Your search keyword '"Dalba, PA"' showing total 14 results

1. The transit transmission spectrum of a cold gas giant planet

Author

Dalba, PA, Muirhead, PS, Fortney, JJ, Hedman, MM, Nicholson, PD, and Veyette, MJ

Subjects

planetary systems, planets and satellites: atmospheres, planets and satellites: individual, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We use solar occultations observed by the Visual and Infrared Mapping Spectrometer on board the Cassini Spacecraft to extract the 1-5 μm transmission spectrum of Saturn, as if it were a transiting exoplanet. We detect absorption from methane, ethane, acetylene, aliphatic hydrocarbons, and possibly carbon monoxide, with peak-to-peak features of up to 90 parts-per-million despite the presence of ammonia clouds. We also find that atmospheric refraction, as opposed to clouds or haze, determines the minimum altitude that could be probed during mid-transit. Self-consistent exoplanet atmosphere models show good agreement with Saturn's transmission spectrum but fail to reproduce a large absorption feature near 3.4 μm, likely caused by gaseous ethane and a C-H stretching mode of an unknown aliphatic hydrocarbon. This large feature is located in one of the Spitzer Space Telescope bandpasses and could alter interpretations of transmission spectra if not properly modeled. The large signal in Saturn's transmission spectrum suggests that transmission spectroscopy of cold, long-period gaseous exoplanets should be possible with current and future observatories. Motivated by these results, we briefly consider the feasibility of using a survey to search for and characterize cold exoplanets that are analogous to Jupiter and Saturn utilizing a target-of-opportunity approach.

Published

2015

2. Erratum: Giant Outer Transiting Exoplanet Mass (GOT ‘EM) Survey. II. Discovery of a Failed Hot Jupiter on a 2.7 yr, Highly Eccentric Orbit (AJ (2021) 162 (154) DOI: 10.3847/1538-3881/ac134b)

Author

Dalba, PA, Dalba, PA, Kane, SR, Li, Z, MacDougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, Payne, MJ, Dalba, PA, Dalba, PA, Kane, SR, Li, Z, MacDougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, and Payne, MJ

Abstract

In the original analysis by Dalba et al. (2021) to confirm and characterize the Kepler-1704 system, an erroneous offset of 0.53878357713256 day was accidentally subtracted from the time stamps of the photometric measurements of this star acquired by the Kepler spacecraft. This photometry was then used in the comprehensive system modeling that yielded the final ephemeris of this exoplanet. As a result, parameters describing the timing of this planet’s orbit, most notably its conjunction (transit) time, were erroneously offset. This erratum serves to correct this error and the ephemeris of Kepler-1704 b. We added the 0.53878357713256 day offset to the time stamps of the Kepler photometry that was used in the original analysis. The corresponding flux values were unchanged. Besides the time stamps, we did not alter any other data product. We then conducted the joint modeling of the stellar and planetary parameters of the Kepler-1704 system using EXOFASTv2 (Eastman et al. 2019) exactly as described in Section 3 of Dalba et al. (2021). All priors and EXOFASTv2 settings were left as described in the original analysis. This new fit converged following the same criteria applied in the original analysis. We again observed a bimodality in mass and age of Kepler-1704 as described in Section 3.1 of Dalba et al. (2021). We selected the lower stellar mass solution just as before and calculated the updated stellar and planetary parameters, which are listed in Tables 1 and 2, respectively. The only parameter values in Tables 1 and 2 that changed significantly between Dalba et al. (2021) and this analysis are conjunction time (TC), periastron time (TP), and eclipse time (TS). This is expected given that the only change to the inputs to the EXOFASTv2 fit were the time stamps of the Kepler photometry. Changes for other parameters other than those listed above were only due to rounding error or small statistical variations in the Markov chain Monte Carlo analysis, and were all well with

Published

2022

3. Giant Outer Transiting Exoplanet Mass (GOT 'EM) Survey. II. Discovery of a Failed Hot Jupiter on a 2.7 Yr, Highly Eccentric Orbit

Author

Dalba, PA, Dalba, PA, Kane, SR, Li, Z, Macdougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, Payne, MJ, Dalba, PA, Dalba, PA, Kane, SR, Li, Z, Macdougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, and Payne, MJ

Abstract

Radial velocity (RV) surveys have discovered giant exoplanets on au-scale orbits with a broad distribution of eccentricities. Those with the most eccentric orbits are valuable laboratories for testing theories of high-eccentricity migration. However, few such exoplanets transit their host stars, thus removing the ability to apply constraints on formation from their bulk internal compositions. We report the discovery of Kepler-1704 b, a transiting 4.15 M J giant planet on a 988.88 day orbit with an extreme eccentricity of 0.921-0.015+0.010. Our decade-long RV baseline from the Keck I telescope allows us to measure the orbit and bulk heavy-element composition of Kepler-1704 b and place limits on the existence of undiscovered companions. A failed hot Jupiter, Kepler-1704 b was likely excited to high eccentricity by scattering events that possibly began during its gas accretion phase. Its final periastron distance was too large to allow for tidal circularization, so now it orbits its host from distances spanning 0.16-3.9 au. The maximum difference in planetary equilibrium temperature resulting from this elongated orbit is over 700 K. A simulation of the thermal phase curve of Kepler-1704 b during periastron passage demonstrates that it is a remarkable target for atmospheric characterization from the James Webb Space Telescope, which could potentially also measure the planet's rotational period as the hot spot from periastron rotates in and out of view. Continued characterization of the Kepler-1704 system promises to refine theories explaining the formation of hot Jupiters and cool giant planets like those in the solar system.

