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Literature DB >> 27905411

The rapid formation of Sputnik Planitia early in Pluto's history.

Douglas P Hamilton¹, S A Stern², J M Moore³, L A Young².

Abstract

Pluto's Sputnik Planitia is a bright, roughly circular feature that resembles a polar ice cap. It is approximately 1,000 kilometres across and is centred on a latitude of 25 degrees north and a longitude of 175 degrees, almost directly opposite the side of Pluto that always faces Charon as a result of tidal locking. One explanation for its location includes the formation of a basin in a giant impact, with subsequent upwelling of a dense interior ocean. Once the basin was established, ice would naturally have accumulated there. Then, provided that the basin was a positive gravity anomaly (with or without the ocean), true polar wander could have moved the feature towards the Pluto-Charon tidal axis, on the far side of Pluto from Charon. Here we report modelling that shows that ice quickly accumulates on Pluto near latitudes of 30 degrees north and south, even in the absence of a basin, because, averaged over its orbital period, those are Pluto's coldest regions. Within a million years of Charon's formation, ice deposits on Pluto concentrate into a single cap centred near a latitude of 30 degrees, owing to the runaway albedo effect. This accumulation of ice causes a positive gravity signature that locks, as Pluto's rotation slows, to a longitude directly opposite Charon. Once locked, Charon raises a permanent tidal bulge on Pluto, which greatly enhances the gravity signature of the ice cap. Meanwhile, the weight of the ice in Sputnik Planitia causes the crust under it to slump, creating its own basin (as has happened on Earth in Greenland). Even if the feature is now a modest negative gravity anomaly, it remains locked in place because of the permanent tidal bulge raised by Charon. Any movement of the feature away from 30 degrees latitude is countered by the preferential recondensation of ices near the coldest extremities of the cap. Therefore, our modelling suggests that Sputnik Planitia formed shortly after Charon did and has been stable, albeit gradually losing volume, over the age of the Solar System.

Entities: Disease

Year: 2016 PMID： 27905411 DOI： 10.1038/nature20586

Source DB: PubMed Journal: Nature ISSN： 0028-0836 Impact factor: 49.962

12 in total

1. The Pluto system: Initial results from its exploration by New Horizons.

Authors: S A Stern; F Bagenal; K Ennico; G R Gladstone; W M Grundy; W B McKinnon; J M Moore; C B Olkin; J R Spencer; H A Weaver; L A Young; T Andert; J Andrews; M Banks; B Bauer; J Bauman; O S Barnouin; P Bedini; K Beisser; R A Beyer; S Bhaskaran; R P Binzel; E Birath; M Bird; D J Bogan; A Bowman; V J Bray; M Brozovic; C Bryan; M R Buckley; M W Buie; B J Buratti; S S Bushman; A Calloway; B Carcich; A F Cheng; S Conard; C A Conrad; J C Cook; D P Cruikshank; O S Custodio; C M Dalle Ore; C Deboy; Z J B Dischner; P Dumont; A M Earle; H A Elliott; J Ercol; C M Ernst; T Finley; S H Flanigan; G Fountain; M J Freeze; T Greathouse; J L Green; Y Guo; M Hahn; D P Hamilton; S A Hamilton; J Hanley; A Harch; H M Hart; C B Hersman; A Hill; M E Hill; D P Hinson; M E Holdridge; M Horanyi; A D Howard; C J A Howett; C Jackman; R A Jacobson; D E Jennings; J A Kammer; H K Kang; D E Kaufmann; P Kollmann; S M Krimigis; D Kusnierkiewicz; T R Lauer; J E Lee; K L Lindstrom; I R Linscott; C M Lisse; A W Lunsford; V A Mallder; N Martin; D J McComas; R L McNutt; D Mehoke; T Mehoke; E D Melin; M Mutchler; D Nelson; F Nimmo; J I Nunez; A Ocampo; W M Owen; M Paetzold; B Page; A H Parker; J W Parker; F Pelletier; J Peterson; N Pinkine; M Piquette; S B Porter; S Protopapa; J Redfern; H J Reitsema; D C Reuter; J H Roberts; S J Robbins; G Rogers; D Rose; K Runyon; K D Retherford; M G Ryschkewitsch; P Schenk; E Schindhelm; B Sepan; M R Showalter; K N Singer; M Soluri; D Stanbridge; A J Steffl; D F Strobel; T Stryk; M E Summers; J R Szalay; M Tapley; A Taylor; H Taylor; H B Throop; C C C Tsang; G L Tyler; O M Umurhan; A J Verbiscer; M H Versteeg; M Vincent; R Webbert; S Weidner; G E Weigle; O L White; K Whittenburg; B G Williams; K Williams; S Williams; W W Woods; A M Zangari; E Zirnstein
Journal: Science Date: 2015-10-16 Impact factor: 47.728

