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1. Low spin-axis variations of circumbinary planets

   https://doi.org/10.1093/mnras/stac2071  

   Chen, Renyi; Li, Gongjie; Tao, Molei (July 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Having a massive moon has been considered as a primary mechanism for stabilized planetary obliquity, an example of which being our Earth. This is, however, not always consistent with the exoplanetary cases. This article details the discovery of an alternative mechanism, namely that planets orbiting around binary stars tend to have low spin-axis variations. This is because the large quadrupole potential of the stellar binary could speed up the planetary orbital precession, and detune the system out of secular spin-orbit resonances. Consequently, habitable zone planets around the stellar binaries in low inclination orbits hold higher potential for regular seasonal changes comparing to their single star analogues. 

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2. The CARMENES search for exoplanets around M dwarfs: Wolf 1069 b: Earth-mass planet in the habitable zone of a nearby, very low-mass star

   https://doi.org/10.1051/0004-6361/202245322  

   Kossakowski, D.; Kürster, M.; Trifonov, T.; Henning, Th.; Kemmer, J.; Caballero, J. A.; Burn, R.; Sabotta, S.; Crouse, J. S.; Fauchez, T. J.; et al (February 2023, Astronomy & Astrophysics)

   We present the discovery of an Earth-mass planet (M_bsini= 1.26 ± 0.21M_⊕) on a 15.6 d orbit of a relatively nearby (d ~9.6 pc) and low-mass (0.167 ± 0.011M_⊙) M5.0 V star, Wolf 1069. Sitting at a separation of 0.0672 ± 0.0014 au away from the host star puts Wolf 1069 b in the habitable zone (HZ), receiving an incident flux ofS= 0.652 ± 0.029S_⊕. The planetary signal was detected using telluric-corrected radial-velocity (RV) data from the CARMENES spectrograph, amounting to a total of 262 spectroscopic observations covering almost four years. There are additional long-period signals in the RVs, one of which we attribute to the stellar rotation period. This is possible thanks to our photometric analysis including new, well-sampled monitoring campaigns undergone with the OSN and TJO facilities that supplement archival photometry (i.e., from MEarth and SuperWASP), and this yielded an updated rotational period range ofP_rot= 150–170 d, with a likely value at 169.3_−3.6^+3.7. The stellar activity indicators provided by the CARMENES spectra likewise demonstrate evidence for the slow rotation period, though not as accurately due to possible factors such as signal aliasing or spot evolution. Our detectability limits indicate that additional planets more massive than one Earth mass with orbital periods of less than 10 days can be ruled out, suggesting that perhaps Wolf 1069 b had a violent formation history. This planet is also the sixth closest Earth-mass planet situated in the conservative HZ, after Proxima Centauri b, GJ 1061 d, Teegarden’s Star c, and GJ 1002 b and c. Despite not transiting, Wolf 1069 b is nonetheless a very promising target for future three-dimensional climate models to investigate various habitability cases as well as for sub-m s⁻¹RV campaigns to search for potential inner sub-Earth-mass planets in order to test planet formation theories. 

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3. Tidal Evolution of the Earth–Moon System with a High Initial Obliquity

   https://doi.org/10.3847/PSJ/ac12d1  

   Ćuk, Matija; Lock, Simon J.; Stewart, Sarah T.; Hamilton, Douglas P. (August 2021, The Planetary Science Journal)

   Abstract A giant-impact origin for the Moon is generally accepted, but many aspects of lunar formation remain poorly understood and debated. Ćuk et al. proposed that an impact that left the Earth–Moon system with high obliquity and angular momentum could explain the Moon’s orbital inclination and isotopic similarity to Earth. In this scenario, instability during the Laplace Plane transition, when the Moon’s orbit transitions from the gravitational influence of Earth’s figure to that of the Sun, would both lower the system’s angular momentum to its present-day value and generate the Moon’s orbital inclination. Recently, Tian & Wisdom discovered new dynamical constraints on the Laplace Plane transition and concluded that the Earth–Moon system could not have evolved from an initial state with high obliquity. Here we demonstrate that the Earth–Moon system with an initially high obliquity can evolve into the present state, and we identify a spin–orbit secular resonance as a key dynamical mechanism in the later stages of the Laplace Plane transition. Some of the simulations by Tian & Wisdom did not encounter this late secular resonance, as their model suppressed obliquity tides and the resulting inclination damping. Our results demonstrate that a giant impact that left Earth with high angular momentum and high obliquity (θ> 61°) is a promising scenario for explaining many properties of the Earth–Moon system, including its angular momentum and obliquity, the geochemistry of Earth and the Moon, and the lunar inclination. 

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4. Can Europa's obliquity help probe its interior structure?

   https://doi.org/10.5194/epsc-dps2025-1704  

   Trinh, Antony; Baland, Rose-Marie; Van_Hoolst, Tim; Yseboodt, Marie; Margot, Jean-Luc (July 2025, EPSC-DPS)

   Jupiter's icy moon Europa is currently seen as the most habitable world closest to Earth. Data from the space mission Galileo supported the presence of a global subsurface water ocean in direct contact with a rocky mantle, implying possible rock-water processes similar to those occurring on Earth's ocean floor, which is teeming with life. Although Juno can provide occasional glimpses of the Galilean satellites, close-up observations are not expected until the arrival of Europa Clipper and JUICE in the Jovian system. In the meantime, radar astronomy can help expand our understanding of this intriguing ocean world.There are ongoing efforts to determine Europa's obliquity from radar echoes observed with the Goldstone Solar System Radar and the Green Bank Telescope [1]. In this contribution, we will present our latest models for icy moon obliquity and nutations, and demonstrate the need for precise modelling of elastic deformation in the ice shell. We will also investigate possible resonant amplification of the obliquity due to ocean dynamics.This work is financially supported by the Belgian Science Policy Office (BELSPO) through the BRAIN.be-2.0 programme.[1] Margot J.-L., Spin states of Europa and Ganymede, European Geosciences Union General Assembly 2025 

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5. Applying Understanding of Earth Systems, Including Climate Change, to Exploration of Other Ocean Worlds

   https://doi.org/10.5670/oceanog.2021.413  

   Grebmeier, Jacqueline (January 2022, Oceanography)

   Earth’s polar and deep ocean systems and how they are affected by environmental changes provide analogs for understanding key processes acting in other ocean worlds, from physical and geological dynamics to chemical and biological processes. Subglacial lakes in Antarctica that are overlain by multiple kilometers of ice, as well as polar ice shelves underlain by subsurface areas of the ocean, are key sites for studying processes operating at ice-water and rock-ocean interfaces on Earth and on icy worlds. Hydrothermal vents at the seafloor release chemicals that provide energy for life and are also key areas for cross-linked Earth and planetary studies relevant to deep oceans dynamics. The presence of chemosynthetic microbes that are then consumed by multicellular life forms provide an analog for examining the potential existence of life in some subregions within ocean worlds. Here, we discuss the various Earth system processes that may have analogs on other ocean worlds and the benefits of collaborative Earth and planetary science investigations. 

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