Bibliographies for GEOL 8200 - Carbonate Petrology - Part II
L.B. Railsback, Department of Geology, University of Georgia

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Recent and/or Important References on Calcrete and Pedogenic Carbonates
 L.B. Railsback, with thanks to J.E. Cox

Allen, J.R.L., 1986, Pedogenic calcretes in the Old Red Sandstone facies (Late Silurian- Early Carboniferous) of the Anglo-Welsh area, southern Britain, in Wright, V.P., ed., Paleosols: Their Recognition and Interpretation: Princeton, Princeton University Press, p. 58-86.

Alonso-Zarza, A.M., and Tanner, L.H., 2006, Paleoenvironmnetal Record and Applications of Calcretes and Palustine Carbonates: Geological Scoiety of America Special Paper 416, 248 p.

Blodgett, R.H., 1988, Calcareous paleosols in the Triassic Dolores Formation, southwestern Colorado, in Reinhardt, J.G., and Sigleo, W.R., eds., Paleosols and Weathering through Geologic Time: Principles and Applications: Geological Society of America Special Paper 216,p. 103-121.

Borchardt, G., and Lienkaemper, J.J., 1999m Pedogenic calcite as evidence ofor an early Holocene dry period in the San Francisco Bay area, California: Geological Society of America Bulletin, vol. 111, p. 906-918.

Capo, R.C., Whipkey, C.E., BlachŹre, J.R., and Chadwick, O.A., 2000, Pedogenic origin of dolomite in a basaltic weathering profile, Kohala peninsula, Hawaii: Geology, v. 28, p. 271-274.

Cerling, T.E., 1984, The stable isotopic composition of modern soil carbonate and its relationship to climate: Earth and Planetary Science Letters, v. 71, p. 229-240.

Chafetz, H.S., and Butler, J.C., 1980, Petrology of recent caliche pisolites, spherulites, and speleothem deposits from central Texas: Sedimentology, v. 27, p. 497-518.

Chiquet, A., Michard, A., Nahon, N., and Hamblin, B., 1999, Atmospheric input vs. in situ weathering in the genesis of calcretes: An Sr isotope study at G‡lvez (Central Spain): Geochimica et Cosmochimica Acta, v. 63, p. 311-323.

Cox, J.E, 1997, The Paleoenvironmental and Paleoclimatic Significance of Carbon and Oxygen Isotopes of Calcrete and Related Rocks of the Catskill Delta: University of Georgia M.S. Thesis, 141 p.

Driese, S.G., and Mora, C.I., 1993, Physico-chemical environment of pedogenic carbonate formation in Devonian vertic paleosols, central Appalachians, USA: Sedimentology, v. 40, p. 199-216.

Dunham, R.J., 1969, Vadose Pisolite in the Capitan Reef (Permian), New Mexico and Texas, in Freidman, G.M., ed., Depositional Environments in Carbonate Rocks: SEPM Spec. Pub. 14, p. 182-191.

Goudie, A.S., 1983, Calcrete, in Goudie, A.S., and Pye, K., eds., Chemical Sediments and Geomorphology: London, Academic Press, p. 93-131.

Fox. D., and Koch, P., 2004, Carbon and oxygen isotopic variability in Neogene paleosol carbonates: constraints on the evolution of the C4-grasslands of the Great Plains: Palaeogeography, Palaeoclimatology, Paleoecology, v. 207, p. 305-329.

Francis, J.E., 1986, The calcareous paleosols in the basal Purbeck Formation (Upper Jurassic), southern England, in Wright, V.P., ed., Paleosols: Their Recognition and Interpretation: Princeton, Princeton University Press, p. 112-138.

Hassouba, A.B.H., 1996, Caliche deposits from the Quaternary coastal plain of northwestern Egypt from Alexandria to El Omayid: Carbonates and Evaporites, v. 11, p. 195-205.

James, N.P., 1972, Holocene and Pleistocene calcareous crust (caliche) profiles: criteria for subaerial exposure: Journal of Sedimentary Petrology, v. 42, p. 817- 836.

Klappa, C.F., 1983, A process-response model for the formation of pedogenic calcretes, in Wilson, R.L.C., Residual Deposits: Surface Related Weathering Processes and Materials: London, Blackwell Scientific Publications, p. 211-220.

