Your search keyword '"Latham DW"' showing total 17 results

1. PTFO 8-8695: Two Stars, Two Signals, No Planet

Author

Massachusetts Institute of Technology. Department of Physics, MIT Kavli Institute for Astrophysics and Space Research, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Bouma, LG, Winn, JN, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Jenkins, JM, Barclay, T, Collins, KA, Doty, JP, Louie, DR, Quinn, SN, Rose, ME, Smith, JC, Villaseñor, J, Wohler, B, Massachusetts Institute of Technology. Department of Physics, MIT Kavli Institute for Astrophysics and Space Research, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Bouma, LG, Winn, JN, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Jenkins, JM, Barclay, T, Collins, KA, Doty, JP, Louie, DR, Quinn, SN, Rose, ME, Smith, JC, Villaseñor, J, and Wohler, B

Abstract

© 2020. The American Astronomical Society. All rights reserved.. PTFO 8-8695 (CVSO 30) is a star in the 7-10 million year old Orion OB1a cluster that shows brightness dips that resemble planetary transits. Although strong evidence against the planet hypothesis has been presented, the possibility remains debated in the literature. To obtain further clues, we inspected data from the NASA Transiting Exoplanet Survey Satellite (TESS) and the ESA Gaia mission. The Gaia data suggest that PTFO 8-8695 is a binary: the photometric data show it to be overluminous with respect to members of its kinematic group, and the astrometric data are inconsistent with a single star. The TESS light curve shows two different photometric periods. The variability is dominated by a sinusoidal signal with a period of 11.98 hr, presumably caused by stellar rotation. Also present is a 10.76 hr signal consisting of a not-quite sinusoid interrupted by hour-long dips, the type of signal previously interpreted as planetary transits. The phase of the dips is nearly 180 away from the phase of the originally reported dips. As noted previously, this makes them difficult to explain as planetary transits. Instead, we believe that PTFO 8-8695 is a pair of young and rapidly rotating M dwarfs, one of which shows the same "transient-dipper"behavior that has been seen in at least five other cases. The origin of these transient dips is still unknown but likely involves circumstellar material.

Published

2022

2. PTFO 8-8695: Two Stars, Two Signals, No Planet

Author

Bouma, LG, Winn, JN, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Jenkins, JM, Barclay, T, Collins, KA, Doty, JP, Louie, DR, Quinn, SN, Rose, ME, Smith, JC, Villaseñor, J, Wohler, B, Bouma, LG, Winn, JN, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Jenkins, JM, Barclay, T, Collins, KA, Doty, JP, Louie, DR, Quinn, SN, Rose, ME, Smith, JC, Villaseñor, J, and Wohler, B

Abstract

© 2020. The American Astronomical Society. All rights reserved.. PTFO 8-8695 (CVSO 30) is a star in the 7-10 million year old Orion OB1a cluster that shows brightness dips that resemble planetary transits. Although strong evidence against the planet hypothesis has been presented, the possibility remains debated in the literature. To obtain further clues, we inspected data from the NASA Transiting Exoplanet Survey Satellite (TESS) and the ESA Gaia mission. The Gaia data suggest that PTFO 8-8695 is a binary: the photometric data show it to be overluminous with respect to members of its kinematic group, and the astrometric data are inconsistent with a single star. The TESS light curve shows two different photometric periods. The variability is dominated by a sinusoidal signal with a period of 11.98 hr, presumably caused by stellar rotation. Also present is a 10.76 hr signal consisting of a not-quite sinusoid interrupted by hour-long dips, the type of signal previously interpreted as planetary transits. The phase of the dips is nearly 180 away from the phase of the originally reported dips. As noted previously, this makes them difficult to explain as planetary transits. Instead, we believe that PTFO 8-8695 is a pair of young and rapidly rotating M dwarfs, one of which shows the same "transient-dipper"behavior that has been seen in at least five other cases. The origin of these transient dips is still unknown but likely involves circumstellar material.

