Dr. Astudillo-Defru, Nicola

2020, Kemmer, J., Stock, S., Kossakowski, D., Kaminski, A., Molaverdikhani, K., Schlecker, M., Caballero, J. A., Amado, P. J., Astudillo-Defru, Nicola, Bonfils, X., Ciardi, David, Collins, Karen A., Espinoza, N., Fukui, A., Hirano, T., Jenkins, J. M., Latham, D. W., Matthews, E. C., Narita, N., Pallé, E., Parviainen, H., Quirrenbach, A., Reiners, A., Ribas, I., Ricker, G., Schlieder, J. E., Seager, S., Vanderspek, R., Winn, J. N., Almenara, José Manuel, Bejar, V. J. S., Bluhm, P., Bouchy, F., Boyd, P., Christiansen, J. L., Cifuentes, C., Cloutier, Ryan, Collins, Kevin I., Cortés Contreras, M., Crossfield, Ian J. M., Crouzet, N., de Leon, J. P., Della Rose, D. D., Delfosse, X., Dreizler, S., Esparza Borges, E., Essack, Z., Forveille, Th., Figueira, P., Galadí Enríquez, D., Gan, T., Glidden, A., Gonzales, E. J., Guerra, P., Harakawa, H., Hatzes, A. P., Henning, Th., Herrero, E., Hodapp, K., Hori, Y., Howell, S. B., Ikoma, M., Isogai, K., Jeffers, S. V., Kürster, M., Kawauchi, K., Kimura, T., Klagyivik, P., Kotani, T., Kurokawa, T., Kusakabe, N., Kuzuhara, M., Lafarga, M., Livingston, J. H., Luque, R., Matson, R., Morales, J. C., Mori, M., Muirhead, P. S., Murgas, F., Nishikawa, J., Nishiumi, T., Omiya, M., Reffert, S., Rodríguez López, C., Santos, N. C., Schöfer, P., Schwarz, R. P., Shiao, B., Tamura, M., Terada, Y., Twicken, J. D., Ueda, A., Vievard, S., Watanabe, N., Zechmeister, M.

We present the confirmation and characterisation of GJ 3473 b (G 50–16, TOI-488.01), a hot Earth-sized planet orbiting an M4 dwarf star, whose transiting signal (P = 1.198 003 5 ± 0.000 001 8 d) was first detected by the Transiting Exoplanet Survey Satellite (TESS). Through a joint modelling of follow-up radial velocity observations with CARMENES, IRD, and HARPS together with extensive ground-based photometric follow-up observations with LCOGT, MuSCAT, and MuSCAT2, we determined a precise planetary mass, Mb = 1.86 ± 0.30 M⊕, and radius, Rb = 1.264 ± 0.050 R⊕. Additionally, we report the discovery of a second, temperate, non-transiting planet in the system, GJ 3473 c, which has a minimum mass, Mc sin i = 7.41 ± 0.91 M⊕, and orbital period, Pc = 15.509 ± 0.033 d. The inner planet of the system, GJ 3473 b, is one of the hottest transiting Earth-sized planets known thus far, accompanied by a dynamical mass measurement, which makes it a particularly attractive target for thermal emission spectroscopy.

