Journal of Deep Space Exploration >

2020 , Vol. 7 >Issue 6: 584 - 604

DOI: https://doi.org/10.15982/j.issn.2096-9287.2020.20200057

Topic:Exploring the Solar System Boundary

The Exploration of Neptune:A Noble Gas and Volatile Perspective

Expand
  • 1. State Key Laboratory of Lithospheric Evolution,Institute of Geology and Geophysics,Chinese Academy of Sciences,Beijing 100029 ,China;
    2. College of Earth and Planetary Sciences,University of Chinese Academy of Sciences,Beijing 100049 ,China;
    3. State Key Laboratory of Atmospheric Boundary Layer Physics and Atmospheric Chemistry,Institute of Atmospheric Physics,Chinese Academy of Sciences, Beijing 100029,China

Received date: 17 Aug 2020

Revised date: 30 Nov 2020

Fold

Abstract

Most of the probes visiting other bodies in our Solar system only focused,due to technical shortcomings,on the exploration of the closer planets and planetary bodies and/or their natural satellites,i.e. Mercury,Venus,the Moon,Mars,and Jupiter,the comet 67P/Churyumov-Gerasimenko,or the 25143 Itokawa near-Earth asteroid. At present time,no specific missions to one of the two ice giants of our Solar System,Uranus and Neptune,has been planned. Our knowledge of Uranus and Neptune is,therefore,so far restricted to the data which have been collected during the flyby of the Voyager 2 mission,in January 1986 and August 1989,respectively,and to observations with the Hubble Space Telescope and the Keck Telescope. Ice giants are,in our galaxy,thought to be much more abundant than gas giant planets such as Jupiter or Saturn,therefore a better knowledge of ice giants is essential for our understanding of exoplanet candidates. Among other scientific goals,the atmospheric composition of ice giants,with a particular emphasis on their noble gas and volatile distribution,is of great significance,and can constrain models about their formation and evolution. In this review,we report,in a first part,the volatile inventories and the measurements in the planetary bodies of our Solar System;in a second part,we will discuss the scientific background about the concentration,distribution,and evolution of noble gases and volatiles in Uranus and Neptune,and finally describe a possible scenario of a future interstellar probe visiting one of the two ice giants as well as the feasibility of such a space mission,in term of payloads selection and mission profile. We will as well briefly evoke the possibility of using an ion trap mass spectrometer,a potential payload for the ice giant atmospheric exploration,onboard a Chinese interstellar mission to the outer Solar system.

Key words: ice giants; Neptune; volatiles; noble gases; isotopic ratios; mass spectrometry; entry probe

Cite this article

Thomas SMITH, ?Huaiyu HE, Ranran LIU . The Exploration of Neptune:A Noble Gas and Volatile Perspective[J]. Journal of Deep Space Exploration, 2020 , 7(6) : 584 -604 . DOI: 10.15982/j.issn.2096-9287.2020.20200057