Machette, M.N., 1985, Calcic soils of the southwestern United States, in Weide, D.L., ed., Soils and Quaternary Geology of the Southwestern United States: Geol. Soc. Amer. Sp. Paper 203, p. 1-21.

Mack, G.H., Cole, D.R., Giordano, T.H., Schaal, W.C., and Barcelos, J.H., 1991, Paleoclimatic controls on stable oxygen and carbon isotopes in caliche of the Abo Formation (Permian), south-central New Mexico, U.S.A.: Journal of Sedimentary Petrology, v. 61, p. 458-472.

Monger, H.C., Daugherty. L.A., Lindemann, W.C., and Liddell, C.M., 1991, Microbial precipitation of pedogenic calcite: Geology, v. 19, p. 997-1000.

Newman, B.D., Campell, A.R., Norman, D.I., and Ringleberg, D.B., 1997, A model for microbially induced precipitation of vadose-zone calcites in fractures at Los alamos, New Mexico, USA: Geochimica et Cosmochimica Acta, v. 61, p. 1783- 1792.

Purvis, K., and Wright, V.P., 1991, Calcretes related to phreatotypic vegetation from the Middle Triassic Otter Sandstone of South West England: Sedimentology, v. 38, p. 539-551.

Reeves, C.C., Jr., 1976, Caliche: Origin, Classification, Morphology, and Uses: Lubbock, TX, Estacado Books, 233 p.

Rossinsky, V., Jr., and Wanless, H.R., 1992, Topographic and vegetative controls on calcrete Formation, Turks and Caicos Island, British West Indies: Journal of Sedimentary Petrology, v. 62, p. 84-98.

Royer, D.L., 1999, Depth to pedogenic carbonate horizon as a paleoprecipitation indicator?: Geology, v. 27, p. 1123-1126. (Discussion and reply v. 28, p. 572- 573).

Spštl, C., and Wright, V.P., 1992, Groundwater dolocretes from the Upper Triassic of the Paris Basin, France: a case study of an arid, continental diagenetic facies: Sedimentology, v. 39, p. 1119-1136.

Swineford, A., Leonard, A.B., and Frye, J.C., 1958, Petrology of the Pliocene pisolitic limestone of the Great Plains: Kansas Geol. Survey Bull. 130, p. 97-116. Tandon, S. K., and Gibling, M. R., 1997, Calcretes at sequence boundaries in Upper Carboniferous cyclothems of the Sydney Basin, Atlantic Canada: Sedimentary Geology, v. 112, p. 43-67.

Theriault, P., and Desrochers, A., 1993, Carboniferous calcretes in the Canadian Arctic: Sedimentology, v. 40, p. 449-465.

Wright, V.P., and Peeters, C., 1989, Origins of some Early Carboniferous calcrete fabrics revealed by cathodoluminescence: implications for interpreting the sites of calcrete formation: Sedimentary Geology, v. 65, p. 345-353.

 

 

Speleothems
See the Bibliography of the Atlas of Speleothem Microfabrics

 

 

References on Travertine, Tufa, and Other Odd Carbonates
L.B. Railsback, with thanks to Shaw-Wen Sheen

Amundson, R.G., and Kelly, E., 1987, The chemistry and mineralogy of a CO2-rich travertine depositing spring in the California Coast Range: Geochimica et Cosmochimica Acta, v. 51, p. 2883-2890.

Arribas, M.E., and Arribas, J., 2007, Interpreting carbonate particles in modern continental sands: an example from fluvial sands (Iberian Range, Spain), in Arribas, J., Critelli, S., and Johnsson, M.J., eds., Sedimentary Provenance and Petrogenesis: Perspectives from Petrography and Geochemistry: Geological Society of America Special Paper 420, p. 176-179.

Banat, K.M., and Obeidat, O.M., 1996, Notes on biogenic tufas associated with the Zerqa- Ma'in hot springs of Jordan: Carbonates and Evaporites, v. 11, p. 213-218.

Barnes, I.,1965, Geochemistry of Birch Creek, Inyo County, California a travertine depositing creek in an arid climate: Geochimica et Cosmochimica Acta, v. 29. p. 85-112.