Published

2021

4. Giant outer transiting exoplanet mass (GOT 'EM) survey. I. Confirmation of an eccentric, cool jupiter with an interior earth-sized planet orbiting kepler-1514

Author

Dalba, PA, Dalba, PA, Kane, SR, Isaacson, H, Giacalone, S, Howard, AW, Rodriguez, JE, Vanderburg, A, Eastman, JD, Kraus, AL, Dupuy, TJ, Weiss, LM, Schwieterman, EW, Dalba, PA, Dalba, PA, Kane, SR, Isaacson, H, Giacalone, S, Howard, AW, Rodriguez, JE, Vanderburg, A, Eastman, JD, Kraus, AL, Dupuy, TJ, Weiss, LM, and Schwieterman, EW

Abstract

Despite the severe bias of the transit method of exoplanet discovery toward short orbital periods, a modest sample of transiting exoplanets with orbital periods greater than 100 days is known. Long-term radial velocity (RV) surveys are pivotal to confirming these signals and generating a set of planetary masses and densities for planets receiving moderate to low irradiation from their host stars. Here we conduct RV observations of Kepler-1514 from the Keck I telescope using the High Resolution Echelle Spectrometer. From these data, we measure the mass of the statistically validated giant (1.108 ± 0.023 RJ) exoplanet Kepler-1514 b with a 218-day orbital period as 5.28 ± 0.22MJ. The bulk density of this cool (~390 K) giant planet is -4.82+0.26-0.25g cm-3, consistent with a core supported by electron degeneracy pressure. We also infer an orbital eccentricity of 0.401+0.013-0.014 from the RV and transit observations, which is consistent with planet-planet scattering and disk cavity migration models. The Kepler-1514 system contains an Earth-size, Kepler Object of Interest on a 10.5-day orbit that we statistically validate against false-positive scenarios, including those involving a neighboring star. The combination of the brightness (V = 11.8) of the host star and the long period, low irradiation, and high density of Kepler-1514 b places this system among a rare group of known exoplanetary systems and as one that is amenable to continued study.

Published

2021

5. The TESS-Keck Survey. I. A Warm Sub-Saturn-mass Planet and a Caution about Stray Light in TESS Cameras

Author

Dalba, PA, Dalba, PA, Gupta, AF, Rodriguez, JE, Dragomir, D, Huang, CX, Kane, SR, Quinn, SN, Bieryla, A, Esquerdo, GA, Fulton, BJ, Scarsdale, N, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dressing, CD, Giacalone, S, Hill, ML, Hirsch, LA, Howard, AW, Huber, D, Isaacson, H, Kosiarek, M, Lubin, J, Mayo, AW, Mocnik, T, Akana Murphy, JM, Petigura, EA, Robertson, P, Rosenthal, LJ, Roy, A, Rubenzahl, RA, Van Zandt, J, Weiss, LM, Knudstrup, E, Andersen, MF, Grundahl, F, Yao, X, Pepper, J, Villanueva, S, Ciardi, DR, Cloutier, R, Jacobs, TL, Kristiansen, MH, Lacourse, DM, Lendl, M, Osborn, HP, Palle, E, Stassun, KG, Stevens, DJ, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Daylan, T, Fong, W, Goeke, RF, Rose, ME, Rowden, P, Schlieder, JE, Smith, JC, Vanderburg, A, Dalba, PA, Dalba, PA, Gupta, AF, Rodriguez, JE, Dragomir, D, Huang, CX, Kane, SR, Quinn, SN, Bieryla, A, Esquerdo, GA, Fulton, BJ, Scarsdale, N, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dressing, CD, Giacalone, S, Hill, ML, Hirsch, LA, Howard, AW, Huber, D, Isaacson, H, Kosiarek, M, Lubin, J, Mayo, AW, Mocnik, T, Akana Murphy, JM, Petigura, EA, Robertson, P, Rosenthal, LJ, Roy, A, Rubenzahl, RA, Van Zandt, J, Weiss, LM, Knudstrup, E, Andersen, MF, Grundahl, F, Yao, X, Pepper, J, Villanueva, S, Ciardi, DR, Cloutier, R, Jacobs, TL, Kristiansen, MH, Lacourse, DM, Lendl, M, Osborn, HP, Palle, E, Stassun, KG, Stevens, DJ, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Daylan, T, Fong, W, Goeke, RF, Rose, ME, Rowden, P, Schlieder, JE, Smith, JC, and Vanderburg, A

