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AU Microscopii

February 18, 2024

AU Microscopii (AU Mic) is a young red dwarf star located 31.7 light-years (9.7 parsecs) away – about 8 times as far as the closest star after the Sun.[5] The apparent visual magnitude of AU Microscopii is 8.73,[2] which is too dim to be seen with the naked eye. It was given this designation because it is in the southern constellation Microscopium and is a variable star. Like β Pictoris, AU Microscopii has a circumstellar disk of dust known as a debris disk and at least two exoplanets, with the presence of an additional two planets being likely.[6][3]

AU Microscopii

AU Microscopii, J band image, 2MASS.
Observation data
Epoch J2000      Equinox J2000
Constellation Microscopium
Right ascension 20h 45m 09.53250s[1]
Declination –31° 20′ 27.2379″[1]
Apparent magnitude (V) 8.73[2]
Characteristics
Spectral type M1Ve[2]
Apparent magnitude (V) 8.627±0.052[3]
Apparent magnitude (J) 5.436±0.017[3]
U−B color index 1.01
B−V color index 1.45
Variable type Flare star
Astrometry
Radial velocity (Rv)−6.90±0.37[1] km/s
Proper motion (μ) RA: +281.319 mas/yr[1]
Dec.: -360.148 mas/yr[1]
Parallax (π)102.9432 ± 0.0231 mas[1]
Distance31.683 ± 0.007 ly
(9.714 ± 0.002 pc)
Absolute magnitude (MV)8.61
Details
Mass0.60±0.04[3] M
Radius0.82±0.02[3] R
Luminosity0.102±0.002[3] L
Surface gravity (log g)4.52±0.05[3] cgs
Temperature3665±31[3] K
Rotation4.8367±0.0006 d[4]
Rotational velocity (v sin i)8.5±0.2[3] km/s
Age23±3, 18.5±2.4[3] Myr
Other designations
CD -31°17815, GCTP 4939.00, GJ 803, HD 197481, HIP 102409, LTT 8214, SAO 212402, Vys 824, LDS 720 A.
Database references
SIMBADdata
ARICNSdata

Stellar properties edit

AU Mic is a young star at only 22 million years old; less than 1% of the age of the Sun.[7] With a stellar classification of M1 Ve,[2] it is a red dwarf star[8] with a physical radius of 75% that of the Sun. Despite being half the Sun's mass,[9][10] it is radiating only 9%[11] as much luminosity as the Sun. This energy is being emitted from the star's outer atmosphere at an effective temperature of 3,700 K, giving it the cool orange-red hued glow of an M-type star.[12] AU Microscopii is a member of the β Pictoris moving group.[13][14] AU Microscopii may be gravitationally bound to the binary star system AT Microscopii.[15]

 
A light curve for AU Microscopii, plotted from TESS data[16]

AU Microscopii has been observed in every part of the electromagnetic spectrum from radio to X-ray and is known to undergo flaring activity at all these wavelengths.[17][18][19][20] Its flaring behaviour was first identified in 1973.[21][22] Underlying these random outbreaks is a nearly sinusoidal variation in its brightness with a period of 4.865 days. The amplitude of this variation changes slowly with time. The V band brightness variation was approximately 0.3 magnitudes in 1971; by 1980 it was merely 0.1 magnitudes.[23]

Planetary system edit

AU Microscopii's debris disk has an asymmetric structure and an inner gap or hole cleared of debris, which has led a number of astronomers to search for planets orbiting AU Microscopii. By 2007, no searches had led to any detections of planets.[24][25] However, in 2020 the discovery of a Neptune-sized planet was announced based on transit observations by TESS.[7] Its rotation axis is well aligned with the rotation axis of the parent star, with the misalignment being equal to 5+16
−15°.[26]

Since 2018, a second planet, AU Microscopii c, was suspected to exist. It was confirmed in December 2020, after additional transit events were documented by the TESS observatory.[27]

A third planet in the system was suspected since 2022 based on transit-timing variations,[28] and "validated" in 2023, although several possible orbital periods of planet d cannot be ruled out yet. This planet has a mass comparable to that of Earth.[6] Radial velocity observations have also found evidence for a fourth, outer planet as of 2023.[3]