Buchardt, B., and nine others, 1997, Submarine columns of ikaite tufa: Nature, v. 390, p. 129-130.

Buczynski, C., and Chafetz, H.S., 1991, Habitat of bacterially induced precipitates of calcium carbonate and the influence of medium viscosity on mineralogy: Journal of Sedimentary Petrology, v. 61, p. 226-233.

Burger, D., 1990, The travertine complex of Antalya/Southwest Turkey: Zeitschrift fur Geomorphologie NF, Supplementband. 77. p. 25-46.

Casanova, J., 1986, East African rift stromatolites, in Frostick, I.E., et al., eds., Geol. Soc. London Spec. Pub. 25, p. 201-210.

Chafetz, H.S., Akdim, B., Julia, R., and Reid, A., 1998, Mn- and Fe-rich black travertine shrubs: bacterially (and nano-bacterially) induced precipitates: Journal of Sedimentary research, v. 68, p. 404-412.

Chafetz, H.S., and Folk, R.L., 1984, Travertines: depositional morphology and the bacterially constructed constituents: Jour. Sed. Petrol., v. 54, p. 289-316.

Chafetz, H.S., Rush, P.F., and Utech, N.M., 1991, Microenvironmental controls on mineralogy and habit of CaCO3 precipitates: an example from an active travertine system: Sedimentology, v. 38, p. 107-126.

Chafetz, H.S., Utech, N.M., and Fitzmaurice, S.P., 1991, Differences in the d18O and d13C signatures of seasonal laminae comprising travertine stromatolites: Journal of Sedimentary Petrology, v. 61, p. 1015-1028.

Council, T.C., and Bennett, P.C., 1993, Geochemistry of ikaite formation at Mono Lake, California: Implications for the origin of tufa mounds: Geology, v. 21, p. 971- 974. (Ikaite=CaCO3×6H2O)

Davaud, E. and Girardclos, S., 2001, Recent freshwater ooids and oncoids from western Lake Geneva (Switzerland): Indications of a common bacterially mediated origin: Journal of Sedimentary Research, v. 71, p. 423-429.

Dean, W.E., and Fouch, T.D., 1983, Lacustrine environment, in Scholle, P.A., Bebout, D.G., and Moore, C.H., Carbonate Depositional Environments: AAPG Memoir 33, p. 97-130.

Drysdale, R.N., and Gale,S.J., 1997, The Indarri Falls travertine dam, Lawn Hill Creek, northwest Queensland, Australia: Earth Surface Processes and Landforms, v. 22., p. 413-418.

Drysdale, R., and Gillieson,D., 1997, Micro-erosion meter measurements of travertine deposition rates: a case study from Louie Creek, northwest Queensland, Australia: Earth Surface Poocesses and Landforms, v. 22, p. 1037-1051.

Dunn, J.R., 1953, The origin of the deposits of tufa in Mono Lake: Journal of Sedimentary Petrology, v. 23, p. 18-23.

Emeis, K.C., Richnow, H.H., and Kempe, S., 1987, Travertine formation in Plitvice National Park, Yugoslavia: chemical versus biological control: Sedimentology, v. 34, p. 595-609.

Evans, J.E., 1999, Recognition and implications of Eocoene tufas and travertines in the Chadron Formation, White River Group, Badlands of South Dakota: Sedimentology, v. 46, p. 771-789.

Folk, R.L., 1990, Bacteria and carbonate precipitation in sulfurous hot springs, Viterbo, Italy: Abstracts of 13th International Sedimentological Congress, Nottingham, p. 172.

Folk, R.L., Chafetz, H.S., and Tiezzi, R.A., 1985, Bizarre forms of depositional and diagenetic calcite in hot spring travertines, central Italy, in N. Schneidermann and P.M. Harris, eds., Carbonate Cements: Soc. Econ. Paleont. Mineral. Sp. Pub. 36, p. 349-369.

Ford, T.D., and Pedley, H.M., 1996, A review of tufa and travertine deposits of the world: Earth-Science Reviews, v. 41, p. 117-176.

