BRINGING "tHE MOTH" to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK

Thomas M. Esposito; Michael P. Fitzgerald; James R. Graham; Paul Kalas; Eve J. Lee; Eugene Chiang; Gaspard Duchene; Jason Wang; Maxwell A. Millar-Blanchaer; Eric Nielsen; S. Mark Ammons; Sebastian Bruzzone; Robert J.De Rosa; Zachary H. Draper; Bruce Macintosh; Franck Marchis; Stanimir A. Metchev; Marshall Perrin; Laurent Pueyo; Abhijith Rajan; Fredrik T. Rantakyrö; David Vega; Schuyler Wolff

doi:10.3847/0004-6256/152/4/85

BRINGING "tHE MOTH" to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK

Thomas M. Esposito, Michael P. Fitzgerald, James R. Graham, Paul Kalas, Eve J. Lee, Eugene Chiang, Gaspard Duchene, Jason Wang, Maxwell A. Millar-Blanchaer, Eric Nielsen, S. Mark Ammons, Sebastian Bruzzone, Robert J.De Rosa, Zachary H. Draper, Bruce Macintosh, Franck Marchis, Stanimir A. Metchev, Marshall Perrin, Laurent Pueyo, Abhijith RajanFredrik T. Rantakyrö, David Vega, Schuyler Wolff

Physics and Astronomy

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

27 Scopus citations

Abstract

The HD 61005 debris disk ("The Moth") stands out from the growing collection of spatially resolved circumstellar disks by virtue of its unusual swept-back morphology, brightness asymmetries, and dust ring offset. Despite several suggestions for the physical mechanisms creating these features, no definitive answer has been found. In this work, we demonstrate the plausibility of a scenario in which the disk material is shaped dynamically by an eccentric, inclined planet. We present new Keck NIRC2 scattered-light angular differential imaging of the disk at 1.2-2.3 μm that further constrains its outer morphology (projected separations of 27-135 au). We also present complementary Gemini Planet Imager 1.6 μm total intensity and polarized light detections that probe down to projected separations less than 10 au. To test our planet-sculpting hypothesis, we employed secular perturbation theory to construct parent body and dust distributions that informed scattered-light models. We found that this method produced models with morphological and photometric features similar to those seen in the data, supporting the premise of a planet-perturbed disk. Briefly, our results indicate a disk parent body population with a semimajor axis of 40-52 au and an interior planet with an eccentricity of at least 0.2. Many permutations of planet mass and semimajor axis are allowed, ranging from an Earth mass at 35 au to a Jupiter mass at 5 au.

Original language	English (US)
Article number	85
Journal	Astronomical Journal
Volume	152
Issue number	4
DOIs	https://doi.org/10.3847/0004-6256/152/4/85
State	Published - Oct 2016

Keywords

infrared: planetary systems
planetdisk interactions
stars: individual (HD 61005)
techniques: high angular resolution
techniques: polarimetric

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/0004-6256/152/4/85

Cite this

Esposito, T. M., Fitzgerald, M. P., Graham, J. R., Kalas, P., Lee, E. J., Chiang, E., Duchene, G., Wang, J., Millar-Blanchaer, M. A., Nielsen, E., Ammons, S. M., Bruzzone, S., Rosa, R. J. D., Draper, Z. H., Macintosh, B., Marchis, F., Metchev, S. A., Perrin, M., Pueyo, L., ... Wolff, S. (2016). BRINGING "tHE MOTH" to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK. Astronomical Journal, 152(4), [85]. https://doi.org/10.3847/0004-6256/152/4/85

@article{cc3287fc82ad417482dd457ec729d54f,

title = "BRINGING {"}tHE MOTH{"} to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK",

abstract = "The HD 61005 debris disk ({"}The Moth{"}) stands out from the growing collection of spatially resolved circumstellar disks by virtue of its unusual swept-back morphology, brightness asymmetries, and dust ring offset. Despite several suggestions for the physical mechanisms creating these features, no definitive answer has been found. In this work, we demonstrate the plausibility of a scenario in which the disk material is shaped dynamically by an eccentric, inclined planet. We present new Keck NIRC2 scattered-light angular differential imaging of the disk at 1.2-2.3 μm that further constrains its outer morphology (projected separations of 27-135 au). We also present complementary Gemini Planet Imager 1.6 μm total intensity and polarized light detections that probe down to projected separations less than 10 au. To test our planet-sculpting hypothesis, we employed secular perturbation theory to construct parent body and dust distributions that informed scattered-light models. We found that this method produced models with morphological and photometric features similar to those seen in the data, supporting the premise of a planet-perturbed disk. Briefly, our results indicate a disk parent body population with a semimajor axis of 40-52 au and an interior planet with an eccentricity of at least 0.2. Many permutations of planet mass and semimajor axis are allowed, ranging from an Earth mass at 35 au to a Jupiter mass at 5 au.",

keywords = "infrared: planetary systems, planetdisk interactions, stars: individual (HD 61005), techniques: high angular resolution, techniques: polarimetric",

