The formation of Charon's red poles from seasonally cold-trapped volatiles

W. M. Grundy; D. P. Cruikshank; G. R. Gladstone; C. J.A. Howett; T. R. Lauer; J. R. Spencer; M. E. Summers; M. W. Buie; A. M. Earle; K. Ennico; J. Wm Parker; S. B. Porter; K. N. Singer; S. A. Stern; A. J. Verbiscer; R. A. Beyer; R. P. Binzel; B. J. Buratti; J. C. Cook; C. M. Dalle Ore; C. B. Olkin; A. H. Parker; S. Protopapa; E. Quirico; K. D. Retherford; S. J. Robbins; B. Schmitt; J. A. Stansberry; O. M. Umurhan; H. A. Weaver; L. A. Young; A. M. Zangari; V. J. Bray; A. F. Cheng; W. B. McKinnon; R. L. McNutt; J. M. Moore; F. Nimmo; D. C. Reuter; P. M. Schenk; F. Bagenal; T. Andert; O. Barnouin; M. Bird; M. Brozović; H. A. Elliott; T. K. Greathouse; M. Hahn; D. P. Hamilton; M. E. Hill; D. P. Hinson; J. Hofgartner; M. Horányi; A. D. Howard; D. E. Jennings; J. A. Kammer; P. Kollmann; P. Lavvas; I. R. Linscott; C. M. Lisse; A. W. Lunsford; D. J. McComas; M. Mutchler; J. I. Nunez; M. Paetzold; S. Philippe; M. Piquette; H. J. Reitsema; J. H. Roberts; K. Runyon; E. Schindhelm; M. R. Showalter; A. J. Steffl; D. F. Strobel; T. Stryk; J. R. Szalay; H. B. Throop; C. C.C. Tsang; G. L. Tyler; M. H. Versteeg; G. E. Weigle; O. L. White; W. W. Woods; E. F. Young

doi:10.1038/nature19340

The formation of Charon's red poles from seasonally cold-trapped volatiles

W. M. Grundy, D. P. Cruikshank, G. R. Gladstone, C. J.A. Howett, T. R. Lauer, J. R. Spencer, M. E. Summers, M. W. Buie, A. M. Earle, K. Ennico, J. Wm Parker, S. B. Porter, K. N. Singer, S. A. Stern, A. J. Verbiscer, R. A. Beyer, R. P. Binzel, B. J. Buratti, J. C. Cook, C. M. Dalle OreC. B. Olkin, A. H. Parker, S. Protopapa, E. Quirico, K. D. Retherford, S. J. Robbins, B. Schmitt, J. A. Stansberry, O. M. Umurhan, H. A. Weaver, L. A. Young, A. M. Zangari, V. J. Bray, A. F. Cheng, W. B. McKinnon, R. L. McNutt, J. M. Moore, F. Nimmo, D. C. Reuter, P. M. Schenk, F. Bagenal, T. Andert, O. Barnouin, M. Bird, M. Brozović, H. A. Elliott, T. K. Greathouse, M. Hahn, D. P. Hamilton, M. E. Hill, D. P. Hinson, J. Hofgartner, M. Horányi, A. D. Howard, D. E. Jennings, J. A. Kammer, P. Kollmann, P. Lavvas, I. R. Linscott, C. M. Lisse, A. W. Lunsford, D. J. McComas, M. Mutchler, J. I. Nunez, M. Paetzold, S. Philippe, M. Piquette, H. J. Reitsema, J. H. Roberts, K. Runyon, E. Schindhelm, M. R. Showalter, A. J. Steffl, D. F. Strobel, T. Stryk, J. R. Szalay, H. B. Throop, C. C.C. Tsang, G. L. Tyler, M. H. Versteeg, G. E. Weigle, O. L. White, W. W. Woods, E. F. Young