Published

2021

3. Erratum: An 11 Earth-mass, Long-period Sub-Neptune Orbiting a Sun-like Star (AJ (2019) 158 (165) DOI: 10.3847/1538-3881/ab3e2f)

Author

Mayo, AW, Mayo, AW, Rajpaul, VM, Buchhave, LA, Dressing, CD, Mortier, A, Zeng, L, Fortenbach, CD, Aigrain, S, Bonomo, AS, Cameron, AC, Charbonneau, D, Coffinet, A, Cosentino, R, Damasso, M, Dumusque, X, Fiorenzano, AFM, Haywood, RD, Latham, DW, López-Morales, M, Malavolta, L, Micela, G, Molinari, E, Pearce, L, Pepe, F, Phillips, D, Piotto, G, Poretti, E, Rice, K, Sozzetti, A, Udry, S, Mayo, AW, Mayo, AW, Rajpaul, VM, Buchhave, LA, Dressing, CD, Mortier, A, Zeng, L, Fortenbach, CD, Aigrain, S, Bonomo, AS, Cameron, AC, Charbonneau, D, Coffinet, A, Cosentino, R, Damasso, M, Dumusque, X, Fiorenzano, AFM, Haywood, RD, Latham, DW, López-Morales, M, Malavolta, L, Micela, G, Molinari, E, Pearce, L, Pepe, F, Phillips, D, Piotto, G, Poretti, E, Rice, K, Sozzetti, A, and Udry, S

Abstract

The semimajor axis and planet insolation flux of Kepler-538b were incorrectly calculated in the published article. This error did not impact any other parameters or any other results in the paper. Table 2 has been included in full here with the corrected semimajor axis and planet insolation flux values. We thank Arbab I. Arbab and Charles D. Fortenbach for bringing this to our attention.(Table Presented).

Published

2020

4. Erratum: An 11 Earth-mass, Long-period Sub-Neptune Orbiting a Sun-like Star (AJ (2019) 158 (165) DOI: 10.3847/1538-3881/ab3e2f)

Author

Mayo, AW, Mayo, AW, Rajpaul, VM, Buchhave, LA, Dressing, CD, Mortier, A, Zeng, L, Fortenbach, CD, Aigrain, S, Bonomo, AS, Cameron, AC, Charbonneau, D, Coffinet, A, Cosentino, R, Damasso, M, Dumusque, X, Fiorenzano, AFM, Haywood, RD, Latham, DW, López-Morales, M, Malavolta, L, Micela, G, Molinari, E, Pearce, L, Pepe, F, Phillips, D, Piotto, G, Poretti, E, Rice, K, Sozzetti, A, Udry, S, Mayo, AW, Mayo, AW, Rajpaul, VM, Buchhave, LA, Dressing, CD, Mortier, A, Zeng, L, Fortenbach, CD, Aigrain, S, Bonomo, AS, Cameron, AC, Charbonneau, D, Coffinet, A, Cosentino, R, Damasso, M, Dumusque, X, Fiorenzano, AFM, Haywood, RD, Latham, DW, López-Morales, M, Malavolta, L, Micela, G, Molinari, E, Pearce, L, Pepe, F, Phillips, D, Piotto, G, Poretti, E, Rice, K, Sozzetti, A, and Udry, S

Abstract

The semimajor axis and planet insolation flux of Kepler-538b were incorrectly calculated in the published article. This error did not impact any other parameters or any other results in the paper. Table 2 has been included in full here with the corrected semimajor axis and planet insolation flux values. We thank Arbab I. Arbab and Charles D. Fortenbach for bringing this to our attention.(Table Presented).

Published

2020

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

Author

Cloutier, R, 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, SR, 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, 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, SR, 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, and Akana Murphy, JM

