The detection of chlorinated hydrocarbons by Curiosity on Mars has been attributed to the presence of unidentified indigenous organic matter. Similarly, oxychlorines on Earth have been proposed to be responsible for the apparent lack of organics in the Atacama Desert. The presence of perchlorate (ClO4−) poses a unique challenge to the measurement of organic matter due to the oxidizing power of oxychlorines during commonly used pyrolysis–gas chromatography–mass spectrometry (py-GC-MS) methods. Here, we show that perchlorates and other oxyanion salts inhibit the detection of organic compounds but that removing these problematic species prior to pyrolysis by using an optimal sample extraction duration and suitable ratios of water to sample mass enables analysis. We have characterized leached and unleached samples containing perchlorates from the Atacama Desert and have found that after leaching, the py-GC-MS chromatograms of the dried mineral residues show identifiable biomarkers associated with indigenous cyanobacteria. Samples which were pyrolyzed without leaching showed no detectable organic matter other than background siloxane and very weak or no trace of detectable polychlorinated benzenes. Dried sample residues remaining after leaching, the mineral matrix and water-insoluble organic matter, showed a strong organic response in all cases when analyzed by py-GC-MS. These residues are most likely the product of the pyrolysis of water-insoluble organics originally present in the samples. In addition, our results imply that previous soil analyses which contained high levels of oxyanions and concluded that organics were either not present or were present at extremely low levels should be reexamined.
Get full access to this article
View all access options for this article.
References
1.
BiemannK., OroJ., ToulminP., III, OrgelL.E., NierA.O., AndersonD.M., SimmondsP.G., FloryD., DiazA.V., RushneckD.R., BillerJ.E., and LafleurA.L. (1977) The search for organic substances and inorganic volatile compounds in the surface of Mars. J Geophys Res, 82:4641–4658.
2.
BillerP., RossA.B., and SkillS.C. (2015) Investigation of the presence of an aliphatic biopolymer in cyanobacteria: implications for kerogen formation. Org Geochem, 81:64–69.
3.
BoyntonW.V., MingD.W., KounavesS.P., YoungS.M., ArvidsonR.E., HechtM.H., HoffmanJ., NilesP.B., HamaraD.K., QuinnR.C., SmithP.H., SutterB., CatlingD.C., and MorrisR.V. (2009) Evidence for calcium carbonate at the Mars Phoenix landing site. Science, 325:61–64.
4.
CarrierB.L. and KounavesS.P. (2015) The origins of perchlorate in the martian soil. Geophys Res Lett, 42:3739–3745.
5.
ChevrierV.F. and Rivera-ValentinE.G. (2012) Formation of recurring slope lineae by liquid brines on present-day Mars. Geophys Res Lett, 39:L21202.
6.
ClarkB.C. and KounavesS.P. (2016) Evidence for the distribution of perchlorates on Mars. Int J Astrobiol, 15:311–318.
7.
DavilaA.F. and Schulze-MakuchD. (2016) The last possible outposts for life on Mars. Astrobiology, 16:159–168.
8.
DundasC.M. and McEwenA.S. (2015) Slope activity in Gale Crater, Mars. Icarus, 254:213–218.
9.
EigenbrodeJ.L., SummonsR.E., SteeleA., FreissinetC., MillanM., Navarro-GonzálezR., SutterB., McAdamA.C., FranzH.B., GlavinD.P., ArcherP.D., MahaffyP.R., ConradP.G., HurowitzJ.A., GrotzingerJ.P., GuptaS., MingD.W., SumnerD.Y., SzopaC., MalespinC., BuchA., and CollP. (2018) Organic matter preserved in 3-billion-year-old mudstones at Gale Crater, Mars. Science, 360:1096–1101.
10.
EwingS.A., YangW., DePaoloD.J., MichalskiG., KendallC., StewartB.W., ThiemensM., and AmundsonR. (2008) Non-biological fractionation of stable Ca isotopes in soils of the Atacama Desert, Chile. Geochim Cosmochim Acta, 72:1096–1110.
11.