References

[1] MCADAMS J V,FARQUHAR R W,TAYLOR A H,et al. MESSENGER mission design and navigation[J]. Space Science Reviews,2007,131:219-246
[2] MILILLO A,FUJIMOTO M,MURAKAMIG,et al. Investigating Mercury’s environment with the two-spacecraft bepicolombo mission[J]. Space Science Reviews,2020,216(93):1-78
[3] ZASOVA L V,GORINOV D A,EISMONT N A,et al. Venera-D:a design of an automatic space station for venus exploration[J]. Solar System Research,2019,53(7):20-24
[4] LAI J L,XU Y,ZHANG X P,et al. Comparison of dielectric properties and structure of lunar regolith at Chang'e‐3 and Chang'e-4 landing sites revealed by ground‐penetrating radar[J]. Geophysical Research Letters,2019,46(22):12783-12793
[5] GOU S,DI K C,YUE Z Y,et al. Lunar deep materials observed by Chang'e-4 rover[J]. Earth and Planetary Science Letters,2019,528:1-9
[6] GOU S,YUE Z Y,DI K C,et al. Impact melt breccia and surrounding regolith measured by Chang'e-4 rover[J]. Earth and Planetary Science Letters,2020,544:1-9
[7] STEVENSON D J. Jupiter’s interior as revealed by Juno[J]. Annual Review of Earth and Planetary Sciences,2020,48(1):465-489
[8] ALTWEGG K,BALSIGER H,BAR-NUM A,et al. 67P/Churyumov-Gerasimenko,a Jupiter family comet with a high D/H ratio[J]. Science,2015,347(6220):1-4
[9] FUJIWARA A,KAWAGUCHI J,YEOMANS D K,et al. The Rubble-Pile Asteroid Itokawa as Observed by Hayabusa[J]. Science,2006,312(5778):1330-1334
[10] MANDT K E,MOUSIS O,MARTY B,et al. Constraints from comets on the formation and volatile acquisition of the planets and satellites[J]. Space Science Reviews,2015,197:297-342
[11] MOUSIS O,ATKINSON D H,CAVALIé T,et al. Scientific rationale for Uranus and Neptune in situ explorations[J]. Planetary and Space Science,2018,155:12-40
[12] JARMAK S,LEONARD E,AKINS A,et al. QUEST:a new frontiers Uranus orbiter mission concept study[J]. Acta Astronautica,2020,170:6-26
[13] ATREYA S K,HOFSTADTER M H,IN J H,et al. Deep atmosphere composition,structure,origin,and exploration,with particular focus on critical in situ science at the icy giants[J]. Space Science Reviews,2020,216:1-31
[14] HOFSTADTER M D,FLETCHER L N,SIMON A A,et al. Future missions to the giant planets that can advance atmospheric science objectives[J]. Space Science Reviews,2020,216:1-91
[15] MANDT K E,MOUSIS O,LUNINE J,et al. Tracing the origins of the ice giants through noble gas isotopic composition[J]. Space Science Reviews,2020,216:1-37
[16] MOUSIS O,AGUICHINE A,ATKINSON D H,et al. Key atmospheric signatures for identifying the source reservoirs of volatiles in Uranus and Neptune[J]. Space Science Reviews,2020,216:1-19
[17] SAYANAGI K M,DILLMAN R A,ATKINSON D H,et al. Small Next-Generation Atmospheric Probe(SNAP)concept to enable future multi-probe missions:a case study for Uranus[J]. Space Science Reviews,2020,216:1-47
[18] VORBURGER A,WURZ P,WAITE H. Chemical and isotopic composition measurements on atmospheric probes exploring Uranus and Neptune[J]. Space Science Reviews,2020,216:1-31
[19] BATALHA N M. Exploring exoplanet populations with NASA’s Kepler Mission[J]. Proceedings of the National Academy of Sciences of the United States of America,2014,111(35):12647-12654
[20] ELLIOTT J. Ice giants pre-decadal survey mission study report:JPL D-100520[R]. USA:JPL,2017.
[21] LEVISON H F,DONES L,CHAPMAN C R,et al. Could the lunar “late heavy bombardment” have been triggered by the formation of Uranus and Neptune?[J]. Icarus,2001,151(2):286-306
[22] BOSS A P. Formation of gas and ice giant planets[J]. Earth and Planetary Science Letters,2002,202(3-4):513-523
[23] VENTURINI J,RONCO M P,GUILERA O M. Setting the stage:planet formation and volatile delivery[J]. Space Science Reviews,2020,216:1-32
[24] THOMMES E W,DUNCAN M J,LEVISON H F. The formation of Uranus and Neptune among Jupiter and Saturn[J]. The Astronomical Journal,2002,123(5):2862-2883
