Winter Weakening of Titan's Stratospheric Polar Vortices

J Shultis; DW Waugh; AD Toigo; CE Newman; Nicholas A  Teanby; Jason Sharkey

doi:10.3847/PSJ/ac5ea1

Winter Weakening of Titan's Stratospheric Polar Vortices

J Shultis^*, DW Waugh, AD Toigo, CE Newman, Nicholas A Teanby, Jason Sharkey

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

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Abstract

Polar vortices are a prominent feature in Titan's stratosphere. The Cassini mission has provided a detailed view of the breakdown of the northern polar vortex and formation of the southern vortex, but the mission did not observe the full annual cycle of the evolution of the vortices. Here we use a TitanWRF general circulation model simulation of an entire Titan year to examine the full annual cycle of the polar vortices. The simulation reveals a winter weakening of the vortices, with a clear minimum in polar potential vorticity and midlatitude zonal winds between winter solstice and spring equinox. The simulation also produces the observed postfall equinox cooling followed by rapid warming in the upper stratosphere. This warming is due to strong descent and adiabatic heating, which also leads to the formation of an annular potential vorticity structure. The seasonal evolution of the polar vortices is very similar in the two hemispheres, with only small quantitative differences that are much smaller than the seasonal variations, which can be related to Titan's orbital eccentricity. This suggests that any differences between observations of the northern hemisphere vortex in late northern winter and the southern hemisphere vortex in early winter are likely due to the different observation times with respect to solstice, rather than fundamental differences in the polar vortices.

Original language	English
Article number	73
Number of pages	11
Journal	Planetary Science Journal
Volume	3
Issue number	4
Early online date	4 Apr 2022
DOIs	https://doi.org/10.3847/PSJ/ac5ea1
Publication status	E-pub ahead of print - 4 Apr 2022

Bibliographical note

Funding Information:
Now that we have an understanding of how the polar vortex evolves over the span of a Titan year from the simulation, another area of future work is examining the transport of tracers within the model. The observed distributions of photochemical trace gases with mesospheric sources have been linked to transport associated with the polar vortices, i.e., the transport of gases from the mesosphere into and down through the stratosphere within the polar vortices, and the reduced exchange between polar and midlatitudes because of the polar vortex edge. However, it is difficult to quantify this transport from available trace gas observations, and there is again a lack of observations during the middle of winter when the weakening of the vortex is predicted. Thus, it is unknown how the vertical and horizontal transport varies through the polar vortex lifecycle. We plan to include tracers in future simulations in order to quantify this transport. Acknowledgments The authors acknowledge NASA Solar System Workings grant 80NSSC20K0138 for funding support to accomplish this work. A. Toigo also thanks the Johns Hopkins University Applied Physics Laboratory Lawrence R. Hafstad Sabbatical Fellowship for additional funding support for this project. N. A. Teanby and J. Sharkey are funded by the UK Science and Technology Facilities Council. The TitanWRF output is available at https://data.nas.nasa.gov/titangcm/ and the Shar-key et al. (2021) CIRS results are available at https://data. mendeley.com/datasets/wn8j8f8ck7/1.

Publisher Copyright:
© 2022. The Author(s). Published by the American Astronomical Society.

Keywords

Atmospheric science
Planetary atmospheres
Atmospheric circulation
Titan
Saturnian satellites
Stratosphere

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Planetary Science at Bristol
Elliott, T. (Principal Investigator)
1/04/18 → 28/02/22
Project: Research
Research into planetary formation at Bristol.
Elliott, T. (Principal Investigator)
1/04/15 → 28/02/19
Project: Research

Cite this

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title = "Winter Weakening of Titan's Stratospheric Polar Vortices",

abstract = "Polar vortices are a prominent feature in Titan's stratosphere. The Cassini mission has provided a detailed view of the breakdown of the northern polar vortex and formation of the southern vortex, but the mission did not observe the full annual cycle of the evolution of the vortices. Here we use a TitanWRF general circulation model simulation of an entire Titan year to examine the full annual cycle of the polar vortices. The simulation reveals a winter weakening of the vortices, with a clear minimum in polar potential vorticity and midlatitude zonal winds between winter solstice and spring equinox. The simulation also produces the observed postfall equinox cooling followed by rapid warming in the upper stratosphere. This warming is due to strong descent and adiabatic heating, which also leads to the formation of an annular potential vorticity structure. The seasonal evolution of the polar vortices is very similar in the two hemispheres, with only small quantitative differences that are much smaller than the seasonal variations, which can be related to Titan's orbital eccentricity. This suggests that any differences between observations of the northern hemisphere vortex in late northern winter and the southern hemisphere vortex in early winter are likely due to the different observation times with respect to solstice, rather than fundamental differences in the polar vortices.",

keywords = "Atmospheric science, Planetary atmospheres, Atmospheric circulation, Titan, Saturnian satellites, Stratosphere",

author = "J Shultis and DW Waugh and AD Toigo and CE Newman and Teanby, {Nicholas A} and Jason Sharkey",