2020, Cloutier, Ryan, Eastman, Jason D., Rodríguez, Joseph E., Astudillo-Defru, Nicola, Bonfils, Xavier, Mortier, Annelies, Watson, Christopher A., Stalport, Manu, Pinamonti, Matteo, Lienhard, Florian, Harutyunyan, Avet, Damasso, Mario, Latham, David W., Collins, Karen A., Massey, Robert, Irwin, Jonathan, Winters, Jennifer G., Charbonneau, David, Ziegler, Carl, Matthews, Elisabeth, Crossfield, Ian J. M., Kreidberg, Laura, Quinn, Samuel N., Ricker, George, Vanderspek, Roland, Seager, Sara, Winn, Joshua, Jenkins, Jon M., Vezie, Michael, Udry, Stéphane, Twicken, Joseph D., Tenenbaum, Peter, Sozzetti, Alessandro, Ségransan, Damien, Schlieder, Joshua E., Sasselov, Dimitar, Santos, Nuno C., Rice, Ken, Rackham, Benjamin V., Poretti, Ennio, Piotto, Giampaolo, Phillips, David, Pepe, Francesco, Molinari, Emilio, Mignon, Lucile, Micela, Giuseppina, Melo, Claudio, De Medeiros, José R., Mayor, Michel, Matson, Rachel A., Martínez Fiorenzano, Aldo F., Mann, Andrew W., Magazzú, Antonio, Lovis, Christophe, López-Morales, Mercedes, López, Eric, Lissauer, Jack J., Lépine, Sébastien, Law, Nicholas, Kielkopf, John F., Johnson, John A., Jensen, Eric L. N., Howell, Steve B., Gonzáles, Erica, Ghedina, Adriano, Forveille, Thierry, Figueira, Pedro, Dumusque, Xavier, Dressing, Courtney D., Doyon, René, Díaz, Rodrigo F., Di Fabrizio, Luca, Delfosse, Xavier, Cosentino, Rosario, Conti, Dennis M., Collins, Kevin I., Collier Cameron, Andrew, Ciardi, David, Caldwell, Douglas A., Burke, Christopher, Buchhave, Lars, Briceño, César, Boyd, Patricia, Bouchy, François, Beichman, Charles, Artigau, Étienne, Almenara, José Manuel

We present the confirmation of two new planets transiting the nearby mid-M dwarf LTT 3780 (TIC 36724087, TOI-732, V = 13.07, Ks = 8.204, Rs = 0.374 R⊙, Ms = 0.401 M⊙, d = 22 pc). The two planet candidates are identified in a single Transiting Exoplanet Survey Satellite sector and validated with reconnaissance spectroscopy, ground-based photometric follow-up, and high-resolution imaging. With measured orbital periods of Pb = 0.77, Pc = 12.25 days and sizes rp,b = 1.33 ± 0.07, rp,c = 2.30 ± 0.16 R⊕, the two planets span the radius valley in period–radius space around low-mass stars, thus making the system a laboratory to test competing theories of the emergence of the radius valley in that stellar mass regime. By combining 63 precise radial velocity measurements from the High Accuracy Radial velocity Planet Searcher (HARPS) and HARPS-N, we measure planet masses of ${m}_{p,b}={2.62}_{-0.46}^{+0.48}$ and ${m}_{p,c}={8.6}_{-1.3}^{+1.6}$ M⊕, which indicates that LTT 3780b has a bulk composition consistent with being Earth-like, while LTT 3780c likely hosts an extended H/He envelope. We show that the recovered planetary masses are consistent with predictions from both photoevaporation and core-powered mass-loss models. The brightness and small size of LTT 3780, along with the measured planetary parameters, render LTT 3780b and c as accessible targets for atmospheric characterization of planets within the same planetary system and spanning the radius valley.

2022, Silverstein, Michele, Schlieder, Joshua, Barclay, Thomas, Hord, Benjamin, Jao, Wei-Chun, Vrijmoet, Eliot, Henry, Todd, Cloutier, Ryan, Kostov, Veselin, Kruse, Ethan, Winters, Jennifer, Irwin, Jonathan, Kane, Stephen, Stassun, Keivan, Huang, Chelsea, Kunimoto, Michelle, Tey, Evan, Vanderburg, Andrew, Astudillo-Defru, Nicola, Bonfils, Xavier, Brasseur, C., Charbonneau, David, Ciardi, David, Collins, Karen, Collins, Kevin, Conti, Dennis, Crossfield, Ian, Daylan, Tansu, Doty, John, Dressing, Courtney, Gilbert, Emily, Horne, Keith, Jenkins, Jon, Latham, David, Mann, Andrew, Matthews, Elisabeth, Paredes, Leonardo, Quinn, Samuel, Ricker, George, Schwarz, Richard, Seager, Sara, Sefako, Ramotholo, Shporer, Avi, Smith, Jeffrey, Stockdale, Christopher, Tan, Thiam-Guan, Torres, Guillermo, Twicken, Joseph, Vanderspek, Roland, Wang, Gavin, Winn, Joshua