[25] TSIGANIS K,GOMES R,MORBIDELLI A,et al. Origin of the orbital architecture of the giant planets of the Solar System[J]. Nature,2005,435(7041):459-461
[26] GOMES R,LEVISON H F,TSIGANIS K,et al. Origin of the cataclysmic late heavy bombardment period of the terrestrial planets[J]. Nature,2005,435(7041):466-469
[27] MORBIDELLI A,LEVISON H F,TSIGANIS K,et al. Chaotic capture of Jupiter’s Trojan asteroids in the early Solar system[J]. Nature,2005,435(7041):462-465
[28] DESCH S J. Mass distribution and planet formation in the solar nebula[J]. The Astrophysical Journal,2007,671(1):878-893
[29] HELLED R,BODENHEIMER P. The formation of Uranus and Neptune:challenges and implications for intermediate-mass exoplanets[J]. The Astronomical Journal,2014,789(1):1-11
[30] TARTèSE R,ANAND M,GATTACCECA J,et al. Constraining the evolutionary history of the Moon and the inner Solar System:a case for new returned lunar samples[J]. Space Science Reviews,2019,215:1-50
[31] MéSZáROS M,HOFMANN B A,LEYA I. A noble gas data collection of Lunar meteorites[J]. Meteoritics and Planetary Science,2018,53(5):1104-1107
[32] SHARP Z,SHEARER C,MCKEEGAN K,et al. The chlorine isotope composition of the moon and implications for an anhydrous mantle[J]. Science,2010,329(5995):1050-1053
[33] PANIELLO R C,DAY J M D,MOYNIER F. Zinc isotopic evidence for the origin of the Moon[J]. Nature,2012,490(7420):376-380
[34] BOGARD D D,FUNKHOUSER J G,SHAEFFER O A,et al. Noble gas abundances in lunar material-cosmic-ray spallation products and radiation ages from the sea of tranquility and the ocean of storm[J]. Journal of Geophysical Research,1971,76(11):2757-2779
[35] REEDY R C,ARNOLD J R. Interaction of solar and galactic cosmic-ray particles with the Moon[J]. Journal of Geophysical Research,1972,77(4):537-555
[36] HARTUNG J B. Lunar rock surfaces as detectors of solar processes. [C]//Conference on The Ancient Sun:Fossil Record in the Earth,Moon and Meteorites. Boulder,CO:New York and Oxford,Pergamon Press,1980.
[37] RAO N N,VENKATESAN T R. Solar-flare produced 3He in lunar samples[J]. Nature,1980,286(5826):788-790
[38] WIELER R. Noble gases in the Solar system[J]. Reviews in Mineralogy and Geochemistry,2002,47(1):21-70
[39] BARNES J J,KRING D A,TARTèSE R,et al. An asteroidal origin for water in the Moon[J]. Nature Communications,2016,7(1):1-10
[40] CURRAN N M,NOTTINGHAM M,ALEXANDER L,et al. A database of noble gases in lunar samples in preparation for mass spectrometry on the Moon[J]. Planetary and Space Sciences,2020,182:1-12
[41] ANAND M,CRAWFORD I A,BALAT-PICHELIN M,et al. A brief review of chemical and mineralogical resources on the Moon and likely initial in Situ Resource Utilization(ISRU)applications[J]. Planetary and Space Sciences,2012,74:42-48
[42] BARBER S J,WRIGHT I P,ABERNETHY F,et al. ProSPA:analysis of lunar polar volatiles and ISRU demonstration on the Moon[C]//49th Lunar and Planetary Science Conference. Woodlands,Texas:Lunar and Planetary Science Conference,2018.
[43] COLAPRETE A,ELPHIC R C,HELDMANN J,et al. An Overview of the Lunar Crater Observation and Sensing Satellite(LCROSS)[J]. Space Science Reviews,2012,167:3-22
[44] SANGHA J. Volatile ice deposits in lunar polar regions and their sources[D]. Toronto,Ontario:York University,2018.
[45] GREENWOOD J P,KARATO S-I,VANDER KAADEN K E,et al. Water,and volatile inventories of Mercury,Venus,the Moon,and Mars[J]. Space Science Reviews,2018,214:1-39
[46] FEGLEY J B. Venus-treatise on geochemistry[M]. Holland:ScienceDriect Publication,2014.
[47] OWEN T,BIEMANN K. Composition of the atmosphere at the surface of Mars:Detection of argon-36 and preliminary analysis[J]. Science,1976,193:801-803
