Two warm Neptunes transiting HIP 9618 revealed by <i>TESS</i> and <i>Cheops</i>

Osborn, H.; Nowak, G.; Hébrard, G.; Masseron, T.; Lillo-Box, J.; Πάλλη, Ε.; Bekkelien, A.; Florén, Hans-Gustav; Guterman, P.; Simon, A. E.; Adibekyan, V.; Bieryla, Allyson; Borsato, L.; Brandeker, Alexis; Ciardi, David R.; Cameron, A. Collier; Collins, Karen A.; Egger, J. A.; Gandolfi, D.; Hooton, Matthew J.; Latham, David W.; Lendl, M.; Matthews, Elisabeth C.; Tuson, A.; Ulmer-Moll, S.; Vanderburg, Andrew; Wilson, T. G.; Ziegler, Carl; Alibert, Yann; Alonso, R.; Anglada, Guillem; Arnold, L.; Asquier, J.; Navascués, D. Barrado y; Baumjohann, W.; Beck, T.; Belinski, A. A.; Benz, W.; Biondi, Federico; Boisse, I.; Bonfils, X.; Broeg, C.; Buchhave, Lars A.; Bárczy, T.; Barros, S. C. C.; Cabrera, J.; Guillén, C. Cardona; Carleo, I.; A., Castro-González,; Charnoz, Sébastien; Christiansen, Jessie L.; Cortés-Zuleta, P.; Csizmadia, Szilárd; Dalal, S.; Davies, Melvyn B.; Deleuil, M.; Delfosse, X.; Delrez, Laetitia; Demory, Brice-Olivier; A., Dunlavey,; Ehrenreich, D.; Erikson, A.; Fernandes, Rachel B.; Fortier, A.; Forveille, T.; Fossati, L.; Fridlund, M.; Gillon, M.; Goeke, R.; Goliguzova, Maria V.; Gonzales, Erica J.; Günther, Maximilian N.; Güdel, M.; Heidari, N.; Henze, Christopher E.; Howell, Steve B.; Hoyer, S.; Frey, J. W.; Isaak, K. G.; Jenkins, Jon M.; Kiefer, F.; Kiss, L. L.; Korth, J.; Maxted, P. F. L.; Laskar, Jacques; Étangs, A. Lecavelier des; Lovis, C.; Lund, Michael B.; Luque, R.; Magrin, Demetrio; Almenara, J. M.; Martioli, Eder; Mečina, M.; Medina, Jennifer; Moldovan, Daniel; Morales-Calderón, M.; Morello, Giuseppe; Moutou, C.; Murgas, F.; Jensen, Eric L. N.; Nascimbeni, V.; Olofsson, G.; Ottensamer, R.; Pagano, I.; Peter, G.; Piotto, G.; Pollacco, D.; Queloz, D.; Ragazzoni, Roberto; Rando, N.; Rauer, H.; Ribas, I.; Ricker, G.; Demangeon, O.; Smith, A. M. S.; Santos, N. C.; Scandariato, G.; Seager, Sara; Sousa, S. G.; Steller, M.; Szabó, Gy. M.; Ségransan, D.; Thomas, Nicolas; Udry, S.; Ulmer, B.; Grootel, Valérie Van; Vanderspek, R.; Walton, N. A.; Winn, Joshua N.

doi:10.1093/mnras/stad1319

Cited by 15 publications

(5 citation statements)

References 106 publications

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“…We demonstrated how CHEOPS can be used to followup TESS duotransits to expand the sample of long-period planets. Through the CHEOPS GTO Duos program, we have contributed to the discovery of 6 planets with orbital periods longer than 20 d, radii smaller than 5 R ⊕ , and host stars brighter than G = 12 mag (Osborn et al, 2022(Osborn et al, , 2023Tuson et al, 2023;Ulmer-Moll et al, 2023;Garai et al, 2023). There are only ∼ 18 other planets confirmed by TESS in this parameter space, illustrating the power of the TESS and CHEOPS synergy for the discovery of small, long-period planets transiting bright stars.…”

Section: Discussionmentioning

confidence: 99%

Confirming long-period transiting exoplanets with TESS and CHEOPS. The case of HD 22946 d

Garai,

Osborn,

Tuson

et al. 2024

caosp

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Due to the limited observing duration of the Transiting Exoplanet Survey Satellite (TESS) primary mission, which observed the majority of the near-ecliptic sectors for only 27 days, planets on long periods produce only single transits. However, thanks to its extended mission, TESS re-observed the same fields 2 years later, and in many cases was able to re-detect a second transit. These duotransit cases require follow-up in order to uncover the true orbital period due to the gap, which causes a set of aliases. The Characterising Exoplanet Satellite (CHEOPS) space observatory can be used to follow-up duotransit targets and to determine their true orbital periods and other characteristics. We investigated the HD 22946 planetary system with a similar aim. Based on the combined TESS and CHEOPS observations, we successfully determined the true orbital period of the planet d to be 47.42489 ± 0.00011 d, and derived precise radii of the planets in the system. Planet d, as a warm sub-Neptune, is very interesting because there are only a few similar confirmed exoplanets to date.