The AU Microscopii planetary system[27][29][6][3]
Companion
(in order from star) 		Mass Semimajor axis
(AU) 		Orbital period
(days) 		Eccentricity Inclination Radius
b 10.2+3.9
−2.7 M🜨 		0.0645±0.0013 8.4630351±0.0000003 0.00021±0.00006 89.9904+0.0036
−0.0019° 		4.07±0.17 R🜨
d (unconfirmed) 1.014±0.146 M 12.73812±0.00128 0.00097±0.00042 88.10±0.43°
c 14.2+4.8
−3.5 M🜨 		0.1101±0.0020 18.85901±0.00009 0.01056±0.00089 89.589+0.058
−0.068° 		3.24±0.16 R🜨
e (unconfirmed) 35.2+6.7
−5.4 M 		33.39±0.10
Debris disk <50–>150 AU

Debris disk edit

 
Hubble Space Telescope image of the debris disk around AU Microscopii.
This short time lapse sequence shows images of the debris disc.

AU Microscopii harbors its own disk of dust, first resolved at optical wavelengths in 2003 by Paul Kalas and collaborators using the University of Hawaii 2.2-m telescope on Mauna Kea, Hawaii.[5] This large debris disk faces the earth edge-on,[30] and measures at least 200 AU in radius. At these large distances from the star, the lifetime of dust in the disk exceeds the age of AU Microscopii.[5] The disk has a gas to dust mass ratio of no more than 6:1, much lower than the usually assumed primordial value of 100:1.[31] The debris disk is therefore referred to as "gas-poor". The total amount of dust visible in the disk is estimated to be at least a lunar mass, while the larger planetesimals from which the dust is produced are inferred to have at least six lunar masses.[32]

The spectral energy distribution of AU Microscopii's debris disk at submillimetre wavelengths indicate the presence of an inner hole in the disk extending to 17 AU,[33] while scattered light images estimate the inner hole to be 12 AU in radius.[34] Combining the spectral energy distribution with the surface brightness profile yields a smaller estimate of the radius of the inner hole, 1 - 10 AU.[24]

The inner part of the disk is asymmetric and shows structure in the inner 40 AU.[35] The inner structure has been compared with that expected to be seen if the disk is influenced by larger bodies or has undergone recent planet formation.[35]

The surface brightness (brightness per area) of the disk in the near infrared   as a function of projected distance   from the star follows a characteristic shape. The inner   of the disk appear approximately constant in density and the brightness is unchanging, more-or-less flat.[34] Around   the density and surface brightness begins to decrease: first it decreases slowly in proportion to distance as  ; then outside  , the density and brightness drops much more steeply, as  .[34] This "broken power-law" shape is similar to the shape of the profile of β Pic's disk.

In October 2015 it was reported that astronomers using the Very Large Telescope (VLT) had detected very unusual outward-moving features in the disk. By comparing the VLT images with those taken by the Hubble Space Telescope in 2010 and 2011 it was found that the wave-like structures are moving away from the star at speeds of up to 10 kilometers per second (22,000 miles per hour). The waves farther away from the star seem to be moving faster than those close to it, and at least three of the features are moving fast enough to escape the gravitational pull of the star.[36]

Methods of observation edit

 
Artist's impression of AU Microscopii Credit: NASA/ESA/G. Bacon (STScI)

AU Mic's disk has been observed at a variety of different wavelengths, giving humans different types of information about the system. The light from the disk observed at optical wavelengths is stellar light that has reflected (scattered) off dust particles into Earth's line of sight. Observations at these wavelengths utilize a coronagraphic spot to block the bright light coming directly from the star. Such observations provide high-resolution images of the disk. Because light having a wavelength longer than the size of a dust grain is scattered only poorly, comparing images at different wavelengths (visible and near-infrared, for example) gives humans information about the sizes of the dust grains in the disk.[37]

 
Hubble observations of blobs of material sweeping through stellar disc.[38]

Optical observations have been made with the Hubble Space Telescope and Keck Telescopes. The system has also been observed at infrared and sub-millimeter wavelengths. This light is emitted directly by dust grains as a result of their internal heat (modified blackbody radiation). The disk cannot be resolved at these wavelengths, so such observations are measurements of the amount of light coming from the entire system. Observations at increasingly longer wavelengths give information about dust particles of larger sizes and at larger distances from the star. These observations have been made with the James Clerk Maxwell Telescope and Spitzer Space Telescope.