[48] OWEN T,BIEMANN K,RUSHNECK D,et al. The composition of the atmosphere at the surface of Mars[J]. Journal of Geophysical Research,1977,82(B28):4635-4640
[49] MAHAFFY P R,WEBSTER C R,CABANE M,et al. The sample analysis at Mars investigation and instrument suite[J]. Space Science Reviews,2012,170(1-4):401-478
[50] MAHAFFY P R,WEBSTER C R,ATREYA S K,et al. Abundance and isotopic composition of gases in the Martian atmosphere from the Curiosity rover[J]. Science,2013,341(6134):263-266
[51] KOUNAVES S P,OBERLIN E A. Volatiles measured by the phoenix lander at the northern plains of Mars[J]. Volatiles in the Martian crust,2019,341(6134):265-283
[52] NIEMANN H B,HARPOLD D N,ATREYA S K,et al. Galileo Probe Mass Spectrometer experiment[J]. Space Science Reviews,1992,60:111-142
[53] NIEMANN H B,ATREYA S K,CARIGNAN G R,et al. The Galileo Probe Mass Spectrometer:composition of Jupiter’s atmosphere[J]. Science,1996,272(5263):846-849
[54] NIEMANN H B,ATREYA S K,CARIGNAN G R,et al. The composition of the Jovian atmosphere as determined by the Galileo probe mass spectrometer[J]. Journal of Geophysica Research,Planets,1998,103(E10):22831-22845
[55] VON ZAHN U,HUNTEN D M,LEHMACHER G. Helium in Jupiter’s atmosphere:Results from the Galileo probe helium interferometer experiment[J]. Journal of Geophysica Research,1998,103(E10):22815-22830
[56] NIEMANN H,ATREYA S,BAUER S J,et al. The Gas Chromatograph Mass Spectrometer Aboard Huygens. Huygens:Science,Payload and Mission[J]. ESA Special Publication,1997,1177:1-85
[57] MELTZE R M. The Cassini-Huygens visit to Saturn-An historic mission to the ringed planet[M]. Switzerland:Springer,2015.
[58] GUILLOT T,GAUTIER D. Giant planets. Treatise on Geophysics[M]. Holland:ScienceDriect Publication,2015.
[59] BISHOP J,ATREYA S K,ROMANI P N,et al. The middle and upper atmosphere of Neptune[M]. Tucson,Arizona:University of Arizona Press,1995.
[60] PODOLA K M,HUBBARD W B,STEVENSON D J. Models of Uranus interior and magnetic field[M]. Tucson,AZ:University of Arizona Press,1991.
[61] ATREYA S K,BAINES K H,EGELER P A. An ocean of water ammonia on Neptune and Uranus:clues from tropospheric cloud structure[C]//DPS meeting #38; Bulletin of the American Astronomical Society. USA:American Astronomical Society,2006.
[62] ATREYA S K,MAHAFFY P R,NIEMANN H B,et al. Composition and Origin of the Atmosphere of Jupiter - An Update and Implications for the Extrasolar Giant Planets[J]. Planetary and Space,Science,2003,51(2):105-112
[63] MAHAFFY P R,NIEMANN H B,ALPERT A,et al. Noble gas abundance and isotope ratios in the atmosphere of Jupiter from the Galileo probe mass spectrometer[J]. Journal of Geophysical Research,2000,105(E6):15061-15071
[64] BIENSTOCK B,ATKINSON D,BAINES K,et al. Neptune polar orbiter with probes[C]//NASA Proceedings of Planetary Probes Workshop. USA:NASA,2004.
[65] ATREYA S K,WONG A S. Clouds of Neptune and Uranus[C]//Proceedings,International Planetary Probe Workshop. [S.l.]:NASA Ames,2004.
[66] SROMOVSKY L A,FRY P M,KIM J H. Methane on Uranus:the case for a compact CH4 cloud layer at low latitudes and a severe CH4 depletion at high-latitudes based on re-analysis of Voyager occultation measurements and STIS spectroscopy[J]. Icarus,2011,215(1):292-312
[67] LODDERS K. Jupiter formed with more tar than ice[J]. The Astrophysical Journal,2004,611(1):587-597
[68] GAUTIER D,HERSANT F,MOUSIS O,et al. Enrichments of volatiles in Jupiter:a new interpretation of the Galileo measurements[J]. The Astrophysical Journal,2001,550(2):227-230
[69] GUILLOT T,HUESO R. The composition of Jupiter:sign of a(relatively)late formation in a chemically evolved protosolar disc[J]. Monthly Notices of the Royal Astronomical Society,2006,367(1):L47-L51
[70] WONG M H,MAHAFFY P R,ATREYA S K,et al. Updated Galileo probe mass spectrometer measurements of carbon,oxygen,nitrogen,and sulfur on Jupiter[J]. Icarus,2004,171(1):153-170