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/nonrocky transition in period-radius space. Here we present the confirmation of TOI-1235 b (P = 3.44 days, rp1.738-0.076+0.087 R⊕), 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/nonrocky transition around early M dwarfs (R s = 0.630± 0.015 ⊕, M s = 0.640 ± 0.016 ⊙. We confirm the TESS planet discovery using reconnaissance spectroscopy, ground-based photometry, high-resolution imaging, and a set of 38 precise radial velocities (RVs) from HARPS-N and HIRES. We measure a planet mass of 6.91-0.85+0.75M⊕ which implies an iron core mass fraction of 20-12+15% in the absence of a gaseous envelope. The bulk composition of TOI-1235 b is therefore consistent with being Earth-like, and we constrain an H/He envelope mass fraction to be <0.5% at 90% confidence. Our results are consistent with model predictions from thermally driven atmospheric mass loss but not with gas-poor formation, suggesting that the former class of processes remains efficient at sculpting close-in planets around early M dwarfs. Our RV analysis also reveals a strong periodicity close to the first harmonic of the photometrically determined stellar rotation period that we treat as stellar activity, despite other lines of evidence favoring a planetary origin ( = P 21.8+0.9-0.8days,mp sin =13.0+ 3.8-5.3M⊕) that cannot be firmly ruled out by our data.

Published

2020

6. 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

7. 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

8. HD 202772A b: A Transiting Hot Jupiter around a Bright, Mildly Evolved Star in a Visual Binary Discovered by TESS

Author

Wang, S, Wang, S, Jones, M, Shporer, A, Fulton, BJ, Paredes, LA, Trifonov, T, Kossakowski, D, Eastman, J, Redfield, S, Günther, MN, Kreidberg, L, Huang, CX, Millholland, S, Seligman, D, Fischer, D, Brahm, R, Wang, XY, Cruz, B, Henry, T, James, HS, Addison, B, Liang, ES, Davis, AB, Tronsgaard, R, Worku, K, Brewer, JM, Kürster, M, Zhang, H, Beichman, CA, Bieryla, A, Brown, TM, Christiansen, JL, Ciardi, DR, Collins, KA, Esquerdo, GA, Howard, AW, Isaacson, H, Latham, DW, Mazeh, T, Petigura, EA, Quinn, SN, Shahaf, S, Siverd, RJ, Rodler, F, Reffert, S, Zakhozhay, O, Ricker, GR, Vanderspek, R, Seager, S, Winn, JN, Jenkins, JM, Boyd, PT, Frész, G, Henze, C, Levine, AM, Morris, R, Paegert, M, Stassun, KG, Ting, EB, Vezie, M, Laughlin, G, Wang, S, Wang, S, Jones, M, Shporer, A, Fulton, BJ, Paredes, LA, Trifonov, T, Kossakowski, D, Eastman, J, Redfield, S, Günther, MN, Kreidberg, L, Huang, CX, Millholland, S, Seligman, D, Fischer, D, Brahm, R, Wang, XY, Cruz, B, Henry, T, James, HS, Addison, B, Liang, ES, Davis, AB, Tronsgaard, R, Worku, K, Brewer, JM, Kürster, M, Zhang, H, Beichman, CA, Bieryla, A, Brown, TM, Christiansen, JL, Ciardi, DR, Collins, KA, Esquerdo, GA, Howard, AW, Isaacson, H, Latham, DW, Mazeh, T, Petigura, EA, Quinn, SN, Shahaf, S, Siverd, RJ, Rodler, F, Reffert, S, Zakhozhay, O, Ricker, GR, Vanderspek, R, Seager, S, Winn, JN, Jenkins, JM, Boyd, PT, Frész, G, Henze, C, Levine, AM, Morris, R, Paegert, M, Stassun, KG, Ting, EB, Vezie, M, and Laughlin, G

Abstract

We report the first confirmation of a hot Jupiter discovered by the Transiting Exoplanet Survey Satellite (TESS) mission: HD 202772A b. The transit signal was detected in the data from TESS Sector 1, and was confirmed to be of planetary origin through radial velocity (RV) measurements. HD 202772A b is orbiting a mildly evolved star with a period of 3.3 days. With an apparent magnitude of V = 8.3, the star is among the brightest and most massive known to host a hot Jupiter. Based on the 27 days of TESS photometry and RV data from the CHIRON, HARPS, and Tillinghast Reflector Echelle Spectrograph, the planet has a mass of and radius of , making it an inflated gas giant. HD 202772A b is a rare example of a transiting hot Jupiter around a quickly evolving star. It is also one of the most strongly irradiated hot Jupiters currently known.

