Connecting the dots - III. Nightside cooling and surface friction affect climates of tidally locked terrestrial planets
Abstract
We investigate how nightside cooling and surface friction affect surface temperatures and large-scale circulation for tidally locked Earth-like planets. For each scenario, we vary the orbital period between Prot = 1 and 100 d and capture changes in climate states. We find drastic changes in climate states for different surface friction scenarios. For very efficient surface friction (ts,fric = 0.1 d), the simulations for short rotation periods (Prot ≤ 10 d) show predominantly standing extratropical Rossby waves. These waves lead to climate states with two high-latitude westerly jets and unperturbed meridional direct circulation. In most other scenarios, simulations with short rotation periods exhibit instead dominance by standing tropical Rossby waves. Such climate states have a single equatorial westerly jet, which disrupts direct circulation. Experiments with weak surface friction (ts,fric = 10-100 d) show decoupling between surface temperatures and circulation, which leads to strong cooling of the nightside. The experiment with ts,fric = 100 d assumes climate states with easterly flow (retrograde rotation) for medium and slow planetary rotations Prot = 12-100 d. We show that an increase of nightside cooling efficiency by one order of magnitude compared to the nominal model leads to a cooling of the nightside surface temperatures by 80-100 K. The dayside surface temperatures only drop by 25 K at the same time. The increase in thermal forcing suppresses the formation of extratropical Rossby waves on small planets (RP = 1REarth) in the short rotation period regime (Prot ≤ 10 d).
- Publication:
-
Monthly Notices of the Royal Astronomical Society
- Pub Date:
- September 2016
- DOI:
- 10.1093/mnras/stw1265
- arXiv:
- arXiv:1605.09545
- Bibcode:
- 2016MNRAS.461.1981C
- Keywords:
-
- methods: numerical;
- planets and satellites: atmospheres;
- planets and satellites: terrestrial planets;
- Astrophysics - Earth and Planetary Astrophysics
- E-Print:
- 25 pages, 21 figures, accepted by MNRAS