Abstract

We report the detection of a Saturn-size exoplanet orbiting HD 332231 (TOI 1456) in light curves from the Transiting Exoplanet Survey Satellite (TESS). HD 332231 - an F8 dwarf star with a V-band magnitude of 8.56 - was observed by TESS in Sectors 14 and 15. We detect a single-transit event in the Sector 15 presearch data conditioning (PDC) light curve. We obtain spectroscopic follow-up observations of HD 332231 with the Automated Planet Finder, Keck I, and SONG telescopes. The orbital period we infer from radial velocity (RV) observations leads to the discovery of another transit in Sector 14 that was masked by PDC due to scattered light contamination. A joint analysis of the transit and RV data confirms the planetary nature of HD 332231 b, a Saturn-size (0.867-0.025+0.027RJ), sub-Saturn-mass (0.244±0.021MJ) exoplanet on a 18.71 day circular orbit. The low surface gravity of HD 332231 b and the relatively low stellar flux it receives make it a compelling target for transmission spectroscopy. Also, the stellar obliquity is likely measurable via the Rossiter-McLaughlin effect, an exciting prospect given the 0.14 au orbital separation of HD 332231 b. The spectroscopic observations do not provide substantial evidence for any additional planets in the HD 332231 system, but continued RV monitoring is needed to further characterize this system. We also predict that the frequency and duration of masked data in the PDC light curves for TESS Sectors 14-16 could hide transits of some exoplanets with orbital periods between 10.5 and 17.5 days.

Published

2020

6. The Lick Observatory Supernova Search follow-up program: photometry data release of 70 SESNe

Author

Zheng, WK, Zheng, WK, Stahl, BE, De Jaeger, T, Filippenko, AV, Wang, SQ, Gan, WP, Brink, TG, Altunin, I, Baer-Way, R, Bigley, A, Blanchard, K, Blanchard, PK, Bradley, J, Cargill, SK, Casper, C, Chapman, T, Chander, V, Channa, S, Choi, BY, Choksi, N, Chu, M, Clubb, KI, Cohen, DP, Dalba, PA, Degraw, A, De Kouchkovsky, M, Ellison, M, Falcon, E, Fox, OD, Fuller, K, Ganeshalingam, M, Girish, N, Gould, C, Halevi, G, Halle, A, Hayakawa, KT, Hardy, R, Hestenes, J, Hoffman, AM, Hyland, M, Jeffers, BT, Jennings, C, Kandrashoff, MT, Khodanian, A, Kim, M, Kim, H, Kislak, ME, Krishnan, D, Kumar, S, Kumar, SG, Leja, J, Leonard, EJ, Li, GZ, Li, W, Lian, JS, Liu, E, Lowe, TB, Lu, P, Ma, E, Mason, MN, May, M, McAllister, K, McGinness, E, Modak, S, Molloy, J, Murakami, YS, Nayak, O, Perera, D, Pina, K, Punjabi, D, Rikhter, A, Ross, TW, Sipple, J, Soler, C, Stegman, S, Stephens, H, Sunseri, J, Tang, K, Taylor, S, Thrasher, P, Van Dyk, SD, Wang, XG, Wayland, J, Wilkins, A, Yagubyan, A, Yuk, H, Yunus, S, Zhang, KD, Zheng, WK, Zheng, WK, Stahl, BE, De Jaeger, T, Filippenko, AV, Wang, SQ, Gan, WP, Brink, TG, Altunin, I, Baer-Way, R, Bigley, A, Blanchard, K, Blanchard, PK, Bradley, J, Cargill, SK, Casper, C, Chapman, T, Chander, V, Channa, S, Choi, BY, Choksi, N, Chu, M, Clubb, KI, Cohen, DP, Dalba, PA, Degraw, A, De Kouchkovsky, M, Ellison, M, Falcon, E, Fox, OD, Fuller, K, Ganeshalingam, M, Girish, N, Gould, C, Halevi, G, Halle, A, Hayakawa, KT, Hardy, R, Hestenes, J, Hoffman, AM, Hyland, M, Jeffers, BT, Jennings, C, Kandrashoff, MT, Khodanian, A, Kim, M, Kim, H, Kislak, ME, Krishnan, D, Kumar, S, Kumar, SG, Leja, J, Leonard, EJ, Li, GZ, Li, W, Lian, JS, Liu, E, Lowe, TB, Lu, P, Ma, E, Mason, MN, May, M, McAllister, K, McGinness, E, Modak, S, Molloy, J, Murakami, YS, Nayak, O, Perera, D, Pina, K, Punjabi, D, Rikhter, A, Ross, TW, Sipple, J, Soler, C, Stegman, S, Stephens, H, Sunseri, J, Tang, K, Taylor, S, Thrasher, P, Van Dyk, SD, Wang, XG, Wayland, J, Wilkins, A, Yagubyan, A, Yuk, H, Yunus, S, and Zhang, KD

Abstract

We present BVRI and unfiltered (Clear) light curves of 70 stripped-envelope supernovae (SESNe), observed between 2003 and 2020, from the Lick Observatory Supernova Search follow-up program. Our SESN sample consists of 19 spectroscopically normal SNe Ib, 2 peculiar SNe Ib, six SNe Ibn, 14 normal SNe Ic, 1 peculiar SN Ic, 10 SNe Ic-BL, 15 SNe IIb, 1 ambiguous SN IIb/Ib/c, and 2 superluminous SNe. Our follow-up photometry has (on a per-SN basis) a mean coverage of 81 photometric points (median of 58 points) and a mean cadence of 3.6 d (median of 1.2 d). From our full sample, a subset of 38 SNe have pre-maximum coverage in at least one passband, allowing for the peak brightness of each SN in this subset to be quantitatively determined. We describe our data collection and processing techniques, with emphasis toward our automated photometry pipeline, from which we derive publicly available data products to enable and encourage further study by the community. Using these data products, we derive host-galaxy extinction values through the empirical colour evolution relationship and, for the first time, produce accurate rise-time measurements for a large sample of SESNe in both optical and infrared passbands. By modelling multiband light curves, we find that SNe Ic tend to have lower ejecta masses and lower ejecta velocities than SNe Ib and IIb, but higher 56Ni masses.