Published

2019

9. 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

10. The Mass of the White Dwarf Companion in the Self-lensing Binary KOI-3278: Einstein versus Newton

Author

Yahalomi, DA, Yahalomi, DA, Shvartzvald, Y, Agol, E, Shporer, A, Latham, DW, Kruse, E, Brewer, JM, Buchhave, LA, Fulton, BJ, Howard, AW, Isaacson, H, Petigura, EA, Quinn, SN, Yahalomi, DA, Yahalomi, DA, Shvartzvald, Y, Agol, E, Shporer, A, Latham, DW, Kruse, E, Brewer, JM, Buchhave, LA, Fulton, BJ, Howard, AW, Isaacson, H, Petigura, EA, and Quinn, SN

Abstract

KOI-3278 is a self-lensing stellar binary consisting of a white dwarf secondary orbiting a Sun-like primary star. Kruse & Agol noticed small periodic brightenings every 88.18 days in the Kepler photometry and interpreted these as the result of microlensing by a white dwarf with about 63% of the mass of the Sun. We obtained two sets of spectra for the primary that allowed us to derive three sets of spectroscopic estimates for its effective temperature, surface gravity, and metallicity for the first time. We used these values to update the Kruse & Agol Einsteinian microlensing model, resulting in a revised mass for the white dwarf of 0.539-0.020+0.022 M o. The spectra also allowed us to determine radial velocities and derive orbital solutions, with good agreement between the two independent data sets. An independent Newtonian dynamical MCMC model of the combined velocities yielded a mass for the white dwarf of 0.5122-0.0058+0.0057 M o. The nominal uncertainty for the Newtonian mass is about four times better than for the Einsteinian, ± 1.1% versus ± 4.1%, and the difference between the two mass determinations is 5.2%. We then present a joint Einsteinian microlensing and Newtonian radial velocity model for KOI-3278, which yielded a mass for the white dwarf of 0.5250-0.0089+0.0082M o. This joint model does not rely on any white dwarf evolutionary models or assumptions on the white dwarf mass-radius relation. We discuss the benefits of a joint model of self-lensing binaries, and how future studies of these systems can provide insight into the mass-radius relation of white dwarfs.

Published

2019

11. The Kepler Follow-up Observation Program. II. Stellar Parameters from Medium- and High-resolution Spectroscopy

Author

Furlan, E, Furlan, E, Ciardi, DR, Cochran, WD, Everett, ME, Latham, DW, Marcy, GW, Buchhave, LA, Endl, M, Isaacson, H, Petigura, EA, Gautier, TN, Huber, D, Bieryla, A, Borucki, WJ, Brugamyer, E, Caldwell, C, Cochran, A, Howard, AW, Howell, SB, Johnson, MC, Macqueen, PJ, Quinn, SN, Robertson, P, Mathur, S, Batalha, NM, Furlan, E, Furlan, E, Ciardi, DR, Cochran, WD, Everett, ME, Latham, DW, Marcy, GW, Buchhave, LA, Endl, M, Isaacson, H, Petigura, EA, Gautier, TN, Huber, D, Bieryla, A, Borucki, WJ, Brugamyer, E, Caldwell, C, Cochran, A, Howard, AW, Howell, SB, Johnson, MC, Macqueen, PJ, Quinn, SN, Robertson, P, Mathur, S, and Batalha, NM

Abstract

We present results from spectroscopic follow-up observations of stars identified in the Kepler field and carried out by teams of the Kepler Follow-up Observation Program. Two samples of stars were observed over 6 yr (2009-2015): 614 standard stars (divided into "platinum" and "gold" categories) selected based on their asteroseismic detections and 2667 host stars of Kepler Objects of Interest (KOIs), most of them planet candidates. Four data analysis pipelines were used to derive stellar parameters for the observed stars. We compare the T eff, log(g), and [Fe/H] values derived for the same stars by different pipelines; from the average of the standard deviations of the differences in these parameter values, we derive error floors of ∼100 K, 0.2 dex, and 0.1 dex for T eff, log(g), and [Fe/H], respectively. Noticeable disagreements are seen mostly at the largest and smallest parameter values (e.g., in the giant star regime). Most of the log(g) values derived from spectra for the platinum stars agree on average within 0.025 dex (but with a spread of 0.1-0.2 dex) with the asteroseismic log(g) values. Compared to the Kepler Input Catalog (KIC), the spectroscopically derived stellar parameters agree within the uncertainties of the KIC but are more precise and thus an important contribution toward deriving more reliable planetary radii.