FairenA.G., DavilaA.F., LimD., BramallN., BonaccorsiR., ZavaletaJ., UcedaE.R., StokerC., WierzchosJ., DohmJ.M., AmilsR., AndersenD., and McKayC.P. (2010) Astrobiology through the ages of Mars: the study of terrestrial analogues to understand the habitability of Mars. Astrobiology, 10:821–843.
12.
FletcherL.E., ConleyC.A., Valdivia-SilvaJ.E., Perez-MontañoS., Condori-ApazaR., KovacsG.T.A., GlavinD.P., and McKayC.P. (2011) Determination of low bacterial concentrations in hyperarid Atacama soils: comparison of biochemical and microscopy methods with real-time quantitative PCR. Can J Microbiol, 57:953–963.
13.
FlynnG. (1996) The delivery of organic matter from asteroids and comets to the early surface of Mars. Earth Moon Planets, 72:469–474.
14.
FrançoisP., SzopaC., BuchA., CollP., McAdamA.C., MahaffyP.R., FreissinetC., GlavinD.P., Navarro-GonzalezR., and CabaneM. (2016) Magnesium sulfate as a key mineral for the detection of organic molecules on Mars using pyrolysis. J Geophys Res: Planets, 121:61–74.
15.
FreissinetC., GlavinD.P., MahaffyP.R., MillerK.E., EigenbrodeJ.L., SummonsR.E., BrunnerA.E., BuchA., SzopaC., ArcherP.D.Jr., FranzH.B., AtreyaS.K., BrinckerhoffW.B., CabaneM., CollP., ConradP.G., Des MaraisD.J., DworkinJ.P., FairénA.G., FrançoisP., GrotzingerJ.P., KashyapS., ten KateI.L., LeshinL.A., MalespinC.A., MartinM.G., Martin-TorresF.J., McAdamA.C., MingD.W., Navarro-GonzálezR., PavlovA.A., PratsB.D., SquyresS.W., SteeleA., SternJ.C., SumnerD.Y., SutterB., ZorzanoM.P., and the MSL ScienceTeam. (2015) Organic molecules in the Sheepbed Mudstone, Gale Crater, Mars. J Geophys Res: Planets, 120:495–514.
16.
GaillardF., MichalskiJ., BergerG., McLennanS.M., and ScailletB. (2013) Geochemical reservoirs and timing of sulfur cycling on Mars. Space Sci Rev, 174:251–300.
17.
GlavinD.P., FreissinetC., MillerK.E., EigenbrodeJ.L., BrunnerA.E., BuchA., SutterB., ArcherP.D.Jr., AtreyaS.K., BrinckerhoffW.B., CabaneM., CollP., ConradP.G., CosciaD., DworkinJ.P., FranzH.B., GrotzingerJ.P., LeshinL.A., MartinM.G., McKayC., MingD.W., Navarro-GonzálezR., PavlovA., SteeleA., SummonsR.E., SzopaC., TeinturierS., and MahaffyP.R. (2013) Evidence for perchlorates and the origin of chlorinated hydrocarbons detected by SAM at the Rocknest aeolian deposit in Gale Crater. J Geophys Res: Planets, 118:1955–1973.
18.
HechtM.H., KounavesS.P., QuinnR.C., WestS.J., YoungS.M., MingD.W., CatlingD.C., ClarkB.C., BoyntonW.V., HoffmanJ., DeFloresL.P., GospodinovaK., KapitJ., and SmithP.H. (2009) Detection of perchlorate and the soluble chemistry of martian soil at the Phoenix lander site. Science, 325:64–67.
19.
JacksonW.A., DavilaA.F., SearsD.W.G., CoatesJ.D., McKayC.P., BrundrettM., EstradaN., and BöhlkeJ.K. (2015) Widespread occurrence of (per)chlorate in the Solar System. Earth Planet Sci Lett, 430:470–476.
20.
KenigF., ChouL., McKayC.P., JacksonW.A., DoranP.T., MurrayA.E., and FritsenC.H. (2016) Perchlorate and volatiles of the brine of Lake Vida (Antarctica): implication for the in situ analysis of Mars sediments. J Geophys Res Planets, 121:1190–1203.