Published

2022

7. Toi-1235 b: A keystone super-earth for testing radius valley emergence models around early m dwarfs

Author

Cloutier, R, Rodriguez, JE, Irwin, J, Charbonneau, D, Stassun, KG, Mortier, A, Latham, DW, Isaacson, H, Howard, AW, Udry, S, Wilson, TG, Watson, CA, Pinamonti, M, Lienhard, F, Giacobbe, P, Guerra, P, Collins, KA, Beiryla, A, Esquerdo, GA, Matthews, E, Matson, RA, Howell, SB, Furlan, E, Crossfield, IJM, Winters, JG, Nava, C, Ment, K, Lopez, ED, Ricker, G, Vanderspek, R, Seager, S, Jenkins, JM, Ting, EB, Tenenbaum, P, Sozzetti, A, Sha, L, Ségransan, D, Schlieder, JE, Sasselov, D, Roy, A, Robertson, P, Rice, K, Poretti, E, Piotto, G, Phillips, D, Pepper, J, Pepe, F, Molinari, E, Mocnik, T, Micela, G, Mayor, M, Martinez Fiorenzano, AF, Mallia, F, Lubin, J, Lovis, C, López-Morales, M, Kosiarek, MR, Kielkopf, JF, Kane, Jensen, ELN, Isopi, G, Huber, D, Hill, ML, Harutyunyan, A, Gonzales, E, Giacalone, S, Ghedina, A, Ercolino, A, Dumusque, X, Dressing, CD, Damasso, M, Dalba, PA, Cosentino, R, Conti, DM, Colón, KD, Collins, KI, Cameron, AC, Ciardi, D, Christiansen, J, Chontos, A, Cecconi, M, Caldwell, DA, Burke, C, Buchhave, L, Beichman, C, Behmard, A, Beard, C, Akana Murphy, JM, Cloutier, R [0000-0001-5383-9393], Rodriguez, JE [0000-0001-8812-0565], Charbonneau, D [0000-0002-9003-484X], Stassun, KG [0000-0002-3481-9052], Mortier, A [0000-0001-7254-4363], Latham, DW [0000-0001-9911-7388], Isaacson, H [0000-0002-0531-1073], Howard, AW [0000-0001-8638-0320], Udry, S [0000-0001-7576-6236], Collins, KA [0000-0001-6588-9574], Beiryla, A [0000-0001-6637-5401], Esquerdo, GA [0000-0002-9789-5474], Matthews, E [0000-0003-0593-1560], Matson, RA [0000-0001-7233-7508], Howell, SB [0000-0002-2532-2853], Winters, JG [0000-0001-6031-9513], Nava, C [0000-0001-8838-3883], Ment, K [0000-0001-5847-9147], Ricker, G [0000-0003-2058-6662], Vanderspek, R [0000-0001-6763-6562], Seager, S [0000-0002-6892-6948], Jenkins, JM [0000-0002-4715-9460], Ting, EB [0000-0002-8219-9505], Tenenbaum, P [0000-0002-1949-4720], Sozzetti, A [0000-0002-7504-365X], Sha, L [0000-0001-5401-8079], Ségransan, D [0000-0003-2355-8034], Schlieder, JE [0000-0001-5347-7062], Sasselov, D [0000-0001-7014-1771], Roy, A [0000-0001-8127-5775], Robertson, P [0000-0003-0149-9678], Poretti, E [0000-0003-1200-0473], Piotto, G [0000-0002-9937-6387], Pepper, J [0000-0002-3827-8417], Molinari, E [0000-0002-1742-7735], Mocnik, T [0000-0003-4603-556X], Micela, G [0000-0002-9900-4751], Lubin, J [0000-0001-8342-7736], López-Morales, M [0000-0003-3204-8183], Kielkopf, JF [0000-0003-0497-2651], Kane, SR [0000-0002-7084-0529], Jensen, ELN [0000-0002-4625-7333], Huber, D [0000-0001-8832-4488], Hill, ML [0000-0002-0139-4756], Giacalone, S [0000-0002-8965-3969], Ghedina, A [0000-0003-4702-5152], Dumusque, X [0000-0002-9332-2011], Dressing, CD [0000-0001-8189-0233], Dalba, PA [0000-0002-4297-5506], Cosentino, R [0000-0003-1784-1431], Conti, DM [0000-0003-2239-0567], Colón, KD [0000-0001-8020-7121], Collins, KI [0000-0003-2781-3207], Ciardi, D [0000-0002-5741-3047], Christiansen, J [0000-0002-8035-4778], Chontos, A [0000-0003-1125-2564], Caldwell, DA [0000-0003-1963-9616], Burke, C [0000-0002-7754-9486], Buchhave, L [0000-0003-1605-5666], Behmard, A [0000-0003-0012-9093], Beard, C [0000-0001-7708-2364], Akana Murphy, JM [0000-0001-8898-8284], and Apollo - University of Cambridge Repository