 
James Webb Space Telescope has imaged (Au Mic) the inner workings of a dusty disk surrounding a nearby red dwarf star. [39]

See also edit


References edit

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External links edit

 
Wikimedia Commons has media related to AU Microscopii.
  • "AU and AT Microscopii AB". SolStation. 2004. from the original on 11 November 2006. Retrieved 2006-12-20.

February 18, 2024
microscopii, young, dwarf, star, located, light, years, parsecs, away, about, times, closest, star, after, apparent, visual, magnitude, which, seen, with, naked, given, this, designation, because, southern, constellation, microscopium, variable, star, like, pi. AU Microscopii AU Mic is a young red dwarf star located 31 7 light years 9 7 parsecs away about 8 times as far as the closest star after the Sun 5 The apparent visual magnitude of AU Microscopii is 8 73 2 which is too dim to be seen with the naked eye It was given this designation because it is in the southern constellation Microscopium and is a variable star Like b Pictoris AU Microscopii has a circumstellar disk of dust known as a debris disk and at least two exoplanets with the presence of an additional two planets being likely 6 3 AU MicroscopiiAU Microscopii J band image 2MASS Observation dataEpoch J2000 Equinox J2000Constellation MicroscopiumRight ascension 20h 45m 09 53250s 1 Declination 31 20 27 2379 1 Apparent magnitude V 8 73 2 CharacteristicsSpectral type M1Ve 2 Apparent magnitude V 8 627 0 052 3 Apparent magnitude J 5 436 0 017 3 U B color index 1 01B V color index 1 45Variable type Flare starAstrometryRadial velocity Rv 6 90 0 37 1 km sProper motion m RA 281 319 mas yr 1 Dec 360 148 mas yr 1 Parallax p 102 9432 0 0231 mas 1 Distance31 683 0 007 ly 9 714 0 002 pc Absolute magnitude MV 8 61DetailsMass0 60 0 04 3 M Radius0 82 0 02 3 R Luminosity0 102 0 002 3 L Surface gravity log g 4 52 0 05 3 cgsTemperature3665 31 3 KRotation4 8367 0 0006 d 4 Rotational velocity v sin i 8 5 0 2 3 km sAge23 3 18 5 2 4 3 MyrOther designationsCD 31 17815 GCTP 4939 00 GJ 803 HD 197481 HIP 102409 LTT 8214 SAO 212402 Vys 824 LDS 720 A Database referencesSIMBADdataARICNSdata Contents 1 Stellar properties 2 Planetary system 2 1 Debris disk 3 Methods of observation 4 See also 5 References 6 External linksStellar properties editAU Mic is a young star at only 22 million years old less than 1 of the age of the Sun 7 With a stellar classification of M1 Ve 2 it is a red dwarf star 8 with a physical radius of 75 that of the Sun Despite being half the Sun s mass 9 10 it is radiating only 9 11 as much luminosity as the Sun This energy is being emitted from the star s outer atmosphere at an effective temperature of 3 700 K giving it the cool orange red hued glow of an M type star 12 AU Microscopii is a member of the b Pictoris moving group 13 14 AU Microscopii may be gravitationally bound to the binary star system AT Microscopii 15 nbsp A light curve for AU Microscopii plotted from TESS data 16 AU Microscopii has been observed in every part of the electromagnetic spectrum from radio to X ray and is known to undergo flaring activity at all these wavelengths 17 18 19 20 Its flaring behaviour was first identified in 1973 21 22 Underlying these random outbreaks is a nearly sinusoidal variation in its brightness with a period of 4 865 days The amplitude of this variation changes slowly with time The V band brightness variation was approximately 0 3 magnitudes in 1971 by 1980 it was merely 0 1 magnitudes 23 Planetary system editAU Microscopii s debris disk has an asymmetric structure and an inner gap or hole cleared of debris which has led a number of astronomers to search for planets orbiting AU Microscopii By 2007 no searches had led to any detections of planets 24 25 However in 2020 the discovery of a Neptune sized planet was announced based on transit observations by TESS 7 Its rotation axis is well