Fluid Dynamics in Earth and Planetary Sciences (FDEPS)
23rd FDEPS workshop, Nov. 28 - Dec. 1, 2023 at Kansai Seminar House

[English page is here]

第 23 回ワークショップ「地球惑星科学における流体力学」

日程:

2023 年 11 月 28 日(火)〜12 月 1 日(金)

共催:

• Research Institute for Mathematical Sciences (RIMS), Kyoto University (京都大学 数理解析研究所)
• Center for Planetary Science (CPS), Kobe University (神戸大学 惑星科学研究センター)

場所:

関西セミナーハウス
京都市左京区一乗寺竹ノ内町23
TEL:075-711-2115, FAX:075-701-5256

プログラム

講師: Peter L. Read (Professor Emeritus and Senior Researcher, Dept. of Physics, Univ. of Oxford)

• 連続講義と自由討論
  Fast and Slow: Super-rotation Phenomena in Planetary Atmospheres

  Super-rotation is a term that describes the tendency for planetary atmospheres to rotate more rapidly than their underlying planet, either locally or in a global average. Such a tendency can be either quite small relative to the rotation of the planet (e.g. in the case of the Earth) or extremely large, as in slowly rotating planetary bodies such as Venus or Titan. In these lectures we will consider how to define super-rotation more precisely, taking into account the conservation of angular momentum, and will explore the range of dynamical processes that can induce and maintain super-rotation. The role of waves and eddies is crucial in this respect and, amongst other things, limits how much an atmosphere can super-rotate, depending on a range of planetary parameters. We will examine a variety of theoretical ideas and models that provide insights to help understand and even predict the strength and form of atmospheric super-rotation. These are then applied to help interpret observations of real atmospheres, including that of the Earth, other Solar System planets (especially Venus and Titan) and even extrasolar planets.

  • 11/28(火)
    • 14:00 - 17:00 講義 1-a 講義 1-b 講義 1-c 講義 1-d pdf 講義資料1
      Lecture 1. Fundamental concepts
      • How to define “super-rotation” (historical)?
      • Angular momentum and Hide’s “first theorem”
      • Quantifying local and global super-rotation
      • Observations of global and local super-rotation: where do we find it?
      • Role of eddies: Hide’s “second theorem”
      • What is actually mixed by eddies?
    • 夜間:<自由討論>
  • 11/29(水)
    • 9:00 - 12:00 講義 2-a 講義 2-b 講義 2-c pdf 講義資料2
      Lecture 2. Idealized models of super-rotation
      • Held-Hou (1980) model of Hadley circulations
      • Gierasch (1975) & Rossow-Williams (1979) [GRW model]
      • Generalisations of GRW: tides and equatorial waves
      • Wave-mean flow interactions
    • 14:00 - 17:00 講義 3-a 講義 3-b 講義 3-c pdf 講義資料3
      Lecture 3. Super-rotation in more complex systems
      • Super-rotation demonstrated in Laboratory experiments
      • Simplified and Intermediate Complexity GCMs
    • 夜間:<自由討論>
  • 11/30(木)
    • 9:00 - 12:00 講義 4-a 講義 4-b 講義 4-c pdf 講義資料4
      Lecture 4. Super-rotation in observations and realistic models - fast rotators
      • Earth, Mars, Solar System gas and ice giant planets
    • 14:30 - 17:30 講義 5-a 講義 5-b 講義 5-c 講義 5-d pdf 講義資料5
      Lecture 5. Super-rotation in observations and realistic models - Slow rotators
      • Titan, Venus, Hot Jupiters and tidally locked atmospheres
      • Open questions/future?
    • 夜間:<自由討論>
  • 12/1(金) 研究セミナー
    • 09:00 - 11:00 セミナー 1-a セミナー 1-b pdf セミナー資料
      Research Seminar : Equatorial Waves and Superrotation in the Stratosphere of a Titan General Circulation Model

      We investigate the characteristics of equatorial waves associated with the maintenance of superrotation in the stratosphere of a Titan general circulation model. A variety of equatorial waves are present in the model atmosphere, including equatorial Kelvin waves, equatorial Rossby waves, and mixed Rossby-gravity waves. In the upper stratosphere, acceleration of superrotation is strongest around solstice and is due to interaction between equatorial Kelvin waves and Rossby-type waves in winter-hemisphere mid-latitudes. The existence of this ‘Rossby-Kelvin’-type wave appears to depend on strong meridional shear of the background zonal wind that occurs in the upper stratosphere at times away from the equinoxes. In the lower stratosphere, acceleration of superrotation occurs throughout the year and is partially induced by equatorial Rossby waves, which we speculate are generated by quasigeostrophic barotropic instability. Acceleration of superrotation is generally due to waves with phase speeds close to the zonal velocity of the mean flow. Consequently, they have short vertical wavelengths which are close to the model’s vertical grid scale, and therefore are likely to be not properly represented. We suggest this may be a common issue amongst Titan GCMs which should be addressed by future model development.

• 講義の参考文献 PDF
• 講義・休憩風景
• 懇親会(参加者のみ)