Subjects

Radial velocity, Exoplanet formation, Transit photometry, M dwarf stars, Exoplanet structure

Abstract

Small planets on close-in orbits tend to exhibit envelope mass fractions of either effectively zero or up to a few percent depending on their size and orbital period. Models of thermally-driven atmospheric mass loss and of terrestrial planet formation in a gas-poor environment make distinct predictions regarding the location of this rocky/non-rocky transition in period-radius space. Here we present the confirmation of TOI-1235 b ($P=3.44$ days, $r_p=1.738^{+0.087}_{-0.076}$ R$_{\oplus}$), a planet whose size and period are intermediate between the competing model predictions, thus making the system an important test case for emergence models of the rocky/non-rocky transition around early M dwarfs ($R_s=0.630\pm 0.015$ R$_{\odot}$, $M_s=0.640\pm 0.016$ M$_{\odot}$). We confirm the TESS planet discovery using reconnaissance spectroscopy, ground-based photometry, high-resolution imaging, and a set of 38 precise radial-velocities from HARPS-N and HIRES. We measure a planet mass of $6.91^{+0.75}_{-0.85}$ M$_{\oplus}$ which implies an iron core mass fraction of $20^{+15}_{-12}$% in the absence of a gaseous envelope. The bulk composition of TOI-1235 b is therefore consistent with being Earth-like and we constrain a H/He envelope mass fraction to be $

Published

2020

8. The TESS-Keck survey. II. An ultra-short-period rocky planet and its siblings transiting the galactic thick-disk star TOI-561

Author

Weiss, LM, Weiss, LM, Dai, F, Huber, D, Brewer, JM, Collins, KA, Ciardi, DR, Matthews, EC, Ziegler, C, Howell, SB, Batalha, NM, Crossfield, IJM, Dressing, C, Fulton, B, Howard, AW, Isaacson, H, Kane, SR, Petigura, EA, Robertson, P, Roy, A, Rubenzahl, RA, Twicken, JD, Claytor, ZR, Stassun, KG, MacDougall, MG, Chontos, A, Giacalone, S, Dalba, PA, Mocnik, T, Hill, ML, Beard, C, Murphy, JMA, Rosenthal, LJ, Behmard, A, Van Zandt, J, Lubin, J, Kosiarek, MR, Lund, MB, Christiansen, JL, Matson, RA, Beichman, CA, Schlieder, JE, Gonzales, EJ, Briceño, C, Law, N, Mann, AW, Collins, KI, Evans, P, Fukui, A, Jensen, ELN, Murgas, F, Narita, N, Palle, E, Parviainen, H, Schwarz, RP, Tan, TG, Acton, JS, Bryant, EM, Chaushev, A, Gill, S, Eigmüller, P, Jenkins, J, Ricker, G, Seager, S, Winn, JN, Weiss, LM, Weiss, LM, Dai, F, Huber, D, Brewer, JM, Collins, KA, Ciardi, DR, Matthews, EC, Ziegler, C, Howell, SB, Batalha, NM, Crossfield, IJM, Dressing, C, Fulton, B, Howard, AW, Isaacson, H, Kane, SR, Petigura, EA, Robertson, P, Roy, A, Rubenzahl, RA, Twicken, JD, Claytor, ZR, Stassun, KG, MacDougall, MG, Chontos, A, Giacalone, S, Dalba, PA, Mocnik, T, Hill, ML, Beard, C, Murphy, JMA, Rosenthal, LJ, Behmard, A, Van Zandt, J, Lubin, J, Kosiarek, MR, Lund, MB, Christiansen, JL, Matson, RA, Beichman, CA, Schlieder, JE, Gonzales, EJ, Briceño, C, Law, N, Mann, AW, Collins, KI, Evans, P, Fukui, A, Jensen, ELN, Murgas, F, Narita, N, Palle, E, Parviainen, H, Schwarz, RP, Tan, TG, Acton, JS, Bryant, EM, Chaushev, A, Gill, S, Eigmüller, P, Jenkins, J, Ricker, G, Seager, S, and Winn, JN