aligned with the rotation axis of the parent star with the misalignment being equal to 5 16 15 26 Since 2018 a second planet AU Microscopii c was suspected to exist It was confirmed in December 2020 after additional transit events were documented by the TESS observatory 27 A third planet in the system was suspected since 2022 based on transit timing variations 28 and validated in 2023 although several possible orbital periods of planet d cannot be ruled out yet This planet has a mass comparable to that of Earth 6 Radial velocity observations have also found evidence for a fourth outer planet as of 2023 3 The AU Microscopii planetary system 27 29 6 3 Companion in order from star Mass Semimajor axis AU Orbital period days Eccentricity Inclination Radiusb 10 2 3 9 2 7 M 0 0645 0 0013 8 4630351 0 0000003 0 00021 0 00006 89 9904 0 0036 0 0019 4 07 0 17 R d unconfirmed 1 014 0 146 M 12 73812 0 00128 0 00097 0 00042 88 10 0 43 c 14 2 4 8 3 5 M 0 1101 0 0020 18 85901 0 00009 0 01056 0 00089 89 589 0 058 0 068 3 24 0 16 R e unconfirmed 35 2 6 7 5 4 M 33 39 0 10 Debris disk lt 50 gt 150 AU Debris disk edit nbsp Hubble Space Telescope image of the debris disk around AU Microscopii source source source source source source source source This short time lapse sequence shows images of the debris disc AU Microscopii harbors its own disk of dust first resolved at optical wavelengths in 2003 by Paul Kalas and collaborators using the University of Hawaii 2 2 m telescope on Mauna Kea Hawaii 5 This large debris disk faces the earth edge on 30 and measures at least 200 AU in radius At these large distances from the star the lifetime of dust in the disk exceeds the age of AU Microscopii 5 The disk has a gas to dust mass ratio of no more than 6 1 much lower than the usually assumed primordial value of 100 1 31 The debris disk is therefore referred to as gas poor The total amount of dust visible in the disk is estimated to be at least a lunar mass while the larger planetesimals from which the dust is produced are inferred to have at least six lunar masses 32 The spectral energy distribution of AU Microscopii s debris disk at submillimetre wavelengths indicate the presence of an inner hole in the disk extending to 17 AU 33 while scattered light images estimate the inner hole to be 12 AU in radius 34 Combining the spectral energy distribution with the surface brightness profile yields a smaller estimate of the radius of the inner hole 1 10 AU 24 The inner part of the disk is asymmetric and shows structure in the inner 40 AU 35 The inner structure has been compared with that expected to be seen if the disk is influenced by larger bodies or has undergone recent planet formation 35 The surface brightness brightness per area of the disk in the near infrared I displaystyle scriptstyle I nbsp as a function of projected distance r displaystyle scriptstyle r nbsp from the star follows a characteristic shape The inner r lt 15 A U displaystyle scriptstyle r lt 15AU nbsp of the disk appear approximately constant in density and the brightness is unchanging more or less flat 34 Around r 15 A U displaystyle scriptstyle r approx 15AU nbsp the density and surface brightness begins to decrease first it decreases slowly in proportion to distance as I r 1 8 displaystyle scriptstyle I propto r 1 8 nbsp then outside r 43 A U displaystyle scriptstyle r approx 43AU nbsp the density and brightness drops much more steeply as I r 4 7 displaystyle scriptstyle I propto r 4 7 nbsp 34 This broken power law shape is similar to the shape of the profile of b Pic s disk In October 2015 it was reported that astronomers using the Very Large Telescope VLT had detected very unusual outward moving features in the disk By comparing the VLT images with those taken by the Hubble Space Telescope in 2010 and 2011 it was found that the wave like structures are moving away from the star at speeds of up to 10 kilometers