author = "Esposito, {Thomas M.} and Fitzgerald, {Michael P.} and Graham, {James R.} and Paul Kalas and Lee, {Eve J.} and Eugene Chiang and Gaspard Duchene and Jason Wang and Millar-Blanchaer, {Maxwell A.} and Eric Nielsen and Ammons, {S. Mark} and Sebastian Bruzzone and Rosa, {Robert J.De} and Draper, {Zachary H.} and Bruce Macintosh and Franck Marchis and Metchev, {Stanimir A.} and Marshall Perrin and Laurent Pueyo and Abhijith Rajan and Rantakyr{\"o}, {Fredrik T.} and David Vega and Schuyler Wolff",

year = "2016",

month = oct,

doi = "10.3847/0004-6256/152/4/85",

language = "English (US)",

volume = "152",

journal = "Astronomical Journal",

issn = "0004-6256",

publisher = "IOP Publishing Ltd.",

number = "4",

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Esposito, TM, Fitzgerald, MP, Graham, JR, Kalas, P, Lee, EJ, Chiang, E, Duchene, G, Wang, J, Millar-Blanchaer, MA, Nielsen, E, Ammons, SM, Bruzzone, S, Rosa, RJD, Draper, ZH, Macintosh, B, Marchis, F, Metchev, SA, Perrin, M, Pueyo, L, Rajan, A, Rantakyrö, FT, Vega, D & Wolff, S 2016, 'BRINGING "tHE MOTH" to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK', Astronomical Journal, vol. 152, no. 4, 85. https://doi.org/10.3847/0004-6256/152/4/85

TY - JOUR

T1 - BRINGING "tHE MOTH" to LIGHT

T2 - A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK

AU - Esposito, Thomas M.

AU - Fitzgerald, Michael P.

AU - Graham, James R.

AU - Kalas, Paul

AU - Lee, Eve J.

AU - Chiang, Eugene

AU - Duchene, Gaspard

AU - Wang, Jason

AU - Millar-Blanchaer, Maxwell A.

AU - Nielsen, Eric

AU - Ammons, S. Mark

AU - Bruzzone, Sebastian

AU - Rosa, Robert J.De

AU - Draper, Zachary H.

AU - Macintosh, Bruce

AU - Marchis, Franck

AU - Metchev, Stanimir A.

AU - Perrin, Marshall

AU - Pueyo, Laurent

AU - Rajan, Abhijith

AU - Rantakyrö, Fredrik T.

AU - Vega, David

AU - Wolff, Schuyler

PY - 2016/10

Y1 - 2016/10

N2 - The HD 61005 debris disk ("The Moth") stands out from the growing collection of spatially resolved circumstellar disks by virtue of its unusual swept-back morphology, brightness asymmetries, and dust ring offset. Despite several suggestions for the physical mechanisms creating these features, no definitive answer has been found. In this work, we demonstrate the plausibility of a scenario in which the disk material is shaped dynamically by an eccentric, inclined planet. We present new Keck NIRC2 scattered-light angular differential imaging of the disk at 1.2-2.3 μm that further constrains its outer morphology (projected separations of 27-135 au). We also present complementary Gemini Planet Imager 1.6 μm total intensity and polarized light detections that probe down to projected separations less than 10 au. To test our planet-sculpting hypothesis, we employed secular perturbation theory to construct parent body and dust distributions that informed scattered-light models. We found that this method produced models with morphological and photometric features similar to those seen in the data, supporting the premise of a planet-perturbed disk. Briefly, our results indicate a disk parent body population with a semimajor axis of 40-52 au and an interior planet with an eccentricity of at least 0.2. Many permutations of planet mass and semimajor axis are allowed, ranging from an Earth mass at 35 au to a Jupiter mass at 5 au.

AB - The HD 61005 debris disk ("The Moth") stands out from the growing collection of spatially resolved circumstellar disks by virtue of its unusual swept-back morphology, brightness asymmetries, and dust ring offset. Despite several suggestions for the physical mechanisms creating these features, no definitive answer has been found. In this work, we demonstrate the plausibility of a scenario in which the disk material is shaped dynamically by an eccentric, inclined planet. We present new Keck NIRC2 scattered-light angular differential imaging of the disk at 1.2-2.3 μm that further constrains its outer morphology (projected separations of 27-135 au). We also present complementary Gemini Planet Imager 1.6 μm total intensity and polarized light detections that probe down to projected separations less than 10 au. To test our planet-sculpting hypothesis, we employed secular perturbation theory to construct parent body and dust distributions that informed scattered-light models. We found that this method produced models with morphological and photometric features similar to those seen in the data, supporting the premise of a planet-perturbed disk. Briefly, our results indicate a disk parent body population with a semimajor axis of 40-52 au and an interior planet with an eccentricity of at least 0.2. Many permutations of planet mass and semimajor axis are allowed, ranging from an Earth mass at 35 au to a Jupiter mass at 5 au.

KW - infrared: planetary systems

KW - planetdisk interactions

KW - stars: individual (HD 61005)

KW - techniques: high angular resolution

KW - techniques: polarimetric

UR - http://www.scopus.com/inward/record.url?scp=84991640192&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84991640192&partnerID=8YFLogxK

U2 - 10.3847/0004-6256/152/4/85

DO - 10.3847/0004-6256/152/4/85

M3 - Article

AN - SCOPUS:84991640192

VL - 152

JO - Astronomical Journal

JF - Astronomical Journal

SN - 0004-6256

IS - 4

M1 - 85

ER -

BRINGING "tHE MOTH" to LIGHT: A PLANET-SCULPTING SCENARIO for the HD 61005 DEBRIS DISK

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