Centaurs (scatterers) as a Probe of the Inner Oort Cloud. Nathan Kaib University of Oklahoma

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Centaurs (scatterers) as a Probe of the Inner Oort Cloud Nathan Kaib University of Oklahoma

Outline Scatterer dynamics background/motivation OSSOS / survey simulator Numerical simulations of scatterer production Results and conclusions

Outline Scatterer dynamics background/motivation OSSOS / survey simulator Numerical simulations of scatterer production Results and conclusions

Scattering Object Defintion Look for any orbit with a < 10 3 AU Integrate orbits in the presence of the giant planets for 10 Myrs If semimajor axis changes by 1.5 AU or more it is considered actively scattering off planets (Gladman et al. 2008)

Semimajor Axis (AU) Pericenter (AU) Kaib & Quinn (2009) Expect comparable LPC contributions from all regions Would be nice to have an additional constraint with a > ~5000 AU (Kaib & Quinn 2009)

a ~10 3 AU Pathway outlined in Emel yanenko et al. (2005)

Semimajor Axis (AU) 2000 OO67 2006 SQ372 log (OC:KB production ratio) Pericenter (AU) Kaib et al. (2009) Both objects are more likely to be from Oort cloud

a change timescale q change timescale Timescale (yr) N a < 800 AU 20 < q < 30 AU ainitial (AU) Kaib et al. (2009) Centaurs/scatterers almost exclusively constrain inner 10 4 AU of Oort cloud Also probe a larger size range than LPCs

Semimajor Axis (AU) 2000 OO67 2006 SQ372 log (OC:KB production ratio) Pericenter (AU) Kaib et al. (2009) Both objects are more likely to be from Oort cloud

Brasser et al. (2012) 13 centaurs/scattering objects have inclination over 65 Expect low-i objects from the Kuiper belt Higher-i objects may be from Oort cloud

KB centaurs OC centaurs Brasser et al. (2012)

Caveats Centaurs database compiled with an amalgam of different surveys with different biases Many of the surveys detection limits and pointings are not published We have no idea what the biases in the observational sample are

Outline Scatterer dynamics background/motivation OSSOS / survey simulator Numerical simulations of scatterer production Results and conclusions

Bannister et al. (2016) Outer Solar System Origins Survey

Bannister et al. (2016) Outer Solar System Origins Survey Observe 148 sq. degrees of sky between 2013 and 2017 By embedding thousands of artificial PSFs, detection efficiency as a function of magnitude is known for each field Typical limiting magnitudes are ~24

CFEPS 321 sq. degrees HiLat 600 sq. degrees Alexandersen et al. (2014) 32 sq. degrees

Survey Simulator Observations of 1100 square degrees are highly characterized Survey simulator is constructed from this Given an orbital track, albedo, and size, simulator predicts whether it is detected

Outline Scatterer dynamics background/motivation OSSOS / survey simulator Numerical simulations of scatterer production Results and conclusions

Simulations Model the formation of the Kuiper belt - Collect centaurs/scatterers produced from diffusion from the Kuiper belt Model the formation of the Oort cloud - Collect centaurs/scatterers produced from reinjected Oort cloud orbits

Kuiper Belt Simulations Based on Nesvorny (2015) Migrating Neptune that jumps 0.5 AU at t = 10 Myrs 10 6 particles Integrated for 4 Gyrs with SWIFT RMVS4 (Levison & Duncan 1994)

Oort Cloud Simulations 2000 particles Cloned 10x when they attain a>100 AU and again at q>45 AU Static planets and static galactic environment Integrated for 4 Gyrs with SCATR (Kaib et al. 2011)

Outline Scatterer dynamics background/motivation OSSOS / survey simulator Numerical simulations of scatterer production Results and conclusions

Building distributions Cull simulations for particles with a < 10 3 AU and q < 40 AU for last 500 Mrs If particle s semimajor axis changes by 1.5 AU after 10-Myr integration classify it as scattering Build separate orbital databases for Kuiper belt and Oort Cloud simulations

Draw from orbital distribution Draw from size/albedo distribution (Shankman et al. 2016) Run through survey simulator Detected Undetected Add to observed distribution Throw away Repeat until 1000 detections are generated

Kuiper Belt Distribution

Oort Cloud Distribution

Oort But cloud Kuiper supplies belt centaur/scatter between 1/4 production and 2/3 of all is centaurs about 500x and more efficient scattering than objects Oort cloud

These ratios are not ruled about by a- or q-distributions

Conclusions Kuiper belt cannot be sole source of centaurs/ scattering objects If we assume a uniform size distribution, survey detections favor a OC:KB population ratio of ~500:1 This ignores effects of a distant super-earth (Batygin & Brown 2016), but initial results don t indicate this will replicate scattering inclinations

Complications of Planet 9 500,000 particles Static planets and static galactic environment Planet 9 with q = 250 AU, a = 500 AU (Batygin & Brown 2016) Integrated for 4 Gyrs with SWIFT RMVS4

Raw Distributions Lawler et al., in prep

Planet 9 Distribution p-value = 10-4 Lawler et al., in prep

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