per second 22 000 miles per hour The waves farther away from the star seem to be moving faster than those close to it and at least three of the features are moving fast enough to escape the gravitational pull of the star 36 Methods of observation edit nbsp Artist s impression of AU Microscopii Credit NASA ESA G Bacon STScI AU Mic s disk has been observed at a variety of different wavelengths giving humans different types of information about the system The light from the disk observed at optical wavelengths is stellar light that has reflected scattered off dust particles into Earth s line of sight Observations at these wavelengths utilize a coronagraphic spot to block the bright light coming directly from the star Such observations provide high resolution images of the disk Because light having a wavelength longer than the size of a dust grain is scattered only poorly comparing images at different wavelengths visible and near infrared for example gives humans information about the sizes of the dust grains in the disk 37 nbsp Hubble observations of blobs of material sweeping through stellar disc 38 Optical observations have been made with the Hubble Space Telescope and Keck Telescopes The system has also been observed at infrared and sub millimeter wavelengths This light is emitted directly by dust grains as a result of their internal heat modified blackbody radiation The disk cannot be resolved at these wavelengths so such observations are measurements of the amount of light coming from the entire system Observations at increasingly longer wavelengths give information about dust particles of larger sizes and at larger distances from the star These observations have been made with the James Clerk Maxwell Telescope and Spitzer Space Telescope nbsp James Webb Space Telescope has imaged Au Mic the inner workings of a dusty disk surrounding a nearby red dwarf star 39 See also editList of exoplanets discovered in 2020 AU Microscopii b and c List of exoplanets discovered in 2023 AU Microscopii dReferences edit a b c d e Vallenari A et al Gaia collaboration 2023 Gaia Data Release 3 Summary of the content and survey properties Astronomy and Astrophysics 674 A1 arXiv 2208 00211 Bibcode 2023A amp A 674A 1G doi 10 1051 0004 6361 202243940 S2CID 244398875 Gaia DR3 record for this source at VizieR a b c d Torres C A O et al December 2006 Search for associations containing young stars SACY I Sample and searching method Astronomy and Astrophysics 460 3 695 708 arXiv astro ph 0609258 Bibcode 2006A amp A 460 695T doi 10 1051 0004 6361 20065602 S2CID 16080025 a b c d e f g h i j k l Donati J F Cristofari P I Finociety B et al 24 April 2023 The magnetic field and multiple planets of the young dwarf AU Mic Monthly Notices of the Royal Astronomical Society 525 455 475 arXiv 2304 09642 doi 10 1093 mnras stad1193 ISSN 0035 8711 S2CID 258212637 Szabo Gy M Gandolfi D et al October 2021 The changing face of AU Mic b stellar spots spin orbit commensurability and transit timing variations as seen by CHEOPS and TESS Astronomy amp Astrophysics 654 A159 arXiv 2108 02149 Bibcode 2021A amp A 654A 159S doi 10 1051 0004 6361 202140345 S2CID 236912985 a b c Kalas Paul Liu Michael C Matthews Brenda C 26 March 2004 Discovery of a Large Dust Disk Around the Nearby Star AU Microscopii Science 303 5666 1990 1992 arXiv astro ph 0403132 Bibcode 2004Sci 303 1990K doi 10 1126 science 1093420 PMID 14988511 S2CID 6943137 a b c Wittrock Justin M et al 2023 Validating AU Microscopii d with Transit Timing Variations The Astronomical Journal 166 6 232 arXiv 2302 04922 Bibcode 2023AJ 166 232W doi 10 3847 1538 3881 acfda8 a b Plavchan Peter Barclay Thomas Gagne Jonathan et al 2020 A planet within the debris disk around the pre main sequence star AU Microscopii Nature 582 7813 497 500 arXiv 2006 13248 Bibcode 2020Natur 582 497P doi 10 1038 s41586 020 2400 z PMC 7323865 PMID 32581383 Maran S P et