 2158C level followed by graupel production through riming processes.",

keywords = "Cloud microphysics, Mesoscale models, Numerical analysis/modeling",

author = "Artur Gevorgyan and Luis Ackermann and Yi Huang and Steven Siems and Michael Manton",

note = "Funding Information: Acknowledgments. We thank three anonymous reviewers for their valuable comments and suggestions that significantly improved this manuscript. The research is funded by the Australian Research Council (ARC) Linkage Grant LP160101494. The simulations were undertaken on the NCI national computing facility in Australia. We would also like to thank Snowy Hydro Limited for providing the pluviometer data over the Snowy Mountains and their participation in the field campaign. We are thankful to Dr. Ted Mansell, Dr. Gregory Thompson, and Dr. Hugh Morrison for their valuable suggestions and help related to microphysical tasks. Publisher Copyright: {\textcopyright} 2022 American Meteorological Society.",

year = "2022",

month = dec,

doi = "10.1175/MWR-D-21-0080.1",

language = "English",

volume = "150",

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AU - Siems, Steven

AU - Manton, Michael

N1 - Funding Information: Acknowledgments. We thank three anonymous reviewers for their valuable comments and suggestions that significantly improved this manuscript. The research is funded by the Australian Research Council (ARC) Linkage Grant LP160101494. The simulations were undertaken on the NCI national computing facility in Australia. We would also like to thank Snowy Hydro Limited for providing the pluviometer data over the Snowy Mountains and their participation in the field campaign. We are thankful to Dr. Ted Mansell, Dr. Gregory Thompson, and Dr. Hugh Morrison for their valuable suggestions and help related to microphysical tasks. Publisher Copyright: © 2022 American Meteorological Society.

PY - 2022/12

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N2 - The case study of a heavy precipitation event associated with the passage of cold front over the Australian Snowy Mountains (ASM) on 3 August 2018 has been examined using the observational data from an intensive field campaign and high-resolution (1 km) Weather Research and Forecasting (WRF) simulation. We divided this event into prefrontal, cold front, and postfrontal periods. The cold front and postfrontal periods were characterized by higher production of graupel, while relatively low graupel was produced in the prefrontal period. Overall, aggregation along with deposition are likely the main growth mechanisms of snow in the prefrontal clouds, while heavy rain was produced below the melting level over windward slopes of the ASM. The simulated melting level is lower compared to the observations, which is consistent with model cold bias. Stronger orographic uplift and frontal forcing were mainly responsible for the enhanced supercooled liquid water (SLW) production over the ASM in the cold front period. A drop in elevation of the freezing level and increase in low-level relative humidity further enhanced the SLW production. The production of graupel through riming processes was highly efficient in the cold front period given the high concentration of ice-phase hydrometeors in the frontal clouds and the development of clouds comprising supercooled liquid water. The orographic updrafts and embedded convection were the main dynamical processes generating postfrontal SLW clouds and graupel. Ice initiation processes were activated once SLW cloud tops reached 2158C level followed by graupel production through riming processes.

AB - The case study of a heavy precipitation event associated with the passage of cold front over the Australian Snowy Mountains (ASM) on 3 August 2018 has been examined using the observational data from an intensive field campaign and high-resolution (1 km) Weather Research and Forecasting (WRF) simulation. We divided this event into prefrontal, cold front, and postfrontal periods. The cold front and postfrontal periods were characterized by higher production of graupel, while relatively low graupel was produced in the prefrontal period. Overall, aggregation along with deposition are likely the main growth mechanisms of snow in the prefrontal clouds, while heavy rain was produced below the melting level over windward slopes of the ASM. The simulated melting level is lower compared to the observations, which is consistent with model cold bias. Stronger orographic uplift and frontal forcing were mainly responsible for the enhanced supercooled liquid water (SLW) production over the ASM in the cold front period. A drop in elevation of the freezing level and increase in low-level relative humidity further enhanced the SLW production. The production of graupel through riming processes was highly efficient in the cold front period given the high concentration of ice-phase hydrometeors in the frontal clouds and the development of clouds comprising supercooled liquid water. The orographic updrafts and embedded convection were the main dynamical processes generating postfrontal SLW clouds and graupel. Ice initiation processes were activated once SLW cloud tops reached 2158C level followed by graupel production through riming processes.

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KW - Mesoscale models

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SN - 0027-0644

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JO - Monthly Weather Review

JF - Monthly Weather Review

IS - 12

ER -

Simulation of Heavy Precipitation and the Production of Graupel Related to the Passage of a Cold Front over the Australian Snowy Mountains

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Keywords

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How does orography enhance precipitation in Australian wintertime storms?

ARC Centre of Excellence for Climate Extremes

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Simulation of Heavy Precipitation and the Production of Graupel Related to the Passage of a Cold Front over the Australian Snowy Mountains

Abstract

Keywords

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How does orography enhance precipitation in Australian wintertime storms?

ARC Centre of Excellence for Climate Extremes

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