21.
KillopsS. and KillopsV. (2005) Introduction to Organic Geochemistry,, 2nd ed., Blackwell Publishing Ltd., Hoboken, NJ.
22.
KminekG. and RummelJ.D. (2015) COSPAR's Planetary Protection Policy. Space Research Today, 193:7–19.
23.
KounavesS.P., HechtM.H., WestS.J., MorookianJ.-M., YoungS.M.M., QuinnR., GrunthanerP., WenX., WeilertM., CableC.A., FisherA., GospodinovaK., KapitJ., StrobleS., HsuP.-C., ClarkB.C., MingD.W., and SmithP.H. (2009) The MECA Wet Chemistry Laboratory on the 2007 Phoenix Mars Scout Lander. J Geophys Res, 114, doi:10.1029/2008je003084.
24.
KounavesS.P., HechtM.H., KapitJ., GospodinovaK., DeFloresL., QuinnR.C., BoyntonW.V., ClarkB.C., CatlingD.C., HredzakP., MingD.W., MooreQ., ShustermanH., StrobieS., WestS.J., And YoungS.M.M. (2010a) Wet Chemistry experiments on the 2007 Phoenix Mars Scout Lander mission: data analysis and results. J Geophys Res, 115, doi:10.1029/2009je003424.
25.
KounavesS.P., HechtM.H., KapitJ., QuinnR.C., CatlingD.C., ClarkB.C., MingD.W., GospodinovaK., HredzakP., McElhoneyK., and ShustermanJ. (2010b) Soluble sulfate in the martian soil at the Phoenix landing site. Geophys Res Lett, 37:L0920.
26.
KounavesS.P., CarrierB.L., O'NeilG.D., StrobleS.T., and ClaireM.W. (2014a) Evidence of martian perchlorate, chlorate, and nitrate in Mars meteorite EETA79001: implications for oxidants and organics. Icarus, 229:206–213.
27.
KounavesS.P., ChaniotakisN.A., ChevrierV.F., CarrierB.L., FoldsK.E., HansenV.M., McElhoneyK.M., O'NeilG.D., and WeberA.W. (2014b) Identification of the perchlorate parent salts at the Phoenix Mars landing site and possible implications. Icarus, 232:226–231.
28.
LeshinL.A., MahaffyP.R., WebsterC.R., CabaneM., CollP., ConradP.G., ArcherP.D.Jr., AtreyaS.K., BrunnerA.E., BuchA., EigenbrodeJ.L., FleschG.J., FranzH.B., FreissinetC., GlavinD.P., McAdamA.C., MillerK.E., MingD.W., MorrisR.V., Navarro-GonzálezR., NilesP.B., OwenT., PepinR.O., SquyresS., SteeleA., SternJ.C., SummonsR.E., SumnerD.Y., SutterB., SzopaC., TeinturierS., TrainerM.G., WrayJ.J., GrotzingerJ.P., and the MSL ScienceTeam. (2013) Volatile, isotope, and organic analysis of martian fines with the Mars Curiosity Rover. Science, 341, doi:10.1126/science.1238937.
29.
LewisJ.M.T., WatsonJ.S., NajorkaJ., LuongD., and SephtonM.A. (2015) Sulfate minerals: a problem for the detection of organic compounds on Mars?. Astrobiology, 15:247–258.
30.
LewisJ.M.T., NajorkaJ., WatsonJ.S., and SephtonM.A. (2018) The search for Hesperian organic matter on Mars: pyrolysis studies of sediments rich in sulfur and iron. Astrobiology, 18:454–464.
31.
LiX., DanellR.M., BrinckerhoffW.B., PinnickV.T., van AmeromF., ArevaloR.D.Jr., GettyS.A., MahaffyP.R., SteiningerH., and GoesmannF. (2015) Detection of trace organics in Mars analog samples containing perchlorate by laser desorption/ionization mass spectrometry. Astrobiology, 15:104–110.
32.
