Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs

Nicholas M. Law; Adam L. Kraus; Rachel Street; Benjamin J. Fulton; Lynne A. Hillenbrand; Avi Shporer; Tim Lister; Christoph Baranec; Joshua S. Bloom; Khanh Bui; Mahesh P. Burse; S. Bradley Cenko; H. K. Das; Jack T.C. Davis; Richard G. Dekany; Alexei V. Filippenko; Mansi M. Kasliwal; S. R. Kulkarni; Peter Nugent; Eran O. Ofek; Dovi Poznanski; Robert M. Quimby; A. N. Ramaprakash; Reed Riddle; Jeffrey M. Silverman; Suresh Sivanandam; Shriharsh P. Tendulkar

doi:10.1088/0004-637X/757/2/133

Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs

Nicholas M. Law, Adam L. Kraus, Rachel Street, Benjamin J. Fulton, Lynne A. Hillenbrand, Avi Shporer, Tim Lister, Christoph Baranec, Joshua S. Bloom, Khanh Bui, Mahesh P. Burse, S. Bradley Cenko, H. K. Das, Jack T.C. Davis, Richard G. Dekany, Alexei V. Filippenko, Mansi M. Kasliwal, S. R. Kulkarni, Peter Nugent, Eran O. OfekDovi Poznanski, Robert M. Quimby, A. N. Ramaprakash, Reed Riddle, Jeffrey M. Silverman, Suresh Sivanandam, Shriharsh P. Tendulkar

School of Physics and Astronomy

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

We present three new eclipsing white-dwarf/M-dwarf binary systems discovered during a search for transiting planets around M-dwarfs. Unlike most known eclipsing systems of this type, the optical and infrared emission is dominated by the M-dwarf components, and the systems have optical colors and discovery light curves consistent with being Jupiter-radius transiting planets around early M-dwarfs. We detail the PTF/M-dwarf transiting planet survey, part of the Palomar Transient Factory (PTF). We present a graphics processing unit (GPU)-based box-least-squares search for transits that runs approximately 8 × faster than similar algorithms implemented on general purpose systems. For the discovered systems, we decompose low-resolution spectra of the systems into white-dwarf and M-dwarf components, and use radial velocity measurements and cooling models to estimate masses and radii for the white dwarfs. The systems are compact, with periods between 0.35 and 0.45days and semimajor axes of approximately 2 R _⊙ (0.01AU). The M-dwarfs have masses of approximately 0.35 M _⊙, and the white dwarfs have hydrogen-rich atmospheres with temperatures of around 8000K and have masses of approximately 0.5 M _⊙. We use the Robo-AO laser guide star adaptive optics system to tentatively identify one of the objects as a triple system. We also use high-cadence photometry to put an upper limit on the white-dwarf radius of 0.025 R _⊙ (95% confidence) in one of the systems. Accounting for our detection efficiency and geometric factors, we estimate that (90% confidence) of M-dwarfs are in these short-period, post-common-envelope white-dwarf/M-dwarf binaries where the optical light is dominated by the M-dwarf. The lack of detections at shorter periods, despite near-100% detection efficiency for such systems, suggests that binaries including these relatively low-temperature white dwarfs are preferentially found at relatively large orbital radii. Similar eclipsing binary systems can have arbitrarily small eclipse depths in red bands and generate plausible small-planet-transit light curves. As such, these systems are a source of false positives for M-dwarf transiting planet searches. We present several ways to rapidly distinguish these binaries from transiting planet systems.

Original language	English
Article number	133
Journal	Astrophysical Journal
Volume	757
Issue number	2
DOIs	https://doi.org/10.1088/0004-637X/757/2/133
State	Published - 1 Oct 2012

Keywords

binaries: eclipsing
methods: data analysis
planets and satellites: detection
stars: low-mass
techniques: photometric
white dwarfs

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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10.1088/0004-637X/757/2/133

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Law, N. M., Kraus, A. L., Street, R., Fulton, B. J., Hillenbrand, L. A., Shporer, A., Lister, T., Baranec, C., Bloom, J. S., Bui, K., Burse, M. P., Cenko, S. B., Das, H. K., Davis, J. T. C., Dekany, R. G., Filippenko, A. V., Kasliwal, M. M., Kulkarni, S. R., Nugent, P., ... Tendulkar, S. P. (2012). Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs. Astrophysical Journal, 757(2), Article 133. https://doi.org/10.1088/0004-637X/757/2/133