[71] FLETCHER L N,ORTON G S,TEANBY N A,et al. Phosphine on Jupiter and Saturn from Cassini/CIRS[J]. Icarus,2009,202(2):543-564
[72] CONRATH B J,GAUTIER D. Saturn helium abundance:A reanalysis of voyager measurements[J]. Icarus,2000,144(1):124-134
[73] De GRAAUW T,FEUCHTGRUBER H,BEZARD B,et al. First results of ISO-SWS observations of Saturn:detection of CO2,CH3C2H,C4HL2 and tropospheric H2O[J]. Astronomy and Astrophysics,1997,321:L13-L16
[74] FLETCHER L N,ORTON G S,TEANBY N A,et al. Methane and its isotopologues on Saturn from Cassini/CIRS observations[J]. Icarus,2009,199(2):351-367
[75] FLETCHER L N,ORTON G S,DE PATER I,et al. The aftermath of the July 2009 impact on Jupiter:ammonia,temperatures and particu-lates from Gemini thermal infrared spectroscopy[J]. Icarus,2011,211(1):568-586
[76] BRIGGS F H,SACKETT P D. Radio observations of Saturn as a probe of its atmosphere and cloud structure[J]. Icarus,1989,80(1):77-103
[77] CONRATH B J,HANEL R,GAUTIER D,et al. The helium abundance of Uranus from Voyager measurements[J]. Journal of Geophysical Research,1987,92(A13):15003-15010
[78] KARKOSCHKA E,TOMASKO M G. The haze and methane distributions on Uranus from HST-STIS spectroscopy[J]. Icarus,2009,202(1):287-309
[79] KARKOSCHKA E,TOMASKO M G. The haze and methane distributions on Neptune from HST-STIS spectroscopy[J]. Icarus,2011,211(1):780-797
[80] DE PATER I,ROMANI P N,ATREYA S K. Possible microwave absorption by H2S gas in Uranus’ and Neptune’s atmospheres[J]. Icarus,1991,91(2):220-233
[81] CONRATH B J,GAUTIER D,LINDAL G F,et al. The helium abundance of Neptune from Voyager measurements[J]. Journal of Geophysical Research,1991,96(S01):18907-18919
[82] LEWIS J S. The clouds of Jupiter and the NH3-H2O and NH3-H2S systems[J]. Icarus,1969,10(3):365-378
[83] WEIDENSCHILLING S J,LEWIS J S. Atmospheric and cloud structures of the jovian planets[J]. Icarus,1973,20(4):465-476
[84] SUDHIR A K,EGELER P A,WONG A. Water-ammonia ionic ocean on Uranus and Neptune-clue from tropospheric hydrogen sulfide clouds[C]//American Geophysical Union,Fall Meeting 2005. USA:AGU,2005.
[85] LINDAL G F,LYONS J R,SWEETNAM D N,et al. The atmosphere of Uranus:results of radio occultation measurements with Voyager 2[J]. Journal of Geophysical Research,1987,92(A13):14987-15001
[86] FEUCHTGRUBER H,LELLOUCH E,ORTON G,et al. The D/H ratio in the atmospheres of Uranus and Neptune from Herschel-PACS observations[J]. Astronomy and Astrophysics,2013,551:A126
[87] GUILLOT T. Interiors of giant planets inside and outside the solar system[J]. Science,1999,286(5437):72-77
[88] YANG L,CIESLA F J,ALEXANDER C M O D. The D/H ratio of water in the solar nebula during its formation and evolution[J]. Icarus,2013,226(1):256-267
[89] ALI-DIB M,LAKHLANI G. What is Neptune’s D/H ratio really telling us about its water abundance?[J]. Monthly Notices of the Royal Astronomical Society,2018,476(1):1169-1173
[90] ASPLUND,M,GREVESSE,N,SAUVAL,A. J,and SCOTT,P The chemical composition of the Sun[J]. Annunal Reviews of Astronomy and Astrophysics,2009(47):481-522
[91] ATREYA S K,CRIDA A,GUILLOT T,et al. The origin and evolution of Saturn,with exoplanet perspective,in Saturn in the 21st Century[M]. Cambridge,UK:Cambridge University Press,2019.
[92] MAHAFFY P R,DONAHUE T M,ATREYA S K,et al. Galileo probe measurements of D/H and 3He/4He in Jupiter’s atmosphere[J]. Space Science Reviews,1998,84:251-263
[93] LELLOUCH E,BéZARD B,FOUCHET T,et al. The deuterium abundance in Jupiter and Saturn from ISO-SWS observations[J]. Astronomy and Astrophysics,2001,370:610-622
[94] HANSEN C J,ALJABRI A S,BANFIELD D,et al. Neptune science with Argo - a voyage through the outer Solar system[EB/OL].(2020-12-8). https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.184.1068&rep=rep1&type=pdf.