Abstract

We report the discovery of TOI-561, a multiplanet system in the galactic thick disk that contains a rocky, ultrashort- period planet. This bright (V = 10.2) star hosts three small transiting planets identified in photometry from the NASA TESS mission: TOI-561 b (TOI-561.02, P = 0.44 days, Rp = 1.45 ± 0.11 R⊕), c (TOI-561.01, P = 10.8 days, Rp = 2.90 ± 0.13 R⊕), and d (TOI-561.03, P = 16.3 days, Rp = 2.32 ± 0.16 R⊕). The star is chemically ([Fe/ H] = -0.41 ± 0.05, [a/Fe]=+0.23 ± 0.05) and kinematically consistent with the galactic thick-disk population, making TOI-561 one of the oldest (10 ± 3 Gyr) and most metal-poor planetary systems discovered yet. We dynamically confirm planets b and c with radial velocities from the W. M. Keck Observatory High Resolution Echelle Spectrometer. Planet b has a mass and density of 3.2 ± 0.8M⊕ and 5.5+2.0-1.6g cm-3, consistent with a rocky composition. Its lower-than-average density is consistent with an iron-poor composition, although an Earth-like iron-to-silicates ratio is not ruled out. Planet c is 7.0 ± 2.3M⊕ and 1.6 ± 0.6 g cm-3, consistent with an interior rocky core overlaid with a low-mass volatile envelope. Several attributes of the photometry for planet d (which we did not detect dynamically) complicate the analysis, but we vet the planet with high-contrast imaging, groundbased photometric follow-up, and radial velocities. TOI-561 b is the first rocky world around a galactic thick-disk star confirmed with radial velocities and one of the best rocky planets for thermal emission studies.

Published

2021

9. Physical parameters of the multiplanet systems HD 106315 and GJ 9827

Author

Kosiarek, MR, Kosiarek, MR, Berardo, DA, Crossfield, IJM, Laguna, C, Piaulet, C, Akana Murphy, JM, Howell, SB, Henry, GW, Isaacson, H, Fulton, B, Weiss, LM, Petigura, EA, Behmard, A, Hirsch, LA, Teske, J, Burt, JA, Mills, SM, Chontos, A, Močnik, T, Howard, AW, Werner, M, Livingston, JH, Krick, J, Beichman, C, Gorjian, V, Kreidberg, L, Morley, C, Christiansen, JL, Morales, FY, Scott, NJ, Crane, JD, Wang, SX, Shectman, SA, Rosenthal, LJ, Grunblatt, SK, Rubenzahl, RA, Dalba, PA, Giacalone, S, Villanueva, CD, Liu, Q, Dai, F, Hill, ML, Rice, M, Kane, SR, Mayo, AW, Kosiarek, MR, Kosiarek, MR, Berardo, DA, Crossfield, IJM, Laguna, C, Piaulet, C, Akana Murphy, JM, Howell, SB, Henry, GW, Isaacson, H, Fulton, B, Weiss, LM, Petigura, EA, Behmard, A, Hirsch, LA, Teske, J, Burt, JA, Mills, SM, Chontos, A, Močnik, T, Howard, AW, Werner, M, Livingston, JH, Krick, J, Beichman, C, Gorjian, V, Kreidberg, L, Morley, C, Christiansen, JL, Morales, FY, Scott, NJ, Crane, JD, Wang, SX, Shectman, SA, Rosenthal, LJ, Grunblatt, SK, Rubenzahl, RA, Dalba, PA, Giacalone, S, Villanueva, CD, Liu, Q, Dai, F, Hill, ML, Rice, M, Kane, SR, and Mayo, AW

Abstract

HD 106315 and GJ 9827 are two bright, nearby stars that host multiple super-Earths and sub-Neptunes discovered by K2 that are well suited for atmospheric characterization. We refined the planets' ephemerides through Spitzer transits, enabling accurate transit prediction required for future atmospheric characterization through transmission spectroscopy. Through a multiyear high-cadence observing campaign with Keck/High Resolution Echelle Spectrometer and Magellan/Planet Finder Spectrograph, we improved the planets' mass measurements in anticipation of Hubble Space Telescope transmission spectroscopy. For GJ 9827, we modeled activity-induced radial velocity signals with a Gaussian process informed by the Calcium II H&K lines in order to more accurately model the effect of stellar noise on our data. We measured planet masses of Mb = 4.87 ± 0.37 M⊕, Mc = 1.92 ± 0.49 M⊕, and Md = 3.42 ± 0.62 M⊕. For HD 106315, we found that such activity radial velocity decorrelation was not effective due to the reduced presence of spots and speculate that this may extend to other hot stars as well (Teff > 6200 K). We measured planet masses of Mb = 10.5 ± 3.1 M⊕ and Mc = 12.0 ± 3.8 M⊕. We investigated all of the planets' compositions through comparison of their masses and radii to a range of interior models. GJ 9827 b and GJ 9827 c are both consistent with a 50/50 rock-iron composition, GJ 9827 d and HD 106315 b both require additional volatiles and are consistent with moderate amounts of water or hydrogen/helium, and HD 106315 c is consistent with a ∼10% hydrogen/helium envelope surrounding an Earth-like rock and iron core.