We present the Transiting Exoplanet Survey Satellite (TESS) discovery of the LHS 1678 (TOI-696) exoplanet system, comprised of two approximately Earth-sized transiting planets and a likely astrometric brown dwarf orbiting a bright (V J = 12.5, K s = 8.3) M2 dwarf at 19.9 pc. The two TESS-detected planets are of radius 0.70 ± 0.04 R ⊕ and 0.98 ± 0.06 R ⊕ in 0.86 day and 3.69 day orbits, respectively. Both planets are validated and characterized via ground-based follow-up observations. High Accuracy Radial Velocity Planet Searcher RV monitoring yields 97.7 percentile mass upper limits of 0.35 M ⊕ and 1.4 M ⊕ for planets b and c, respectively. The astrometric companion detected by the Cerro Tololo Inter-American Observatory/Small and Moderate Aperture Telescope System 0.9 m has an orbital period on the order of decades and is undetected by other means. Additional ground-based observations constrain the companion to being a high-mass brown dwarf or smaller. Each planet is of unique interest; the inner planet has an ultra-short period, and the outer planet is in the Venus zone. Both are promising targets for atmospheric characterization with the James Webb Space Telescope and mass measurements via extreme-precision radial velocity. A third planet candidate of radius 0.9 ± 0.1 R ⊕ in a 4.97 day orbit is also identified in multicycle TESS data for validation in future work. The host star is associated with an observed gap in the lower main sequence of the Hertzsprung-Russell diagram. This gap is tied to the transition from partially to fully convective interiors in M dwarfs, and the effect of the associated stellar astrophysics on exoplanet evolution is currently unknown. The culmination of these system properties makes LHS 1678 a unique, compelling playground for comparative exoplanet science and understanding the formation and evolution of small, short-period exoplanets orbiting low-mass stars. © 2022. The Author(s). Published by the American Astronomical Society.

2023, Dominic, Oddo, Diana,Dragomir, Brandeker, Alexis, Osborn, Hugh P, Collins, Karen, Stassun, Keivan G., Astudillo-Defru, Nicola, Bieryla, Allyson, Howell- B., Steve, Ciardi, David, Quinn, Samuel, Almenara, Jose, Briceño, César, Collins, Kevin, Colón, Knicole, Conti, Dennis, Crouzet, Nicolas, Furlan, Elise, Gan, Tianjun, Gnilka, Cristal L., Goeke-Es, Robert, González, Erica, Mallory, Harris, Jenkins, Jon, Jensen, Eric, Latham, David, Ley, Nicolás, Lund, Michael, Mann, Andrew, Bob, Massey, Murgas, Felipe, Ricker, George, Relles, Howard, Rowden, Pamela, Schwarz, Richard, Schlieder, Josué, Shporer, Avi, Seager, Sara, Srdoc, Gregor, Torres, Guillermo, Twicken, Joseph, Vanderspek, Roland, Winn, Josué, Ziegler, Carl

The radius valley carries implications for how the atmospheres of small planets form and evolve, but this feature is visible only with highly precise characterizations of many small planets. We present the characterization of nine planets and one planet candidate with both NASA TESS and ESA CHEOPS observations, which adds to the overall population of planets bordering the radius valley. While five of our planets—TOI 118 b, TOI 262 b, TOI 455 b, TOI 560 b, and TOI 562 b—have already been published, we vet and validate transit signals as planetary using follow-up observations for four new TESS planets, including TOI 198 b, TOI 244 b, TOI 444 b, and TOI 470 b. While a three times increase in primary mirror size should mean that one CHEOPS transit yields an equivalent model uncertainty in transit depth as about nine TESS transits in the case that the star is equally as bright in both bands, we find that our CHEOPS transits typically yield uncertainties equivalent to between two and 12 TESS transits, averaging 5.9 equivalent transits. Therefore, we find that while our fits to CHEOPS transits provide overall lower uncertainties on transit depth and better precision relative to fits to TESS transits, our uncertainties for these fits do not always match expected predictions given photon-limited noise. We find no correlations between number of equivalent transits and any physical parameters, indicating that this behavior is not strictly systematic, but rathe might be due to other factors such as in-transit gaps during CHEOPS visits or nonhomogeneous detrending of CHEOPS light curves.