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

54 Scopus citations

Abstract

A unique feature of Pluto's large satellite Charon is its dark red northern polar cap. Similar colours on Pluto's surface have been attributed to tholin-like organic macromolecules produced by energetic radiation processing of hydrocarbons. The polar location on Charon implicates the temperature extremes that result from Charon's high obliquity and long seasons in the production of this material. The escape of Pluto's atmosphere provides a potential feedstock for a complex chemistry. Gas from Pluto that is transiently cold-trapped and processed at Charon's winter pole was proposed as an explanation for the dark coloration on the basis of an image of Charon's northern hemisphere, but not modelled quantitatively. Here we report images of the southern hemisphere illuminated by Pluto-shine and also images taken during the approach phase that show the northern polar cap over a range of longitudes. We model the surface thermal environment on Charon and the supply and temporary cold-trapping of material escaping from Pluto, as well as the photolytic processing of this material into more complex and less volatile molecules while cold-trapped. The model results are consistent with the proposed mechanism for producing the observed colour pattern on Charon.

Original language	English (US)
Pages (from-to)	65-68
Number of pages	4
Journal	Nature
Volume	539
Issue number	7627
DOIs	https://doi.org/10.1038/nature19340
State	Published - 2016
Externally published	Yes

All Science Journal Classification (ASJC) codes

General

Access to Document

10.1038/nature19340

Cite this

Grundy, W. M., Cruikshank, D. P., Gladstone, G. R., Howett, C. J. A., Lauer, T. R., Spencer, J. R., Summers, M. E., Buie, M. W., Earle, A. M., Ennico, K., Parker, J. W., Porter, S. B., Singer, K. N., Stern, S. A., Verbiscer, A. J., Beyer, R. A., Binzel, R. P., Buratti, B. J., Cook, J. C., ... Young, E. F. (2016). The formation of Charon's red poles from seasonally cold-trapped volatiles. Nature, 539(7627), 65-68. https://doi.org/10.1038/nature19340

@article{f4c5f254c23e474399503f6b570f1357,

title = "The formation of Charon's red poles from seasonally cold-trapped volatiles",

abstract = "A unique feature of Pluto's large satellite Charon is its dark red northern polar cap. Similar colours on Pluto's surface have been attributed to tholin-like organic macromolecules produced by energetic radiation processing of hydrocarbons. The polar location on Charon implicates the temperature extremes that result from Charon's high obliquity and long seasons in the production of this material. The escape of Pluto's atmosphere provides a potential feedstock for a complex chemistry. Gas from Pluto that is transiently cold-trapped and processed at Charon's winter pole was proposed as an explanation for the dark coloration on the basis of an image of Charon's northern hemisphere, but not modelled quantitatively. Here we report images of the southern hemisphere illuminated by Pluto-shine and also images taken during the approach phase that show the northern polar cap over a range of longitudes. We model the surface thermal environment on Charon and the supply and temporary cold-trapping of material escaping from Pluto, as well as the photolytic processing of this material into more complex and less volatile molecules while cold-trapped. The model results are consistent with the proposed mechanism for producing the observed colour pattern on Charon.",

author = "Grundy, {W. M.} and Cruikshank, {D. P.} and Gladstone, {G. R.} and Howett, {C. J.A.} and Lauer, {T. R.} and Spencer, {J. R.} and Summers, {M. E.} and Buie, {M. W.} and Earle, {A. M.} and K. Ennico and Parker, {J. Wm} and Porter, {S. B.} and Singer, {K. N.} and Stern, {S. A.} and Verbiscer, {A. J.} and Beyer, {R. A.} and Binzel, {R. P.} and Buratti, {B. J.} and Cook, {J. C.} and {Dalle Ore}, {C. M.} and Olkin, {C. B.} and Parker, {A. H.} and S. Protopapa and E. Quirico and Retherford, {K. D.} and Robbins, {S. J.} and B. Schmitt and Stansberry, {J. A.} and Umurhan, {O. M.} and Weaver, {H. A.} and Young, {L. A.} and Zangari, {A. M.} and Bray, {V. J.} and Cheng, {A. F.} and McKinnon, {W. B.} and McNutt, {R. L.} and Moore, {J. M.} and F. Nimmo and Reuter, {D. C.} and Schenk, {P. M.} and F. Bagenal and T. Andert and O. Barnouin and M. Bird and M. Brozovi{\'c} and Elliott, {H. A.} and Greathouse, {T. K.} and M. Hahn and Hamilton, {D. P.} and Hill, {M. E.} and Hinson, {D. P.} and J. Hofgartner and M. Hor{\'a}nyi and Howard, {A. D.} and Jennings, {D. E.} and Kammer, {J. A.} and P. Kollmann and P. Lavvas and Linscott, {I. R.} and Lisse, {C. M.} and Lunsford, {A. W.} and McComas, {D. J.} and M. Mutchler and Nunez, {J. I.} and M. Paetzold and S. Philippe and M. Piquette and Reitsema, {H. J.} and Roberts, {J. H.} and K. Runyon and E. Schindhelm and Showalter, {M. R.} and Steffl, {A. J.} and Strobel, {D. F.} and T. Stryk and Szalay, {J. R.} and Throop, {H. B.} and Tsang, {C. C.C.} and Tyler, {G. L.} and Versteeg, {M. H.} and Weigle, {G. E.} and White, {O. L.} and Woods, {W. W.} and Young, {E. F.}",

