Beyond the Hematite: More Reasons To Visit Meridiani Wendy Calvin, Alicia Fallacaro (UNR) Alice Baldridge (ASU) Supported by NASA EPSCOR, PGG, MER-PS.

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Presentation transcript:

Beyond the Hematite: More Reasons To Visit Meridiani Wendy Calvin, Alicia Fallacaro (UNR) Alice Baldridge (ASU) Supported by NASA EPSCOR, PGG, MER-PS

Overview Mariner 6/7 IRS, Locations, footprint Hydration of hematite sites (Meridiani and Aram!) Methods Amount of Water Synthesis 0.4 to 50  m Alteration Analogs Astrobiology Potential Hypothesis Testing

Mariner 6/7 IRS: 1969 Flybys Mariner 6: 2-6  m, 2 segments Mariner 7: 2-6  m; 5-15  m, 4segments Footprint 100km x 200km Both crossed the Meridiani Site. M6 crossed the Aram site. Neither covered W Candor site.

Where was/is the water? Early M6 analysis shows some low albedo regions more hydrated. Noted correlation with classic low albedo regions and drainage density Proposed a model of dark alteration consistent with ISM/IRS spectra.

Determining Hydration State Normalized, Integrated Band Depth Convert data to radiance Calculated I/F where F=solar+planck fit, divided by cos(i) cos(e) Merge wavelength segments Integrate 3  m band depth and divide out albedo at both 2.2  m and 4  m.

Hydration Clusters Compare NIBD with albedo, incidence, emission angles High hydration, low albedo Mid hydration, moderate albedo Low hydration, low albedo Remnant high incidence, emission angle effects

Hydration of Aram Chaos Strong correlation of hydration and hematite.

Hydration of Meridiani Precise correlation between increased hydration and mapped hematite boundaries.

Mariner 7 over Meridiani 3  m also show increased band depth. Thermal wavelengths consistent with more water in surface minerals. Need to look at TES at the short wavelengths. Better data with mini-TES

How much water is there? Little systematic work on 3-  m band strength and amount of water. Grain size and albedo can be important. Miyamoto and Zolensky (1994) showed linear correlation between integrated band depth and bulk H in C-chondrites. Yen et al. (1998) showed apparent absorbance method works well for constant albedo, grain size. Based on apparent absorbance Mariner data suggest 2% additional water by weight at hematite sites. As the average is inferred to be only 1-2% this is a significant local increase in water bound in minerals. GRS also supports broad regional hydration at Meridiani. The hematite sites may be small surface expression of a more extensive global layer at depth.

Spectral Properties 0.4 to 50  m TES shows bulk hematite, but no strong variation in Si signature from 8-12  m. Mariner shows increased hydration at 3-  m and from 5 to 7  m. Subtle variation in 1-  m “pyroxene” band. Hematite is not hydrated So what is? Oxy-hydroxides, Sulfates, Carbonates, Ferrous Silicates.

Where’s the Water? Dark Alteration Analogs

Banded Iron Formation Shallow marine vs Deep Sea Dominant in rock record before ramp up in atmospheric O 2 Gradations among facies endmembers

BIF- Oxide & Carbonate

Ferrous Silicates Common in C-chondrite matrix BIF silicate facies Model shows nice fit to ISM/IRS data, especially 1-  m band. No strong features 8-12  m Need measurements at long wavelengths.

Other options Sulfates Acid Gels Carbonates Ferrous Silicate

Astrobiology Implications Role of biological precipitation in BIF Presence of organic signatures in C- chondrites (amino acids) If hematite locations reflect this kind of alteration scenario, potential for associated organics could be high. Pre-Biotic Chemistry Life C-ChondritesBIF Mars Hematite? 3.4 Ga > 4.5 Ga

Hypothesis Testing Water WAS involved in the formation of the hematite regions. In all cases: What carries the water? Dark Alteration Model Sub-aqueous origin (BIF analog). Look for: Layers, other facies, C in carbonate or carbonaceous cherts, sedimentary structures Ground water interaction (C-chondrite analog). Look for: minerals intermixed on very small scale, C in carbonaceous detritus Look for sulfides (though not source of hydration)

Hypothesis Testing - 2 If H 2 O is in other oxy-hydroxides says something about history and duration of alteration event. Mossbauer, mini-TES and PanCam all needed to unambiguously resolve auxiliary minerals.

From Here to There Work in the Interim to assist with MER Characterize ferrous clays to 50  m, also w/ Mössbauer, Fe 3+ /Fe 2+ More naturally occurring hematites BIF Carbonate composition TES < 8  m