Published

2020

10. The TESS-keck survey. III. A stellar obliquity measurement of TOI-1726 c

Author

Dai, F, Dai, F, Roy, A, Fulton, B, Robertson, P, Hirsch, L, Isaacson, H, Albrecht, S, Mann, AW, Kristiansen, MH, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dalba, PA, Dressing, C, Giacalone, S, Hill, M, Howard, AW, Huber, D, Kane, SR, Kosiarek, M, Lubin, J, Mayo, A, Mocnik, T, Akana Murphy, JM, Petigura, EA, Rosenthal, L, Rubenzahl, RA, Scarsdale, N, Weiss, LM, van Zandt, J, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Charbonneau, D, Daylan, T, Günther, MN, Morgan, E, Quinn, SN, Rose, ME, Smith, JC, Dai, F, Dai, F, Roy, A, Fulton, B, Robertson, P, Hirsch, L, Isaacson, H, Albrecht, S, Mann, AW, Kristiansen, MH, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dalba, PA, Dressing, C, Giacalone, S, Hill, M, Howard, AW, Huber, D, Kane, SR, Kosiarek, M, Lubin, J, Mayo, A, Mocnik, T, Akana Murphy, JM, Petigura, EA, Rosenthal, L, Rubenzahl, RA, Scarsdale, N, Weiss, LM, van Zandt, J, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Charbonneau, D, Daylan, T, Günther, MN, Morgan, E, Quinn, SN, Rose, ME, and Smith, JC

Abstract

We report the measurement of a spectroscopic transit of TOI-1726c, one of two planets transiting a G-type star with V = 6.9 in the Ursa Major Moving Group (∼400 Myr). With a precise age constraint from cluster membership, TOI-1726 provides a great opportunity to test various obliquity excitation scenarios that operate on different timescales. By modeling the Rossiter-McLaughlin (RM) effect, we derived a sky-projected obliquity of -1-+3235∘. This result rules out a polar/retrograde orbit and is consistent with an aligned orbit for planet c. Considering the previously reported, similarly prograde RM measurement of planet b and the transiting nature of both planets, TOI-1726 tentatively conforms to the overall picture that compact multitransiting planetary systems tend to have coplanar, likely aligned orbits. TOI-1726 is also a great atmospheric target for understanding differential atmospheric loss of sub-Neptune planets (planet b 2.2 R☉ and c 2.7 R☉ both likely underwent photoevaporation). The coplanar geometry points to a dynamically cold history of the system that simplifies any future modeling of atmospheric escape.

Published

2020

11. A Super-Earth and Sub-Neptune Transiting the Late-type M Dwarf LP 791-18

Author

Crossfield, IJM, Crossfield, IJM, Waalkes, W, Newton, ER, Narita, N, Muirhead, P, Ment, K, Matthews, E, Kraus, A, Kostov, V, Kosiarek, MR, Kane, SR, Isaacson, H, Halverson, S, Gonzales, E, Everett, M, Dragomir, D, Collins, KA, Chontos, A, Berardo, D, Winters, JG, Winn, JN, Scott, NJ, Rojas-Ayala, B, Rizzuto, AC, Petigura, EA, Peterson, M, Mocnik, T, Mikal-Evans, T, Mehrle, N, Matson, R, Kuzuhara, M, Irwin, J, Huber, D, Huang, C, Howell, S, Howard, AW, Hirano, T, Fulton, BJ, Dupuy, T, Dressing, CD, Dalba, PA, Charbonneau, D, Burt, J, Berta-Thompson, Z, Benneke, B, Watanabe, N, Twicken, JD, Tamura, M, Schlieder, J, Seager, S, Rose, ME, Ricker, G, Quintana, E, Lépine, S, Latham, DW, Kotani, T, Jenkins, JM, Hori, Y, Colon, K, Caldwell, DA, Crossfield, IJM, Crossfield, IJM, Waalkes, W, Newton, ER, Narita, N, Muirhead, P, Ment, K, Matthews, E, Kraus, A, Kostov, V, Kosiarek, MR, Kane, SR, Isaacson, H, Halverson, S, Gonzales, E, Everett, M, Dragomir, D, Collins, KA, Chontos, A, Berardo, D, Winters, JG, Winn, JN, Scott, NJ, Rojas-Ayala, B, Rizzuto, AC, Petigura, EA, Peterson, M, Mocnik, T, Mikal-Evans, T, Mehrle, N, Matson, R, Kuzuhara, M, Irwin, J, Huber, D, Huang, C, Howell, S, Howard, AW, Hirano, T, Fulton, BJ, Dupuy, T, Dressing, CD, Dalba, PA, Charbonneau, D, Burt, J, Berta-Thompson, Z, Benneke, B, Watanabe, N, Twicken, JD, Tamura, M, Schlieder, J, Seager, S, Rose, ME, Ricker, G, Quintana, E, Lépine, S, Latham, DW, Kotani, T, Jenkins, JM, Hori, Y, Colon, K, and Caldwell, DA

Abstract

Planets occur most frequently around cool dwarfs, but only a handful of specific examples are known to orbit the latest-type M stars. Using TESS photometry, we report the discovery of two planets transiting the low-mass star called LP 791-18 (identified by TESS as TOI 736). This star has spectral type M6V, effective temperature 2960 K, and radius 0.17 R o, making it the third-coolest star known to host planets. The two planets straddle the radius gap seen for smaller exoplanets; they include a 1.1R ⊕ planet on a 0.95 day orbit and a 2.3R ⊕ planet on a 5 day orbit. Because the host star is small the decrease in light during these planets' transits is fairly large (0.4% and 1.7%). This has allowed us to detect both planets' transits from ground-based photometry, refining their radii and orbital ephemerides. In the future, radial velocity observations and transmission spectroscopy can both probe these planets' bulk interior and atmospheric compositions, and additional photometric monitoring would be sensitive to even smaller transiting planets.