year = "2016",

doi = "10.1038/nature19340",

language = "English (US)",

volume = "539",

pages = "65--68",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "7627",

}

Grundy, WM, Cruikshank, DP, Gladstone, GR, Howett, CJA, Lauer, TR, Spencer, JR, Summers, ME, Buie, MW, Earle, AM, Ennico, K, Parker, JW, Porter, SB, Singer, KN, Stern, SA, Verbiscer, AJ, Beyer, RA, Binzel, RP, Buratti, BJ, Cook, JC, Dalle Ore, CM, Olkin, CB, Parker, AH, Protopapa, S, Quirico, E, Retherford, KD, Robbins, SJ, Schmitt, B, Stansberry, JA, Umurhan, OM, Weaver, HA, Young, LA, Zangari, AM, Bray, VJ, Cheng, AF, McKinnon, WB, McNutt, RL, Moore, JM, Nimmo, F, Reuter, DC, Schenk, PM, Bagenal, F, Andert, T, Barnouin, O, Bird, M, Brozović, M, Elliott, HA, Greathouse, TK, Hahn, M, Hamilton, DP, Hill, ME, Hinson, DP, Hofgartner, J, Horányi, M, Howard, AD, Jennings, DE, Kammer, JA, Kollmann, P, Lavvas, P, Linscott, IR, Lisse, CM, Lunsford, AW, McComas, DJ, Mutchler, M, Nunez, JI, Paetzold, M, Philippe, S, Piquette, M, Reitsema, HJ, Roberts, JH, Runyon, K, Schindhelm, E, Showalter, MR, Steffl, AJ, Strobel, DF, Stryk, T, Szalay, JR, Throop, HB, Tsang, CCC, Tyler, GL, Versteeg, MH, Weigle, GE, White, OL, Woods, WW & Young, EF 2016, 'The formation of Charon's red poles from seasonally cold-trapped volatiles', Nature, vol. 539, no. 7627, pp. 65-68. https://doi.org/10.1038/nature19340

TY - JOUR

T1 - The formation of Charon's red poles from seasonally cold-trapped volatiles

AU - Grundy, W. M.

AU - Cruikshank, D. P.

AU - Gladstone, G. R.

AU - Howett, C. J.A.

AU - Lauer, T. R.

AU - Spencer, J. R.

AU - Summers, M. E.

AU - Buie, M. W.

AU - Earle, A. M.

AU - Ennico, K.

AU - Parker, J. Wm

AU - Porter, S. B.

AU - Singer, K. N.

AU - Stern, S. A.

AU - Verbiscer, A. J.

AU - Beyer, R. A.

AU - Binzel, R. P.

AU - Buratti, B. J.

AU - Cook, J. C.

AU - Dalle Ore, C. M.

AU - Olkin, C. B.

AU - Parker, A. H.

AU - Protopapa, S.

AU - Quirico, E.

AU - Retherford, K. D.

AU - Robbins, S. J.

AU - Schmitt, B.

AU - Stansberry, J. A.

AU - Umurhan, O. M.

AU - Weaver, H. A.

AU - Young, L. A.

AU - Zangari, A. M.

AU - Bray, V. J.

AU - Cheng, A. F.

AU - McKinnon, W. B.