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title = "Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs",

abstract = "We present three new eclipsing white-dwarf/M-dwarf binary systems discovered during a search for transiting planets around M-dwarfs. Unlike most known eclipsing systems of this type, the optical and infrared emission is dominated by the M-dwarf components, and the systems have optical colors and discovery light curves consistent with being Jupiter-radius transiting planets around early M-dwarfs. We detail the PTF/M-dwarf transiting planet survey, part of the Palomar Transient Factory (PTF). We present a graphics processing unit (GPU)-based box-least-squares search for transits that runs approximately 8 × faster than similar algorithms implemented on general purpose systems. For the discovered systems, we decompose low-resolution spectra of the systems into white-dwarf and M-dwarf components, and use radial velocity measurements and cooling models to estimate masses and radii for the white dwarfs. The systems are compact, with periods between 0.35 and 0.45days and semimajor axes of approximately 2 R ⊙ (0.01AU). The M-dwarfs have masses of approximately 0.35 M ⊙, and the white dwarfs have hydrogen-rich atmospheres with temperatures of around 8000K and have masses of approximately 0.5 M ⊙. We use the Robo-AO laser guide star adaptive optics system to tentatively identify one of the objects as a triple system. We also use high-cadence photometry to put an upper limit on the white-dwarf radius of 0.025 R ⊙ (95% confidence) in one of the systems. Accounting for our detection efficiency and geometric factors, we estimate that (90% confidence) of M-dwarfs are in these short-period, post-common-envelope white-dwarf/M-dwarf binaries where the optical light is dominated by the M-dwarf. The lack of detections at shorter periods, despite near-100% detection efficiency for such systems, suggests that binaries including these relatively low-temperature white dwarfs are preferentially found at relatively large orbital radii. Similar eclipsing binary systems can have arbitrarily small eclipse depths in red bands and generate plausible small-planet-transit light curves. As such, these systems are a source of false positives for M-dwarf transiting planet searches. We present several ways to rapidly distinguish these binaries from transiting planet systems.",

keywords = "binaries: eclipsing, methods: data analysis, planets and satellites: detection, stars: low-mass, techniques: photometric, white dwarfs",

author = "Law, {Nicholas M.} and Kraus, {Adam L.} and Rachel Street and Fulton, {Benjamin J.} and Hillenbrand, {Lynne A.} and Avi Shporer and Tim Lister and Christoph Baranec and Bloom, {Joshua S.} and Khanh Bui and Burse, {Mahesh P.} and Cenko, {S. Bradley} and Das, {H. K.} and Davis, {Jack T.C.} and Dekany, {Richard G.} and Filippenko, {Alexei V.} and Kasliwal, {Mansi M.} and Kulkarni, {S. R.} and Peter Nugent and Ofek, {Eran O.} and Dovi Poznanski and Quimby, {Robert M.} and Ramaprakash, {A. N.} and Reed Riddle and Silverman, {Jeffrey M.} and Suresh Sivanandam and Tendulkar, {Shriharsh P.}",

year = "2012",

month = oct,

day = "1",

doi = "10.1088/0004-637X/757/2/133",

language = "الإنجليزيّة",

volume = "757",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "IOP Publishing Ltd.",

number = "2",

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Law, NM, Kraus, AL, Street, R, Fulton, BJ, Hillenbrand, LA, Shporer, A, Lister, T, Baranec, C, Bloom, JS, Bui, K, Burse, MP, Cenko, SB, Das, HK, Davis, JTC, Dekany, RG, Filippenko, AV, Kasliwal, MM, Kulkarni, SR, Nugent, P, Ofek, EO , Poznanski, D, Quimby, RM, Ramaprakash, AN, Riddle, R, Silverman, JM, Sivanandam, S & Tendulkar, SP 2012, 'Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs', Astrophysical Journal, vol. 757, no. 2, 133. https://doi.org/10.1088/0004-637X/757/2/133

TY - JOUR

T1 - Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs

AU - Law, Nicholas M.

AU - Kraus, Adam L.

AU - Street, Rachel

AU - Fulton, Benjamin J.

AU - Hillenbrand, Lynne A.

AU - Shporer, Avi

AU - Lister, Tim

AU - Baranec, Christoph

AU - Bloom, Joshua S.

AU - Bui, Khanh

AU - Burse, Mahesh P.

AU - Cenko, S. Bradley

AU - Das, H. K.

AU - Davis, Jack T.C.

AU - Dekany, Richard G.

AU - Filippenko, Alexei V.

AU - Kasliwal, Mansi M.

AU - Kulkarni, S. R.

AU - Nugent, Peter

AU - Ofek, Eran O.

AU - Poznanski, Dovi

AU - Quimby, Robert M.

AU - Ramaprakash, A. N.

AU - Riddle, Reed

AU - Silverman, Jeffrey M.