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Section: Discussionmentioning

confidence: 99%

Confirming long-period transiting exoplanets with TESS and CHEOPS. The case of HD 22946 d

Garai,

Osborn,

Tuson

et al. 2024

caosp

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“…However, in two cases, we measure only an upper limit on the planet mass. The first, HIP 9618 c, was externally validated and confirmed by Osborn et al (2023) using a combination of TESS and CHEOPS photometry and CAFE, HARPS-N, and SOPHIE RVs (see Section 10.6.2 for details). The second, TOI-554.02 (HD 25463 c) has not yet been confirmed, so we take additional measures to statistically validate this planet.…”

Section: Transit Searchmentioning

confidence: 98%

“…The TOI-669 Keck-NIRC2 observation was taken on 2019 June 9 using the K filter (λ 0 = 2.196 μm and Δλ = 0.336 μm) and an integration time of 10 s. The star appears single, and the Keck-NIRC2 observation rules out companions of Δ7.6 mag at 5σ confidence at a separation of 0 5. Osborn et al (2023) reported the discovery and confirmation of HIP 9618 b and c using space-based photometry from TESS and CHEOPS (Benz et al 2021) along with radial velocity observations from CAFE, HARPS-N, and SOPHIE (Perruchot et al 2008;Cosentino et al 2012;Aceituno et al 2013). To rule out dilution from nearby sources, the authors observed HIP 9618 with a variety of optical speckle and near-infrared (NIR) adaptive optics (AO) instruments, including Keck-NIRC2.…”

Section: Literature Observationsmentioning

confidence: 99%

“…It was not until later that TFOP follow-up revealed these two transits were actually of different depth and duration. To include the 1788 BTJD transit of HIP 9618 b in their analysis, Osborn et al (2023), hereafter O23, re-extracted aperture photometry for HIP 9618 starting from the 2 minute cadence target pixel files. In place of the PDC algorithm, they then use a custom light curve detrending method similar to Vanderburg et al (2019) in order to remove spacecraft systematics.…”

Section: Transit Searchmentioning

confidence: 99%

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The TESS-Keck Survey. XVI. Mass Measurements for 12 Planets in Eight Systems

Akana Murphy,

Batalha,

Scarsdale

et al. 2023

Self Cite

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With JWST’s successful deployment and unexpectedly high fuel reserves, measuring the masses of sub-Neptunes transiting bright, nearby stars will soon become the bottleneck for characterizing the atmospheres of small exoplanets via transmission spectroscopy. Using a carefully curated target list and observations from more than 2 yr of APF-Levy and Keck-HIRES Doppler monitoring, the TESS-Keck Survey is working toward alleviating this pressure. Here we present mass measurements for 11 transiting planets in eight systems that are particularly suited to atmospheric follow-up with JWST. We also report the discovery and confirmation of a temperate super-Jovian-mass planet on a moderately eccentric orbit. The sample of eight host stars, which includes one subgiant, spans early-K to late-F spectral types (T eff = 5200–6200 K). We homogeneously derive planet parameters using a joint photometry and radial velocity modeling framework, discuss the planets’ possible bulk compositions, and comment on their prospects for atmospheric characterization.

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“…Somewhat surprisingly, the number of promising targets in our search area has increased very significantly in the past few years, and 6 out of 9 systems were discovered in 2021 or later. This rapidly increasing rate of discoveries can be devoted to the long observation time basis for planet search (e.g., repeated TESS visits) and the evolution of the observation strategies (e.g., follow-up long-period TESS planet candidates to determine the accurate period, (e.g., [122,[131][132][133]), which help the precise characterization of longperiod transiting planets. The chances of obtaining more and more appropriate candidates within the exomoon search region are increased due to the longer time coverage of the observations and also the better resolution of the full sky with appropriately long and precise observations (as indicated by the arrows in Figure 5.…”

Section: The Insufficiency Of the Catalogsmentioning

confidence: 99%

The “Drake Equation” of Exomoons—A Cascade of Formation, Stability and Detection

Szabó,

Schneider,

Dencs

et al. 2024

Universe

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After 25 years of the prediction of the possibility of observations, and despite the many hundreds of well-studied transiting exoplanet systems, we are still waiting for the announcement of the first confirmed exomoon. We follow the “cascade” structure of the Drake equation but apply it to the chain of events leading to a successful detection of an exomoon. The scope of this paper is to reveal the structure of the problem, rather than to give a quantitative solution. We identify three important steps that can lead us to discovery. The steps are the formation, the orbital dynamics and long-term stability, and the observability of a given exomoon in a given system. This way, the question will be closely related to questions of star formation, planet formation, five possible pathways of moon formation; long-term dynamics of evolved planet systems involving stellar and planetary rotation and internal structure; and the proper evaluation of the observed data, taking the correlated noise of stellar and instrumental origin and the sampling function also into account. We highlight how a successful exomoon observation and the interpretations of the expected further measurements prove to be among the most complex and interdisciplinary questions in astrophysics.

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Two warm Neptunes transiting HIP 9618 revealed by TESS and Cheops

Cited by 15 publications

References 106 publications

Confirming long-period transiting exoplanets with TESS and CHEOPS. The case of HD 22946 d

Confirming long-period transiting exoplanets with TESS and CHEOPS. The case of HD 22946 d

The TESS-Keck Survey. XVI. Mass Measurements for 12 Planets in Eight Systems

The “Drake Equation” of Exomoons—A Cascade of Formation, Stability and Detection

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