Published

2019

12. A dearth of small particles in the transiting material around the white dwarfWD 1145+017

Author

Xu, S, Rappaport, S, Van Lieshout, R, Vanderburg, A, Gary, B, Hallakoun, N, Ivanov, VD, Wyatt, MC, DeVore, J, Bayliss, D, Bento, J, Bieryla, A, Cameron, A, Cann, JM, Croll, B, Collins, KA, Dalba, PA, Debes, J, Doyle, D, Dufour, P, Ely, J, Espinoza, N, Joner, MD, Jura, M, Kaye, T, McClain, JL, Muirhead, P, Palle, E, Panka, PA, Provencal, J, Randall, S, Rodriguez, JE, Scarborough, J, Sefako, R, Shporer, A, Strickland, W, Zhou, G, Zuckerman, B, Wyatt, Mark [0000-0001-9064-5598], and Apollo - University of Cambridge Repository

Subjects

stars: individual: WD 1145+017, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics::Earth and Planetary Astrophysics, minor planets, asteroids: general, eclipses, Astrophysics::Galaxy Astrophysics, white dwarfs

Abstract

White dwarf WD 1145+017 is orbited by several clouds of dust, possibly emanating from actively disintegrating bodies. These dust clouds reveal themselves through deep, broad, and evolving transits in the star's light curve. Here, we report two epochs of multi-wavelength photometric observations of WD 1145+017, including several filters in the optical, K$_\mathrm{s}$ and 4.5 $\mu$m bands in 2016 and 2017. The observed transit depths are different at these wavelengths. However, after correcting for excess dust emission at K$_\mathrm{s}$ and 4.5 $\mu$m, we find the transit depths for the white dwarf itself are the same at all wavelengths, at least to within the observational uncertainties of $\sim$5%-10%. From this surprising result, and under the assumption of low optical depth dust clouds, we conclude that there is a deficit of small particles (with radii $s \lesssim$ 1.5 $\mu$m) in the transiting material. We propose a model wherein only large particles can survive the high equilibrium temperature environment corresponding to 4.5 hr orbital periods around WD 1145+017, while small particles sublimate rapidly. In addition, we evaluate dust models that are permitted by our measurements of infrared emission.

Published

2018

13. Light curves and colours of the ejecta from Dimorphos after the DART impact.

Author

Graykowski A, Lambert RA, Marchis F, Cazeneuve D, Dalba PA, Esposito TM, O'Conner Peluso D, Sgro LA, Blaclard G, Borot A, Malvache A, Marfisi L, Powell TM, Huet P, Limagne M, Payet B, Clarke C, Murabana S, Owen DC, Wasilwa R, Fukui K, Goto T, Guillet B, Huth P, Ishiyama S, Kukita R, Mitchell M, Primm M, Randolph J, Rivett DA, Ryno M, Shimizu M, Toullec JP, Will S, Yue WC, Camilleri M, Graykowski K, Janetzke R, Janke D, Kardel S, Loose M, Pickering JW, Smith BA, and Transom IM

Abstract

On 26 September 2022, the Double Asteroid Redirection Test (DART) spacecraft struck Dimorphos, a satellite of the asteroid 65803 Didymos 1 . Because it is a binary system, it is possible to determine how much the orbit of the satellite changed, as part of a test of what is necessary to deflect an asteroid that might threaten Earth with an impact. In nominal cases, pre-impact predictions of the orbital period reduction ranged from roughly 8.8 to 17 min (refs. 2,3 ). Here we report optical observations of Dimorphos before, during and after the impact, from a network of citizen scientists' telescopes across the world. We find a maximum brightening of 2.29 ± 0.14 mag on impact. Didymos fades back to its pre-impact brightness over the course of 23.7 ± 0.7 days. We estimate lower limits on the mass contained in the ejecta, which was 0.3-0.5% Dimorphos's mass depending on the dust size. We also observe a reddening of the ejecta on impact., (© 2023. The Author(s).)

Published

2023

14. The exoplanet perspective on future ice giant exploration.

Author

Wakeford HR and Dalba PA

Abstract

Exoplanets number in their thousands, and the number is ever increasing with the advent of new surveys and improved instrumentation. One of the most surprising things we have learnt from these discoveries is not that small-rocky planets in their stars habitable zones are likely to be common, but that the most typical size of exoplanets is that not seen in our solar system-radii between that of Neptune and the Earth dubbed mini-Neptunes and super-Earths. In fact, a transiting exoplanet is four times as likely to be in this size regime than that of any giant planet in our solar system. Investigations into the atmospheres of giant hydrogen/helium dominated exoplanets has pushed down to Neptune and mini-Neptune-sized worlds revealing molecular absorption from water, scattering and opacity from clouds, and measurements of atmospheric abundances. However, unlike measurements of Jupiter, or even Saturn sized worlds, the smaller giants lack a ground truth on what to expect or interpret from their measurements. How did these sized worlds form and evolve and was it different from their larger counterparts? What is their internal composition and how does that impact their atmosphere? What informs the energy budget of these distant worlds? In this we discuss what characteristics we can measure for exoplanets, and why a mission to the ice giants in our solar system is the logical next step for understanding exoplanets. This article is part of a discussion meeting issue 'Future exploration of ice giant systems'.

Published

2020