Published

2018

12. A 2 R ⊕ Planet Orbiting the Bright Nearby K Dwarf Wolf 503

Author

Peterson, MS, Peterson, MS, Benneke, B, David, TJ, Dressing, CD, Ciardi, D, Crossfield, IJM, Schlieder, JE, Petigura, EA, Mamajek, EE, Christiansen, JL, Quinn, SN, Fulton, BJ, Howard, AW, Sinukoff, E, Beichman, C, Latham, DW, Yu, L, Arango, N, Shporer, A, Henning, T, Huang, CX, Kosiarek, MR, Dittmann, J, Isaacson, H, Peterson, MS, Peterson, MS, Benneke, B, David, TJ, Dressing, CD, Ciardi, D, Crossfield, IJM, Schlieder, JE, Petigura, EA, Mamajek, EE, Christiansen, JL, Quinn, SN, Fulton, BJ, Howard, AW, Sinukoff, E, Beichman, C, Latham, DW, Yu, L, Arango, N, Shporer, A, Henning, T, Huang, CX, Kosiarek, MR, Dittmann, J, and Isaacson, H

Abstract

Since its launch in 2009, the Kepler telescope has found thousands of planets with radii between that of Earth and Neptune. Recent studies of the distribution of these planets have revealed a gap in the population near 1.5-2.0 R ⊕, informally dividing these planets into "super-Earths" and "sub-Neptunes." The origin of this division is difficult to investigate directly because the majority of planets found by Kepler orbit distant, dim stars and are not amenable to radial velocity follow-up or transit spectroscopy, making bulk density and atmospheric measurements difficult. Here, we present the discovery and validation of a newly found planet in direct proximity to the radius gap, orbiting the bright (J = 8.32 mag), nearby (D = 44.5 pc) high proper motion K3.5V star Wolf 503 (EPIC 212779563). We determine the possibility of a companion star and false positive detection to be extremely low using both archival images and high-contrast adaptive optics images from the Palomar observatory. The brightness of the host star makes Wolf 503b a prime target for prompt radial velocity follow-up, and with the small stellar radius (0.690 ± 0.025R o), it is also an excellent target for HST transit spectroscopy and detailed atmospheric characterization with JWST. With its measured radius near the gap in the planet radius and occurrence rate distribution, Wolf 503b offers a key opportunity to better understand the origin of this radius gap as well as the nature of the intriguing populations of "super-Earths" and "sub-Neptunes" as a whole.

Published

2018

13. Two Warm, Low-density Sub-Jovian Planets Orbiting Bright Stars in K2 Campaigns 13 and 14

Author

Yu, L, Yu, L, Rodriguez, JE, Eastman, JD, Crossfield, IJM, Shporer, A, Gaudi, BS, Burt, J, Fulton, BJ, Sinukoff, E, Howard, AW, Isaacson, H, Kosiarek, MR, Ciardi, DR, Schlieder, JE, Penev, K, Vanderburg, A, Stassun, KG, Bieryla, A, Butler, RP, Berlind, P, Calkins, ML, Esquerdo, GA, Latham, DW, Murawski, G, Stevens, DJ, Petigura, EA, Kreidberg, L, Bristow, M, Yu, L, Yu, L, Rodriguez, JE, Eastman, JD, Crossfield, IJM, Shporer, A, Gaudi, BS, Burt, J, Fulton, BJ, Sinukoff, E, Howard, AW, Isaacson, H, Kosiarek, MR, Ciardi, DR, Schlieder, JE, Penev, K, Vanderburg, A, Stassun, KG, Bieryla, A, Butler, RP, Berlind, P, Calkins, ML, Esquerdo, GA, Latham, DW, Murawski, G, Stevens, DJ, Petigura, EA, Kreidberg, L, and Bristow, M