AU - McNutt, R. L.

AU - Moore, J. M.

AU - Nimmo, F.

AU - Reuter, D. C.

AU - Schenk, P. M.

AU - Bagenal, F.

AU - Andert, T.

AU - Barnouin, O.

AU - Bird, M.

AU - Brozović, M.

AU - Elliott, H. A.

AU - Greathouse, T. K.

AU - Hahn, M.

AU - Hamilton, D. P.

AU - Hill, M. E.

AU - Hinson, D. P.

AU - Hofgartner, J.

AU - Horányi, M.

AU - Howard, A. D.

AU - Jennings, D. E.

AU - Kammer, J. A.

AU - Kollmann, P.

AU - Lavvas, P.

AU - Linscott, I. R.

AU - Lisse, C. M.

AU - Lunsford, A. W.

AU - McComas, D. J.

AU - Mutchler, M.

AU - Nunez, J. I.

AU - Paetzold, M.

AU - Philippe, S.

AU - Piquette, M.

AU - Reitsema, H. J.

AU - Roberts, J. H.

AU - Runyon, K.

AU - Schindhelm, E.

AU - Showalter, M. R.

AU - Steffl, A. J.

AU - Strobel, D. F.

AU - Stryk, T.

AU - Szalay, J. R.

AU - Throop, H. B.

AU - Tsang, C. C.C.

AU - Tyler, G. L.

AU - Versteeg, M. H.

AU - Weigle, G. E.

AU - White, O. L.

AU - Woods, W. W.

AU - Young, E. F.

PY - 2016

Y1 - 2016

N2 - A unique feature of Pluto's large satellite Charon is its dark red northern polar cap. Similar colours on Pluto's surface have been attributed to tholin-like organic macromolecules produced by energetic radiation processing of hydrocarbons. The polar location on Charon implicates the temperature extremes that result from Charon's high obliquity and long seasons in the production of this material. The escape of Pluto's atmosphere provides a potential feedstock for a complex chemistry. Gas from Pluto that is transiently cold-trapped and processed at Charon's winter pole was proposed as an explanation for the dark coloration on the basis of an image of Charon's northern hemisphere, but not modelled quantitatively. Here we report images of the southern hemisphere illuminated by Pluto-shine and also images taken during the approach phase that show the northern polar cap over a range of longitudes. We model the surface thermal environment on Charon and the supply and temporary cold-trapping of material escaping from Pluto, as well as the photolytic processing of this material into more complex and less volatile molecules while cold-trapped. The model results are consistent with the proposed mechanism for producing the observed colour pattern on Charon.

AB - A unique feature of Pluto's large satellite Charon is its dark red northern polar cap. Similar colours on Pluto's surface have been attributed to tholin-like organic macromolecules produced by energetic radiation processing of hydrocarbons. The polar location on Charon implicates the temperature extremes that result from Charon's high obliquity and long seasons in the production of this material. The escape of Pluto's atmosphere provides a potential feedstock for a complex chemistry. Gas from Pluto that is transiently cold-trapped and processed at Charon's winter pole was proposed as an explanation for the dark coloration on the basis of an image of Charon's northern hemisphere, but not modelled quantitatively. Here we report images of the southern hemisphere illuminated by Pluto-shine and also images taken during the approach phase that show the northern polar cap over a range of longitudes. We model the surface thermal environment on Charon and the supply and temporary cold-trapping of material escaping from Pluto, as well as the photolytic processing of this material into more complex and less volatile molecules while cold-trapped. The model results are consistent with the proposed mechanism for producing the observed colour pattern on Charon.

UR - http://www.scopus.com/inward/record.url?scp=84994558441&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84994558441&partnerID=8YFLogxK

U2 - 10.1038/nature19340

DO - 10.1038/nature19340

M3 - Article

C2 - 27626378

AN - SCOPUS:84994558441

SN - 0028-0836

VL - 539

SP - 65

EP - 68

JO - Nature

JF - Nature

IS - 7627

ER -

The formation of Charon's red poles from seasonally cold-trapped volatiles

Abstract

All Science Journal Classification (ASJC) codes

Access to Document

Other files and links

Fingerprint

Cite this