AU - Sivanandam, Suresh

AU - Tendulkar, Shriharsh P.

PY - 2012/10/1

Y1 - 2012/10/1

N2 - We present three new eclipsing white-dwarf/M-dwarf binary systems discovered during a search for transiting planets around M-dwarfs. Unlike most known eclipsing systems of this type, the optical and infrared emission is dominated by the M-dwarf components, and the systems have optical colors and discovery light curves consistent with being Jupiter-radius transiting planets around early M-dwarfs. We detail the PTF/M-dwarf transiting planet survey, part of the Palomar Transient Factory (PTF). We present a graphics processing unit (GPU)-based box-least-squares search for transits that runs approximately 8 × faster than similar algorithms implemented on general purpose systems. For the discovered systems, we decompose low-resolution spectra of the systems into white-dwarf and M-dwarf components, and use radial velocity measurements and cooling models to estimate masses and radii for the white dwarfs. The systems are compact, with periods between 0.35 and 0.45days and semimajor axes of approximately 2 R ⊙ (0.01AU). The M-dwarfs have masses of approximately 0.35 M ⊙, and the white dwarfs have hydrogen-rich atmospheres with temperatures of around 8000K and have masses of approximately 0.5 M ⊙. We use the Robo-AO laser guide star adaptive optics system to tentatively identify one of the objects as a triple system. We also use high-cadence photometry to put an upper limit on the white-dwarf radius of 0.025 R ⊙ (95% confidence) in one of the systems. Accounting for our detection efficiency and geometric factors, we estimate that (90% confidence) of M-dwarfs are in these short-period, post-common-envelope white-dwarf/M-dwarf binaries where the optical light is dominated by the M-dwarf. The lack of detections at shorter periods, despite near-100% detection efficiency for such systems, suggests that binaries including these relatively low-temperature white dwarfs are preferentially found at relatively large orbital radii. Similar eclipsing binary systems can have arbitrarily small eclipse depths in red bands and generate plausible small-planet-transit light curves. As such, these systems are a source of false positives for M-dwarf transiting planet searches. We present several ways to rapidly distinguish these binaries from transiting planet systems.

AB - We present three new eclipsing white-dwarf/M-dwarf binary systems discovered during a search for transiting planets around M-dwarfs. Unlike most known eclipsing systems of this type, the optical and infrared emission is dominated by the M-dwarf components, and the systems have optical colors and discovery light curves consistent with being Jupiter-radius transiting planets around early M-dwarfs. We detail the PTF/M-dwarf transiting planet survey, part of the Palomar Transient Factory (PTF). We present a graphics processing unit (GPU)-based box-least-squares search for transits that runs approximately 8 × faster than similar algorithms implemented on general purpose systems. For the discovered systems, we decompose low-resolution spectra of the systems into white-dwarf and M-dwarf components, and use radial velocity measurements and cooling models to estimate masses and radii for the white dwarfs. The systems are compact, with periods between 0.35 and 0.45days and semimajor axes of approximately 2 R ⊙ (0.01AU). The M-dwarfs have masses of approximately 0.35 M ⊙, and the white dwarfs have hydrogen-rich atmospheres with temperatures of around 8000K and have masses of approximately 0.5 M ⊙. We use the Robo-AO laser guide star adaptive optics system to tentatively identify one of the objects as a triple system. We also use high-cadence photometry to put an upper limit on the white-dwarf radius of 0.025 R ⊙ (95% confidence) in one of the systems. Accounting for our detection efficiency and geometric factors, we estimate that (90% confidence) of M-dwarfs are in these short-period, post-common-envelope white-dwarf/M-dwarf binaries where the optical light is dominated by the M-dwarf. The lack of detections at shorter periods, despite near-100% detection efficiency for such systems, suggests that binaries including these relatively low-temperature white dwarfs are preferentially found at relatively large orbital radii. Similar eclipsing binary systems can have arbitrarily small eclipse depths in red bands and generate plausible small-planet-transit light curves. As such, these systems are a source of false positives for M-dwarf transiting planet searches. We present several ways to rapidly distinguish these binaries from transiting planet systems.

KW - binaries: eclipsing

KW - methods: data analysis

KW - planets and satellites: detection

KW - stars: low-mass

KW - techniques: photometric

KW - white dwarfs

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U2 - 10.1088/0004-637X/757/2/133

DO - 10.1088/0004-637X/757/2/133

M3 - مقالة

SN - 0004-637X

VL - 757

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 2

M1 - 133

ER -

Three new eclipsing white-dwarf-M-dwarf binaries discovered in a search for transiting planets around M-dwarfs

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Keywords

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