Abstract

We report the discovery of two planets transiting the bright stars HD 89345 (EPIC 248777106, V = 9.376, K = 7.721) in K2 Campaign 14 and HD 286123 (EPIC 247098361, V = 9.822, K = 8.434) in K2 Campaign 13. Both stars are G-Type stars, one of which is at or near the end of its main-sequence lifetime, and the other is just over halfway through its main-sequence lifetime. HD 89345 hosts a warm sub-Saturn (0.66 , 0.11 , = 1100 K) in an 11.81 day orbit. The planet is similar in size to WASP-107b, which falls in the transition region between ice giants and gas giants. HD 286123 hosts a Jupiter-sized, low-mass planet (1.06 , 0.39 , = 1000 K) in an 11.17 day, mildly eccentric orbit, with e = 0.255 ± 0.035. Given that they orbit relatively evolved main-sequence stars and have orbital periods longer than 10 days, these planets are interesting candidates for studies of gas planet evolution, migration, and (potentially) reinflation. Both planets have spent their entire lifetimes near the proposed stellar irradiation threshold at which giant planets become inflated, and neither shows any sign of radius inflation. They probe the regime where inflation begins to become noticeable and are valuable in constraining planet inflation models. In addition, the brightness of the host stars, combined with large atmospheric scale heights of the planets, makes these two systems favorable targets for transit spectroscopy to study their atmospheres and perhaps provide insight into the physical mechanisms that lead to inflated hot Jupiters.

Published

2018

14. A TESS Dress Rehearsal: Planetary Candidates and Variables from K2 Campaign 17

Author

Crossfield, IJM, Crossfield, IJM, Guerrero, N, David, T, Quinn, SN, Feinstein, AD, Huang, C, Yu, L, Collins, KA, Fulton, BJ, Benneke, B, Peterson, M, Bieryla, A, Schlieder, JE, Kosiarek, MR, Bristow, M, Newton, E, Bedell, M, Latham, DW, Christiansen, JL, Esquerdo, GA, Berlind, P, Calkins, ML, Shporer, A, Burt, J, Ballard, S, Rodriguez, JE, Mehrle, N, Dressing, CD, Livingston, JH, Petigura, EA, Seager, S, Dittmann, J, Berardo, D, Sha, L, Essack, Z, Zhan, Z, Owens, M, Kain, I, Isaacson, H, Ciardi, DR, Gonzales, EJ, Howard, AW, Cardoso, JVDM, Crossfield, IJM, Crossfield, IJM, Guerrero, N, David, T, Quinn, SN, Feinstein, AD, Huang, C, Yu, L, Collins, KA, Fulton, BJ, Benneke, B, Peterson, M, Bieryla, A, Schlieder, JE, Kosiarek, MR, Bristow, M, Newton, E, Bedell, M, Latham, DW, Christiansen, JL, Esquerdo, GA, Berlind, P, Calkins, ML, Shporer, A, Burt, J, Ballard, S, Rodriguez, JE, Mehrle, N, Dressing, CD, Livingston, JH, Petigura, EA, Seager, S, Dittmann, J, Berardo, D, Sha, L, Essack, Z, Zhan, Z, Owens, M, Kain, I, Isaacson, H, Ciardi, DR, Gonzales, EJ, Howard, AW, and Cardoso, JVDM

Abstract

We produce light curves for all ∼34,000 targets observed with K2 in Campaign 17 (C17), identifying planet candidates, eclipsing binaries, and other periodic variables. The forward-facing direction of the C17 field means follow-up can begin immediately now that the campaign has concluded and interesting targets have been identified. The C17 field has a large overlap with C6, so this latest campaign also offers an infrequent opportunity to study a large number of targets already observed in a previous K2 campaign. The timing of the C17 data release, shortly before science operations begin with the Transiting Exoplanet Survey Satellite (TESS), also lets us exercise some of the tools and methods developed for identification and dissemination of planet candidates from TESS. We find excellent agreement between these results and those identified using only K2-based tools. Among our planet candidates are several planet candidates with sizes <4 R ⊕ and orbiting stars with Kp ≲ 10 (indicating good RV targets of the sort TESS hopes to find) and a Jupiter-sized single-transit event around a star already hosting a 6 day planet candidate.

