The Fate of Chromium in Weathered Ultramafic Rocks and Their Derivitative Soils in Cuba: Clues from Spectroscopic Studies

• Published in: Acta geologica Sinica (Beijing) Vol. 91; no. S1; p. 12
• Main Author: FOSTER, Andrea L.
• Format: Journal Article
• Language: English
• Published: Richmond Wiley Subscription Services, Inc 01.05.2017
• Edition: English ed.
• Subjects: Absorption; Absorption spectroscopy; Abundance; Access; Amorphous materials; Analytical methods; Carcinogens; Cations; Chromite; Chromium; Climate; Climatology; Control stability; Correlation; Crystal structure; Digestion; Electron transfer; Environments; Estimation; Geochemistry; Goethite; Iron; Lasers; Luminescence; Manganese; Mine wastes; Minerals; Mobility; Oxidation; Oxides; Oxidoreductions; Photons; Products; Raman spectroscopy; Relative abundance; Resonance; Reviews; Risk factors; Rock; Rocks; Scattering; Serpentine; Serpentine soils; Soil; Soils; Solid phases; Spectroscopic analysis; Spectroscopy; Spectrum analysis; Studies; Wastes; Weather; Weathering; X-ray absorption spectroscopy
• ISSN: 1000-9515; 1755-6724
• DOI: 10.1111/1755-6724.13153

In its cationic,trivalent form,Chromium(Cr)it is a micronutrient,and exhibits low environmental mobility.In hexavalent form,however,it is a human carcinogen and also highly mobile.Climate is a key environmental factor controlling weathering rates and stability of primary and secondary Cr-bearing minerals.Knowledge of Cr oxidation state and mineral residence is therefore essential to estimating the risk posed by Cr in serpentinites,chromite mine wastes,and soils developed on these parent materials.X-ray absorption spectroscopy(XAS)is currently the best available technique for determination of the relative abundance of Cr(III)and Cr(VI)in situ(that is,without digestion of solid phases).A brief review of relevant XAS studies of is presented below,focusing on studies in tropical climates1,as they will be most relevant to eastern Cuba’s extensively serpentinized ophiolite belt.Cr(III)-bearing spinels are usually the dominant and most refractory Cr host in ultramafic rocks.Previous XAS studies2 indicate that in tropical climates,Cr-spinels weather rapidly to form Cr(III)-bearing secondary Fe(III)(hydr)oxides(goethite,hematite).Manganese(Mn)is also enriched in ultramafic rocks2;as Mn(IV),it can also co-precipitate with Fe(III)(hydr)oxides,or form its own secondary(hydr)oxides.A previous study found up to 20%Cr(VI)in in a tropical,serpentine soil that contained substantial Mn,and a strong correlation between the*amounts of Cr(VI)and Mn(IV)in the soil profile2.Theresults of several XAS studies suggest that a close association of Mn(IV)and Cr(III)in secondary Fe(hydr)oxides is necessary for oxidation of Cr(III)to Cr(VI)via electron transfer reactions with Mn(IV);however,additional XAS studies have shown that organic matter3and Cr-bearing aluminosilicates4 may also be important sources of Cr(III)to the environment under specific conditions.The stability and fate of Cr has not been studied in detail for these two host phase types,to the best of our knowledge.Access to XAS facilities to perform Cr geochemical experiments is limited and will only become more so in the future.We are working to develop and apply(micro)Raman spectroscopy to evaluate Cr oxidation state and mineral residence(in crystalline and amorphous materials).In addition to standard Raman scattering,we are employing resonance Raman(785 nm laser)to enhance signal from Cr(VI)-bearing phases and laser-stimulated photoluminescence to identify Cr(III)associated with Al-rich alteration products