2. Formation of Iapetus' extreme albedo dichotomy by exogenically triggered thermal ice migration.

Authors: John R Spencer; Tilmann Denk
Journal: Science Date: 2009-12-10 Impact factor: 47.728

3. Resonant interactions and chaotic rotation of Pluto's small moons.

Authors: M R Showalter; D P Hamilton
Journal: Nature Date: 2015-06-04 Impact factor: 49.962

4. Reorientation and faulting of Pluto due to volatile loading within Sputnik Planitia.

Authors: James T Keane; Isamu Matsuyama; Shunichi Kamata; Jordan K Steckloff
Journal: Nature Date: 2016-11-16 Impact factor: 49.962

5. Reorientation of Sputnik Planitia implies a subsurface ocean on Pluto.

Authors: F Nimmo; D P Hamilton; W B McKinnon; P M Schenk; R P Binzel; C J Bierson; R A Beyer; J M Moore; S A Stern; H A Weaver; C B Olkin; L A Young; K E Smith
Journal: Nature Date: 2016-11-16 Impact factor: 49.962

6. Pluto's interaction with its space environment: Solar wind, energetic particles, and dust.

Authors: F Bagenal; M Horányi; D J McComas; R L McNutt; H A Elliott; M E Hill; L E Brown; P A Delamere; P Kollmann; S M Krimigis; M Kusterer; C M Lisse; D G Mitchell; M Piquette; A R Poppe; D F Strobel; J R Szalay; P Valek; J Vandegriff; S Weidner; E J Zirnstein; S A Stern; K Ennico; C B Olkin; H A Weaver; L A Young
Journal: Science Date: 2016-03-18 Impact factor: 47.728

7. Surface compositions across Pluto and Charon.

Authors: W M Grundy; R P Binzel; B J Buratti; J C Cook; D P Cruikshank; C M Dalle Ore; A M Earle; K Ennico; C J A Howett; A W Lunsford; C B Olkin; A H Parker; S Philippe; S Protopapa; E Quirico; D C Reuter; B Schmitt; K N Singer; A J Verbiscer; R A Beyer; M W Buie; A F Cheng; D E Jennings; I R Linscott; J Wm Parker; P M Schenk; J R Spencer; J A Stansberry; S A Stern; H B Throop; C C C Tsang; H A Weaver; G E Weigle; L A Young
Journal: Science Date: 2016-03-18 Impact factor: 47.728

8. The geology of Pluto and Charon through the eyes of New Horizons.

Authors: Jeffrey M Moore; William B McKinnon; John R Spencer; Alan D Howard; Paul M Schenk; Ross A Beyer; Francis Nimmo; Kelsi N Singer; Orkan M Umurhan; Oliver L White; S Alan Stern; Kimberly Ennico; Cathy B Olkin; Harold A Weaver; Leslie A Young; Richard P Binzel; Marc W Buie; Bonnie J Buratti; Andrew F Cheng; Dale P Cruikshank; Will M Grundy; Ivan R Linscott; Harold J Reitsema; Dennis C Reuter; Mark R Showalter; Veronica J Bray; Carrie L Chavez; Carly J A Howett; Tod R Lauer; Carey M Lisse; Alex Harrison Parker; S B Porter; Stuart J Robbins; Kirby Runyon; Ted Stryk; Henry B Throop; Constantine C C Tsang; Anne J Verbiscer; Amanda M Zangari; Andrew L Chaikin; Don E Wilhelms
Journal: Science Date: 2016-03-18 Impact factor: 47.728

9. Observed glacier and volatile distribution on Pluto from atmosphere-topography processes.

Authors: Tanguy Bertrand; François Forget
Journal: Nature Date: 2016-09-19 Impact factor: 49.962

10. The atmosphere of Pluto as observed by New Horizons.

Authors: G Randall Gladstone; S Alan Stern; Kimberly Ennico; Catherine B Olkin; Harold A Weaver; Leslie A Young; Michael E Summers; Darrell F Strobel; David P Hinson; Joshua A Kammer; Alex H Parker; Andrew J Steffl; Ivan R Linscott; Joel Wm Parker; Andrew F Cheng; David C Slater; Maarten H Versteeg; Thomas K Greathouse; Kurt D Retherford; Henry Throop; Nathaniel J Cunningham; William W Woods; Kelsi N Singer; Constantine C C Tsang; Rebecca Schindhelm; Carey M Lisse; Michael L Wong; Yuk L Yung; Xun Zhu; Werner Curdt; Panayotis Lavvas; Eliot F Young; G Leonard Tyler
Journal: Science Date: 2016-03-18 Impact factor: 47.728

4 in total