Published

2018

15. Revised Stellar Properties of Kepler Targets for the Q1-17 (DR25) Transit Detection Run

Author

Mathur, S, Mathur, S, Huber, D, Batalha, NM, Ciardi, DR, Bastien, FA, Bieryla, A, Buchhave, LA, Cochran, WD, Endl, M, Esquerdo, GA, Furlan, E, Howard, A, Howell, SB, Isaacson, H, Latham, DW, Macqueen, PJ, Silva, DR, Mathur, S, Mathur, S, Huber, D, Batalha, NM, Ciardi, DR, Bastien, FA, Bieryla, A, Buchhave, LA, Cochran, WD, Endl, M, Esquerdo, GA, Furlan, E, Howard, A, Howell, SB, Isaacson, H, Latham, DW, Macqueen, PJ, and Silva, DR

Abstract

The determination of exoplanet properties and occurrence rates using Kepler data critically depends on our knowledge of the fundamental properties (such as temperature, radius, and mass) of the observed stars. We present revised stellar properties for 197,096 Kepler targets observed between Quarters 1-17 (Q1-17), which were used for the final transiting planet search run by the Kepler Mission (Data Release 25, DR25). Similar to the Q1-16 catalog by Huber et al., the classifications are based on conditioning published atmospheric parameters on a grid of Dartmouth isochrones, with significant improvements in the adopted method and over 29,000 new sources for temperatures, surface gravities, or metallicities. In addition to fundamental stellar properties, the new catalog also includes distances and extinctions, and we provide posterior samples for each stellar parameter of each star. Typical uncertainties are ∼27% in radius, ∼17% in mass, and ∼51% in density, which is somewhat smaller than previous catalogs because of the larger number of improved constraints and the inclusion of isochrone weighting when deriving stellar posterior distributions. On average, the catalog includes a significantly larger number of evolved solar-type stars, with an increase of 43.5% in the number of subgiants. We discuss the overall changes of radii and masses of Kepler targets as a function of spectral type, with a particular focus on exoplanet host stars.

Published

2017

16. KELT-14b and KELT-15b: AN INDEPENDENT DISCOVERY of WASP-122b and A NEW HOT JUPITER

Author

Rodriguez, JE, Colón, KD, Stassun, KG, Wright, D, Cargile, PA, Bayliss, D, Pepper, J, Collins, KA, Kuhn, RB, Lund, MB, Siverd, RJ, Zhou, G, Gaudi, BS, Tinney, CG, Penev, K, Tan, TG, Stockdale, C, Curtis, IA, James, D, Udry, S, Segransan, D, Bieryla, A, Latham, DW, Beatty, TG, Eastman, JD, Myers, G, Bartz, J, Bento, J, Jensen, ELN, Oberst, TE, Stevens, DJ, Rodriguez, JE, Colón, KD, Stassun, KG, Wright, D, Cargile, PA, Bayliss, D, Pepper, J, Collins, KA, Kuhn, RB, Lund, MB, Siverd, RJ, Zhou, G, Gaudi, BS, Tinney, CG, Penev, K, Tan, TG, Stockdale, C, Curtis, IA, James, D, Udry, S, Segransan, D, Bieryla, A, Latham, DW, Beatty, TG, Eastman, JD, Myers, G, Bartz, J, Bento, J, Jensen, ELN, Oberst, TE, and Stevens, DJ

Abstract

Gas to Liquids (GTL) diesel has been produced commercially for several years. GTL diesel is known for its excellent properties, including zero aromatics, near zero sulphur and a high cetane number. Most of the GTL diesel produced by commercial plants is utilised as a blend component, especially in blends up to 20%. In these applications, the cold flow properties are potentially less critical, as the cold flow properties of the blend will mostly be determined by the petroleum-derived component. In certain markets, however, it is possible that GTL diesel can be used as a neat diesel, therefore requiring good cold flow properties. An advantage of GTL technology is that the cold flow properties of GTL diesel can be tailored to meet the climatic requirements of a specific geographical area. In the current study, GTL diesel samples with cold flow properties ranging from summer type to winter type and varying intermediate cold flow qualities were evaluated. In line with expectations, it was shown that increasing the degree of isomerisation will improve the cold flow properties of the GTL diesel, whilst the other bulk properties such as density, cetane and viscosity of the fuels are not significantly altered. It is also shown that the excellent cold flow properties of these winter type GTL fuels translate into excellent operability performance.