note = "Funding Information: Now that we have an understanding of how the polar vortex evolves over the span of a Titan year from the simulation, another area of future work is examining the transport of tracers within the model. The observed distributions of photochemical trace gases with mesospheric sources have been linked to transport associated with the polar vortices, i.e., the transport of gases from the mesosphere into and down through the stratosphere within the polar vortices, and the reduced exchange between polar and midlatitudes because of the polar vortex edge. However, it is difficult to quantify this transport from available trace gas observations, and there is again a lack of observations during the middle of winter when the weakening of the vortex is predicted. Thus, it is unknown how the vertical and horizontal transport varies through the polar vortex lifecycle. We plan to include tracers in future simulations in order to quantify this transport. Acknowledgments The authors acknowledge NASA Solar System Workings grant 80NSSC20K0138 for funding support to accomplish this work. A. Toigo also thanks the Johns Hopkins University Applied Physics Laboratory Lawrence R. Hafstad Sabbatical Fellowship for additional funding support for this project. N. A. Teanby and J. Sharkey are funded by the UK Science and Technology Facilities Council. The TitanWRF output is available at https://data.nas.nasa.gov/titangcm/ and the Shar-key et al. (2021) CIRS results are available at https://data. mendeley.com/datasets/wn8j8f8ck7/1. Publisher Copyright: {\textcopyright} 2022. The Author(s). Published by the American Astronomical Society.",

year = "2022",

month = apr,

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doi = "10.3847/PSJ/ac5ea1",

language = "English",

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journal = "Planetary Science Journal",

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T1 - Winter Weakening of Titan's Stratospheric Polar Vortices

AU - Shultis, J

AU - Waugh, DW

AU - Toigo, AD

AU - Newman, CE

AU - Teanby, Nicholas A

AU - Sharkey, Jason

N1 - Funding Information: Now that we have an understanding of how the polar vortex evolves over the span of a Titan year from the simulation, another area of future work is examining the transport of tracers within the model. The observed distributions of photochemical trace gases with mesospheric sources have been linked to transport associated with the polar vortices, i.e., the transport of gases from the mesosphere into and down through the stratosphere within the polar vortices, and the reduced exchange between polar and midlatitudes because of the polar vortex edge. However, it is difficult to quantify this transport from available trace gas observations, and there is again a lack of observations during the middle of winter when the weakening of the vortex is predicted. Thus, it is unknown how the vertical and horizontal transport varies through the polar vortex lifecycle. We plan to include tracers in future simulations in order to quantify this transport. Acknowledgments The authors acknowledge NASA Solar System Workings grant 80NSSC20K0138 for funding support to accomplish this work. A. Toigo also thanks the Johns Hopkins University Applied Physics Laboratory Lawrence R. Hafstad Sabbatical Fellowship for additional funding support for this project. N. A. Teanby and J. Sharkey are funded by the UK Science and Technology Facilities Council. The TitanWRF output is available at https://data.nas.nasa.gov/titangcm/ and the Shar-key et al. (2021) CIRS results are available at https://data. mendeley.com/datasets/wn8j8f8ck7/1. Publisher Copyright: © 2022. The Author(s). Published by the American Astronomical Society.

PY - 2022/4/4

Y1 - 2022/4/4

N2 - Polar vortices are a prominent feature in Titan's stratosphere. The Cassini mission has provided a detailed view of the breakdown of the northern polar vortex and formation of the southern vortex, but the mission did not observe the full annual cycle of the evolution of the vortices. Here we use a TitanWRF general circulation model simulation of an entire Titan year to examine the full annual cycle of the polar vortices. The simulation reveals a winter weakening of the vortices, with a clear minimum in polar potential vorticity and midlatitude zonal winds between winter solstice and spring equinox. The simulation also produces the observed postfall equinox cooling followed by rapid warming in the upper stratosphere. This warming is due to strong descent and adiabatic heating, which also leads to the formation of an annular potential vorticity structure. The seasonal evolution of the polar vortices is very similar in the two hemispheres, with only small quantitative differences that are much smaller than the seasonal variations, which can be related to Titan's orbital eccentricity. This suggests that any differences between observations of the northern hemisphere vortex in late northern winter and the southern hemisphere vortex in early winter are likely due to the different observation times with respect to solstice, rather than fundamental differences in the polar vortices.

AB - Polar vortices are a prominent feature in Titan's stratosphere. The Cassini mission has provided a detailed view of the breakdown of the northern polar vortex and formation of the southern vortex, but the mission did not observe the full annual cycle of the evolution of the vortices. Here we use a TitanWRF general circulation model simulation of an entire Titan year to examine the full annual cycle of the polar vortices. The simulation reveals a winter weakening of the vortices, with a clear minimum in polar potential vorticity and midlatitude zonal winds between winter solstice and spring equinox. The simulation also produces the observed postfall equinox cooling followed by rapid warming in the upper stratosphere. This warming is due to strong descent and adiabatic heating, which also leads to the formation of an annular potential vorticity structure. The seasonal evolution of the polar vortices is very similar in the two hemispheres, with only small quantitative differences that are much smaller than the seasonal variations, which can be related to Titan's orbital eccentricity. This suggests that any differences between observations of the northern hemisphere vortex in late northern winter and the southern hemisphere vortex in early winter are likely due to the different observation times with respect to solstice, rather than fundamental differences in the polar vortices.

KW - Atmospheric science

KW - Planetary atmospheres

KW - Atmospheric circulation

KW - Titan

KW - Saturnian satellites

KW - Stratosphere

U2 - 10.3847/PSJ/ac5ea1

DO - 10.3847/PSJ/ac5ea1

M3 - Article (Academic Journal)

SN - 2632-3338

VL - 3

JO - Planetary Science Journal

JF - Planetary Science Journal

IS - 4

M1 - 73

ER -

Winter Weakening of Titan's Stratospheric Polar Vortices

Abstract

Bibliographical note

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Planetary Science at Bristol

Research into planetary formation at Bristol.

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