McAdamA.C., FranzH.B., SutterB., ArcherP.D., FreissinetC., EigenbrodeJ.L., MingD.W., AtreyaS.K., BishD.L., BlakeD.F., BowerH.E., BrunnerA., BuchA., GlavinD.P., GrotzingerJ.P., MahaffyP.R., McLennanS.M., MorrisR.V., Navarro-GonzálezR., RampeE.B., SquyresS.W., SteeleA., SternJ.C., SumnerD.Y., and WrayJ.J. (2014) Sulfur-bearing phases detected by evolved gas analysis of the Rocknest aeolian deposit, Gale Crater, Mars. J Geophys Res, 119:373–393.
33.
McCaigH.C., StocktonA., CrillyC., ChungS., KanikI., LinY., and ZhongF. (2016) Supercritical carbon dioxide extraction of coronene in the presence of perchlorate for in situ chemical analysis of martian regolith. Astrobiology, 16:703–714.
34.
McEwenA.S., OjhaL., DundasC.M., MattsonS.S., ByrneS., WrayJ.J., CullS.C., MurchieS.L., ThomasN., and GulickV.C. (2011) Seasonal flows on warm martian slopes. Science, 333:740–743.
35.
MingD.W., ArcherP.D.Jr., GlavinD.P., EigenbrodeJ.L., FranzH.B., SutterB., BrunnerA.E., SternJ.C., FreissinetC., McAdamA.C., MahaffyP.R., CabaneM., CollP., CampbellJ.L., AtreyaS.K., NilesP.B., BellJ.F., III, BishD.L., BrinckerhoffW.B., BuchA., ConradP.G., Des MaraisD.J., EhlmannB.L., FairénA.G., FarleyK., FleschG.J., FrançoisP., GellertR., GrantJ.A., GrotzingerJ.P., GuptaS., HerkenhoffK.E., HurowitzJ.A., LeshinL.A., LewisK.W., McLennanS.M., MillerK.E., MoerschJ., MorrisR.V., Navarro-GonzálezR., PavlovA.A., PerrettG.M., PradlerI., SquyresS.W., SummonsR.E., SteeleA., StolperE.M., SumnerD.Y., SzopaC., TeinturierS., TrainerM.G., TreimanA.H., VanimanD.T., VasavadaA.R., WebsterC.R., WrayJ.J., YingstR.A., and the MSL ScienceTeam. (2014) Volatile and organic compositions of sedimentary rocks in Yellowknife Bay, Gale Crater, Mars. Science, 343, doi:10.1126/science.1245267.
36.
MuJ. and PerlmutterD.D. (1981) Thermal decomposition of inorganic sulfates and their hydrates. Industrial & Engineering Chemistry Process Design and Development, 20:640–646.
37.
Navarro-GonzálezR., VargasE., de la RosaJ., RagaA.C., and McKayC.P. (2010) Reanalysis of the Viking results suggests perchlorate and organics at midlatitudes on Mars. J Geophys Res, 115, doi:10.1029/2010je003599.
38.
Perez-FodichA., ReichM., AlvarezF., SnyderG.T., SchoenbergR., VargasG., MuramatsuY., and FehnU. (2014) Climate change and tectonic uplift triggered the formation of the Atacama Desert's giant nitrate deposits. Geology, 42:251–254.
39.
RoyleS.H., OberlinE., WatsonJ.S., MontgomeryW., KounavesS.P., and SephtonM.A. (2018) Perchlorate-driven combustion of organic matter during pyrolysis-gas chromatography-mass spectrometry: implications for organic matter detection on Earth and Mars. J Geophys Res, 123:1901–1909.
40.
RummelJ.D., BeatyD.W., JonesM.A., BakermansC., BarlowN.G., BostonP.J., ChevrierV.F., ClarkB.C., de VeraJ.P., GoughR.V., HallsworthJ.E., HeadJ.W., HipkinV.J., KieftT.L., McEwenA.S., MellonM.T., MikuckiJ.A., NicholsonW.L., OmelonC.R., PetersonR., RodenE.E., Sherwood LollarB., TanakaK.L., ViolaD., and WrayJ.J. (2014) A new analysis of Mars “Special Regions”: findings of the Second MEPAG Special Regions Science Analysis Group (SR-SAG2). Astrobiology, 14:887–968.