al September 1991 An Investigation of the Flare Star AU Mic with the Goddard High Resolution Spectrograph on the Hubble Space Telescope Bulletin of the American Astronomical Society 23 1382 Bibcode 1991BAAS 23 1382M Del Zanna G Landini M Mason H E April 2002 Spectroscopic diagnostics of stellar transition regions and coronae in the XUV AU Mic in quiescence PDF Astronomy and Astrophysics 385 3 968 985 Bibcode 2002A amp A 385 968D doi 10 1051 0004 6361 20020164 Mouillet David 26 March 2004 Nearby Planetary Disks Science 303 5666 1982 1983 doi 10 1126 science 1095851 PMID 15044792 S2CID 118888307 Plavchan Peter et al June 2009 New Debris Disks Around Young Low Mass Stars Discovered with the Spitzer Space Telescope The Astrophysical Journal 698 2 1068 1094 arXiv 0904 0819 Bibcode 2009ApJ 698 1068P doi 10 1088 0004 637X 698 2 1068 S2CID 51417657 The Colour of Stars Australia Telescope Outreach and Education Commonwealth Scientific and Industrial Research Organisation December 21 2004 archived from the original on February 22 2012 retrieved 2012 01 16 Zuckerman B Song Inseok September 2004 Young Stars Near the Sun Annual Review of Astronomy amp Astrophysics 42 1 685 721 Bibcode 2004ARA amp A 42 685Z doi 10 1146 annurev astro 42 053102 134111 S2CID 34114530 Barrado y Navascues David et al August 1 1999 The age of beta Pictoris The Astrophysical Journal 520 2 L123 L126 arXiv astro ph 9905242 Bibcode 1999ApJ 520L 123B doi 10 1086 312162 S2CID 119365418 Monsignori Fossi B C et al October 1995 The EUV spectrum of AT Microscopii Astronomy amp Astrophysics 302 193 Bibcode 1995A amp A 302 193M MAST Barbara A Mikulski Archive for Space Telescopes Space Telescope Science Institute Retrieved 8 December 2021 Maran S P et al 1 February 1994 Observing stellar coronae with the Goddard High Resolution Spectrograph 1 The dMe star AU microscopoii The Astrophysical Journal 421 2 800 808 Bibcode 1994ApJ 421 800M doi 10 1086 173692 Cully Scott L et al September 10 1993 Extreme Ultraviolet Explorer deep survey observations of a large flare on AU Microscopii The Astrophysical Journal 414 2 L49 L52 Bibcode 1993ApJ 414L 49C doi 10 1086 186993 Kundu M R et al 15 January 1987 Microwave observations of the flare stars UV Ceti AT Microscopii and AU Microscopii The Astrophysical Journal 312 822 829 Bibcode 1987ApJ 312 822K doi 10 1086 164928 Tsikoudi V Kellett B J December 2000 ROSAT All Sky Survey X ray and EUV observations of YY Gem and AU Mic Monthly Notices of the Royal Astronomical Society 319 4 1147 1153 Bibcode 2000MNRAS 319 1147T doi 10 1046 j 1365 8711 2000 03905 x Kunkel W E 1973 Activity in Flare Stars in the Solar Neighborhood The Astrophysical Journal Supplement 25 1 Bibcode 1973ApJS 25 1K doi 10 1086 190263 Butler C J et al December 1981 Ultraviolet spectra of dwarf solar neighbourhood stars I Monthly Notices of the Royal Astronomical Society 197 3 815 827 Bibcode 1981MNRAS 197 815B doi 10 1093 mnras 197 3 815 Butler C J et al March 1987 Rotational modulation and flares on RS CVn and BY DRA systems II IUE observations of BY Draconis and AU Microscopii Astronomy and Astrophysics 174 1 2 139 157 Bibcode 1987A amp A 174 139B a b Stanimir A Metchev Joshua A Eisner amp Lynne A Hillenbrand March 20 2005 Adaptive Optics Imaging of the AU Microscopii Circumstellar Disk Evidence for Dynamical Evolution The Astrophysical Journal 622 1 451 462 arXiv astro ph 0412143 Bibcode 2005ApJ 622 451M doi 10 1086 427869 S2CID 16455262 E Masciadri R Mundt Th Henning amp C Alvarez 1 June 2005 A Search for Hot Massive Extrasolar Planets around Nearby Young Stars with the Adaptive Optics System NACO The Astrophysical Journal 625 2 1004 1018 arXiv astro ph 0502376 Bibcode 2005ApJ 625 1004M doi 10 1086 429687 S2CID 15070805 Addison Brett C Horner Jonathan Wittenmyer Robert A Plavchan Peter Wright Duncan J Nicholson Belinda A Marshall Jonathan P Clark Jake T Kane Stephen R Hirano Teruyuki Kielkopf