Published

2016

17. THE KEPLER-454 SYSTEM: A SMALL, NOT-ROCKY INNER PLANET, A JOVIAN WORLD, and A DISTANT COMPANION

Author

Gettel, S, Gettel, S, Charbonneau, D, Dressing, CD, Buchhave, LA, Dumusque, X, Vanderburg, A, Bonomo, AS, Malavolta, L, Pepe, F, Cameron, AC, Latham, DW, Udry, S, Marcy, GW, Isaacson, H, Howard, AW, Davies, GR, Aguirre, VS, Kjeldsen, H, Bedding, TR, Lopez, E, Affer, L, Cosentino, R, Figueira, P, Fiorenzano, AFM, Harutyunyan, A, Johnson, JA, Lopez-Morales, M, Lovis, C, Mayor, M, Micela, G, Molinari, E, Motalebi, F, Phillips, DF, Piotto, G, Queloz, D, Rice, K, Sasselov, D, Ségransan, D, Sozzetti, A, Watson, C, Basu, S, Campante, TL, Christensen-Dalsgaard, J, Kawaler, SD, Metcalfe, TS, Handberg, R, Lund, MN, Lundkvist, MS, Huber, D, Chaplin, WJ, Gettel, S, Gettel, S, Charbonneau, D, Dressing, CD, Buchhave, LA, Dumusque, X, Vanderburg, A, Bonomo, AS, Malavolta, L, Pepe, F, Cameron, AC, Latham, DW, Udry, S, Marcy, GW, Isaacson, H, Howard, AW, Davies, GR, Aguirre, VS, Kjeldsen, H, Bedding, TR, Lopez, E, Affer, L, Cosentino, R, Figueira, P, Fiorenzano, AFM, Harutyunyan, A, Johnson, JA, Lopez-Morales, M, Lovis, C, Mayor, M, Micela, G, Molinari, E, Motalebi, F, Phillips, DF, Piotto, G, Queloz, D, Rice, K, Sasselov, D, Ségransan, D, Sozzetti, A, Watson, C, Basu, S, Campante, TL, Christensen-Dalsgaard, J, Kawaler, SD, Metcalfe, TS, Handberg, R, Lund, MN, Lundkvist, MS, Huber, D, and Chaplin, WJ

Abstract

Kepler-454 (KOI-273) is a relatively bright (V = 11.69 mag), Sun-like star that hosts a transiting planet candidate in a 10.6 day orbit. From spectroscopy, we estimate the stellar temperature to be 5687 ± 50 K, its metallicity to be [m/H] = 0.32 ± 0.08, and the projected rotational velocity to be v sin i < 2.4 km s-1. We combine these values with a study of the asteroseismic frequencies from short cadence Kepler data to estimate the stellar mass to be , the radius to be 1.066 ± 0.012 Ro, and the age to be Gyr. We estimate the radius of the 10.6 day planet as 2.37 ± 0.13 R⊕. Using 63 radial velocity observations obtained with the HARPS-N spectrograph on the Telescopio Nazionale Galileo and 36 observations made with the HIRES spectrograph at the Keck Observatory, we measure the mass of this planet to be 6.8 ± 1.4 M⊕. We also detect two additional non-transiting companions, a planet with a minimum mass of 4.46 ± 0.12 MJ in a nearly circular 524 day orbit and a massive companion with a period >10 years and mass >12.1 MJ. The 12 exoplanets with radii <2.7 R⊕ and precise mass measurements appear to fall into two populations, with those <1.6 R⊕ following an Earth-like composition curve and larger planets requiring a significant fraction of volatiles. With a density of 2.76 ± 0.73 g cm-3, Kepler-454b lies near the mass transition between these two populations and requires the presence of volatiles and/or H/He gas.

Published

2016