SephtonM.A., LewisJ.M.T., WatsonJ.S., MontgomeryW., and GarnierC. (2014) Perchlorate-induced combustion of organic matter with variable molecular weights: implications for Mars missions. Geophys Res Lett, 41:7453–7460.
43.
SternJ.C., SutterB., FreissinetC., Navarro-GonzálezR., McKayC.P., ArcherP.D.Jr., BuchA., BrunnerA.E., CollP., EigenbrodeJ.L., FairenA.G., FranzH.B., GlavinD.P., KashyapS., McAdamA.C., MingD.W., SteeleA., SzopaC., WrayJ.J., Martín-TorresF.J., ZorzanoM.-P., ConradP.G., and MahaffyP.R. (2015) Evidence for indigenous nitrogen in sedimentary and aeolian deposits from the Curiosity rover investigations at Gale Crater, Mars. Proc Natl Acad Sci USA, 112:4245–4250.
44.
SternJ.C., SutterB., JacksonW.A., Navarro-GonzálezR., McKayC.P., MingD.W., ArcherP.D., and MahaffyP.R. (2017) The nitrate/(per)chlorate relationship on Mars. Geophys Res Lett, 44:2643–2651.
45.
SutterB., McAdamA.C., MahaffyP.R., MingD.W., EdgettK.S., RampeE.B., EigenbrodeJ.L., FranzH.B., FreissinetC., GrotzingerJ.P., SteeleA., HouseC.H., ArcherP.D., MalespinC.A., Navarro-GonzálezR., SternJ.C., BellJ.F., CalefF.J., GellertR., GlavinD.P., ThompsonL.M., and YenA.S. (2017) Evolved gas analyses of sedimentary rocks and eolian sediment in Gale Crater, Mars: results of the Curiosity rover's Sample Analysis at Mars instrument from Yellowknife Bay to the Namib Dune. J Geophys Res, 122:2574–2609.
46.
TissotB. and WelteD.H. (1984) Petroleum Formation and Occurrence,, 2nd ed., Springer, Berlin.
47.
VitekP., EdwardsH.G., JehlickaJ., AscasoC., de los RiosA., ValeaS., Jorge-VillarS.E., DavilaA.F., and WierzchosJ. (2010) Microbial colonization of halite from the hyper-arid Atacama Desert studied by Raman spectroscopy. Philos Trans A Math Phys Eng Sci, 368:3205–3221.
48.
von KiparskiG.R., ParkerD.R., and TsapinA.I. (2013) Removing perchlorate from samples to facilitate organics detection by pyrolitic methods. Icarus, 225:636–642.
49.
Warren-RhodesK.A., RhodesK.L., PointingS.B., EwingS.A., LacapD.C., Gómez-SilvaB., AmundsonR., FriedmannE.I., and McKayC.P. (2006) Hypolithic cyanobacteria, dry limit of photosynthesis, and microbial ecology in the hyperarid Atacama Desert. Microb Ecol, 52:389–398.
50.
WierzchosJ., AscasoC., and McKayC.P. (2006) Endolithic cyanobacteria in halite rocks from the hyperarid core of the Atacama Desert. Astrobiology, 6:415–422.
51.
WierzchosJ., de los RíosA., and AscasoC. (2012) Microorganisms in desert rocks: the edge of life on Earth. Int Microbiol, 15:173–183.
52.
YenA.S., MingD.W., VanimanD.T., GellertR., BlakeD.F., MorrisR.V., MorrisonS.M., BristowT.F., ChiperaS.J., EdgettK.S., TreimanA.H., ClarkB.C., DownsR.T., FarmerJ.D., GrotzingerJ.P., RampeE.B., SchmidtM.E., SutterB., ThompsonL.M.; MSL ScienceTeam. (2017) Multiple stages of aqueous alteration along fractures in mudstone and sandstone strata in Gale Crater, Mars. Earth Planet Sci Lett, 471:186–198.
53.
ZentA. and McKayC. (1994) The chemical reactivity of the martian soil and implications for future missions. Icarus, 108:146–157.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