John Shporer Avi Tinney C G Zhang Hui Ballard Sarah Bedding Timothy Bowler Brendan P Mengel Matthew W Okumura Jack Gaidos Eric 2021 The Youngest Planet to Have a Spin Orbit Alignment Measurement AU Mic B The Astronomical Journal 162 4 137 arXiv 2006 13675 Bibcode 2021AJ 162 137A doi 10 3847 1538 3881 ac1685 S2CID 220041674 a b Martioli E Hebrard G Correia A C M Laskar J Lecavelier Des Etangs A 2021 New constraints on the planetary system around the young active star AU Mic Astronomy amp Astrophysics 649 A177 arXiv 2012 13238 doi 10 1051 0004 6361 202040235 S2CID 229371309 Wittrock Justin M et al 2022 Transit Timing Variations for AU Microscopii b and C The Astronomical Journal 164 1 27 arXiv 2202 05813 Bibcode 2022AJ 164 27W doi 10 3847 1538 3881 ac68e5 S2CID 245001008 Cale Bryson L et al 1 December 2021 Diving Beneath the Sea of Stellar Activity Chromatic Radial Velocities of the Young AU Mic Planetary System The Astronomical Journal 162 6 295 arXiv 2109 13996 Bibcode 2021AJ 162 295C doi 10 3847 1538 3881 ac2c80 Paul Kalas James R Graham and Mark Clampin 23 June 2005 A planetary system as the origin of structure in Fomalhaut s dust belt Nature 435 7045 1067 1070 arXiv astro ph 0506574 Bibcode 2005Natur 435 1067K doi 10 1038 nature03601 PMID 15973402 S2CID 4406070 Aki Roberge Alycia J Weinberger Seth Redfield amp Paul D Feldman 20 June 2005 Rapid Dissipation of Primordial Gas from the AU Microscopii Debris Disk The Astrophysical Journal 626 2 L105 L108 arXiv astro ph 0505302 Bibcode 2005ApJ 626L 105R doi 10 1086 431899 S2CID 367734 C H Chen B M Patten M W Werner C D Dowell K R Stapelfeldt I Song J R Stauffer M Blaylock K D Gordon amp V Krause December 1 2005 A Spitzer Study of Dusty Disks around Nearby Young Stars The Astrophysical Journal 634 2 1372 1384 Bibcode 2005ApJ 634 1372C doi 10 1086 497124 Michael C Liu Brenda C Matthews Jonathan P Williams amp Paul G Kalas June 10 2004 A Submillimeter Search of Nearby Young Stars for Cold Dust Discovery of Debris Disks around Two Low Mass Stars The Astrophysical Journal 608 1 526 532 arXiv astro ph 0403131 Bibcode 2004ApJ 608 526L doi 10 1086 392531 S2CID 9178164 a b c John E Kirst D R Ardila D A Golimowski M Clampin H C Ford G D Illingworth G F Hartig F Bartko N Benitez J P Blakeslee R J Bouwens L D Bradley T J Broadhurst R A Brown C J Burrows E S Cheng N J G Cross R Demarco P D Feldman M Franx T Goto C Gronwall B Holden N Homeier L Infante R A Kimble M P Lesser A R Martel S Mei F Mennanteau G R Meurer G K Miley V Motta M Postman P Rosati M Sirianni W B Sparks H D Tran Z I Tsvetanov R L White amp W Zheng February 2005 Hubble Space Telescope Advanced Camera for Surveys Coronagraphic Imaging of the AU Microscopii Debris Disk The Astronomical Journal 129 2 1008 1017 Bibcode 2005AJ 129 1008K CiteSeerX 10 1 1 561 8393 doi 10 1086 426755 S2CID 53497065 a b Michael C Liu 3 September 2004 Substructure in the Circumstellar Disk Around the Young Star AU Microscopii Science 305 5689 1442 1444 arXiv astro ph 0408164 Bibcode 2004Sci 305 1442L doi 10 1126 science 1102929 PMID 15308766 S2CID 8457455 Mysterious Ripples Found Racing Through Planet Forming Disk Hubblesite Archived from the original on 11 October 2015 Retrieved 8 October 2015 Sanders Robert 2007 01 08 Dust around nearby star like powder snow UC Berkeley News Archived from the original on 15 January 2007 Retrieved 2007 01 11 Hubble captures blobs of material sweeping through stellar disc www spacetelescope org Retrieved 10 January 2019 Dusty Debris Disk Around AU Mic6 October 18 2023 External links edit nbsp Wikimedia Commons has media related to AU Microscopii AU and AT Microscopii AB SolStation 2004 Archived from the original on 11 November 2006 Retrieved 2006 12 20 Retrieved from https en wikipedia org w index php title AU Microscopii amp oldid 1194884237, wikipedia, wiki, book, books, library,

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