[95] FULCHIGNONI M,ANGRILLI F,BIANCHINI G,et al. The Huygens Atmospheric Structure Instrument(HASI)[C]//Huygens:Science,Payload and Mission,Proceedings of an ESA conference. [S.l.]:ESA,1997.
[96] FERRI F,ANGRILLI F,BIANCHINI G,et al. Huygens Atmospheric Structure Instrument of Huygens probe on Cassini mission[J]. Acta Astronautica,2002,50:249-255
[97] BROCKWELL T G,MEECH K J,PICKENS K,et al. The mass spectrometer for planetary exploration(MASPEX)[C]//2016 IEEE Aerospace Conference. Big Sky,MT,USA:IEEE,2016.
[98] TOYODA M,OKUMURA D,ISHIHARA M,et al. Multi-turn time-of-flight mass spectrometers with electrostatic sectors[J]. Journal of Mass Spectrometry,2003,38(11):1125-1142
[99] OTT U,SWINDLE T D,SCHWENZER S P. Noble gases in Martian meteorites:budgets,sources,sinks,and processes[M]. Netherlands:Elsevier,2019.
[100] LUSPAY-KUTI A,H?SSIG M,FUSELIER S A,et al. Composition-dependent outgassing of comet 67P/Churyumov-Gerasimenko from ROSINA/DFMS-Implications for nucleus heterogeneity?[J]. Astronomy and Astrophysics,2015,583(A4):1-8
[101] LE ROY L,ALTWEGG K,BALSIGER H,et al. Inventory of the volatiles on comet 67P/Churyumov-Gerasimenko from Rosetta/ROSINA[J]. Astronomy and Astrophysics,2015,583(A1):1-12
[102] MALL U,ALTWEGG K,BALSIGER H,et al. High-Time Resolution In-situ Investigation of Major Cometary Volatiles around 67P/C-G at 3.1-2.3 AU Measured with ROSINA-RTOF[J]. The Astrophysical Journal,2016,819(2):1-9
[103] MARTY B,ALTWEGG K,BALSIGER H,et al. Xenon isotopes in Comet 67P/Churyumov-Gerasimenko show comets contributed to Earth's atmosphere[J]. Science,2017,356(6342):1069-1072
[104] SCHERER S,ALTWEGG K,BALSIGER H,et al. A novel principle for an ion mirror design in time-of-flight mass spectrometry[J]. International Journal of Mass Spectrometry,2006,251(1):73-81
[105] SIMCIC J,NIKOLIC D,BELOUSOV A,et al. Quadrupole Ion Trap Mass Spectrometer for ice giant atmospheres exploration[C]//EGU General Assembly 2020. [S.l.]:EGU,2020.
[106] MADZUNKOV S M,NIKOLI? D. Accurate Xe isotope measurement using JPL ion trap[J]. American Society for Mass Spectrometry,2014,25:1841-1852
[107] AREVALO J R,BRINCKERHOFF W B,MAHAFFY P R,et al. It’s a trap! A review of MOMA and others ion traps in space or under development[R]. USA:NASA,2012.
[108] DARRACH M,CHUTJIAN A,BORNSTEIN B,et al. on-orbit measurements of the ISS atmosphere by the vehicle cabin atmosphere monitor[C]//41st International Conference on Environmental Systems. Portland,Oregon:AIAA,2011.
[109] NIEMANN H B,BOOTH J R,HARTLE R E,et al. Pioneer Venus Orbiter Neutral Gas Mass Spectrometer Experiment[J]. IEEE transactions on geoscience and remote sensing,1980,18(1):60-65
[110] NIEMANN H B,HARPOLD D N,FENG S,et al. The Planet-B neutral gas mass spectrometer[J]. Earth,Planets and Space,1998,50:785-792
[111] WAITE JR J H,LEWIS W S,KASPRZAK W T,et al. The Cassini Ion and Neutral Mass Spectrometer(INMS)investigation[J]. Space Science Reviews,2004,114:113-231
[112] ELPHIC R C,DELORY G T,HINE B P,et al. The lunar atmosphere and dust environment explorer mission[J]. Space Science Reviews,2014,185:3-25
[113] MAHAFFY P R,BENNA M,KING T,et al. The neutral gas and ion mass spectrometer on the Mars atmosphere and volatile evolution mission[J]. Space Science Reviews,2015,195:49-73
[114] BHARDWAJ A,MOHANKUMAR S,DAS T P,et al. MENCA experiment aboard India’s Mars orbiter mission[J]. Current Science,2015,109(6):1106-1113
[115] FLETCHER L N,DE PATER I,ORTON G S,et al. Ice giant circulation patterns:implications for atmospheric probes[J]. Space Science Reviews,2020,216:1-38
[116] AGNOR C,BARR A,BIERHAUS B,et al. The exploration of Neptune and Triton[R]. USA:Planetary Science Decadal Survey,2009.
Options
Outlines

/