Fouke, B.W., and six others, 2000, Depositional facies and aqueous-solid geochemistry of travertine-depositng hot springs (Angel Terrace, Mammoth Hot Springs, Yellowstone National Park, U.S.A.: Journal of Sedimentary Research, v. 70, p. 565-585.

Giralt, S., Julia, R., and Klerkx, J., 2001, Microbial biscuits of vaterite in Lake Issy- Kul (Republic of Kyrgyzstan): Journal of Sedimentary Research, v. 71, p. 430- 435.

Guo, L., Andrews, J., Riding, R., Dennis, P., amd Dresser, Q., 1996, Possible microbial effects on stable carbon isotopes in hot-spring travertines: Journal of Sedimentary Research, v. 66, p. 468-473.

Guo, L., and Riding, R., 1992, Aragonite laminae in hot water travertine crusts, Rapolano Terme, Italy: Sedimentology, v. 39, p. 1067-1079.

Guo, L., and Riding, R., 1994, Origin and diagenesis of Quaternary travertine shrub fabrics, Rapolano Terme, central Italy: Sedimentology, v. 41, p. 499-520.

Guo, L., and Riding, R., 1998, Hot-spring travertine facies and sequences, Late Pleistocene, Rapolano Terme, Italy: Sedimentology, v. 45, p. 163-180.

Heimann, A., and Sass,E., 1989, Travertines in the northern Hula Valley, Israel: Sedimentology, v. 36., p. 95-108.

Hennig, G.J., Grun, H., and Brunnacker, K., 1983, Speleothems, travertines, and paleoclimates: Quaternary Research, v. 20, p. 1-29.

Herman, J.S., and Lorah, M.M., 1988, Calcite precipitation rates in the field: measurement and prediction for a travertine-depositing stream: Geochimica et Cosmochimica Acta, v. 52, p. 2347-2355.

Irion, G., and Muller, G., 1968, Mineralogy, petrology, and chemical composition of some calcareous tufa from the Schwabische Alb, Germany, in Muller, G., and Friedman, G.M., eds., Recent Developments in Carbonate Sedimentology in Central Europe: Berlin, Springer-Verlag, p. 157-171.

Jones, B., and Renault, R.W., 1996, Morphology and growth of aragonite crystals in hot-spring travertines at Lake Bogoria, Kenya Rift Valley: Sedimentology, v. 43, p. 323-340.

Jones, F.G., and Wilkinson, B.H., 1978, Structure and growth of lacustrine pisoliths from Recent Michigan marl lakes: Journal of Sedimentary Petrology, v. 48, p. 1103-1110.

Julia, R., 1983, Travertines, in Scholle, P.A., Bebout, D.G., and Moore, C.H., Carbonate Depositional Environments: AAPG Memoir 33, p. 64-72.

Kano, A., 1997, Characteristics and origins of the freshwater carbonate tufa; a review: Earth Science (Chikyu Kagaku), v. 51, p. 177-187 (Japanese with English summary).

Kostecka, A., 1993, Calcite from the Quaternary spring waters at Tylicz, Krynica, Polish Carpathians: Sedimentology, v. 40, p. 27-39.

Kronfeld, J., Vogel, J.C., Rosenthal, E., and Weinstein-Evron, M., 1988, Age and paleoclimatic implications of the Bet Shean travertines: Quaternary Research, v. 30, p. 298-303.

Leslie, A.B., Tucker, M.E., and Spiro, B., 1992, A sedimentological and stable isotopic study of travertines and associated sediments within Upper Triassic lacustrine limestones, South Wales, UK: Sedimentology, v. 39, p. 613-629.

Lorah, M.M., and Herman, J.S., 1988, The chemical evolution of travertine-depositing stream:geochemical processes and mass transfer reaction: Water Resources Research, v. 24, p. 1541-1552.

Love, K.M., and Chafetz, H.C., 1988, Diagenesis of laminated travertine crusts, Arbuckle Mountains, Oklahoma: Journal of Sedimentary Petrology, v. 58, p. 441-445.

Lucas, D., and Andrews, J., 1996, A re-examination of reported lacustrine vaterite formation in Holkham Lake, Norfolk, UK: Journal of Sedimentary Research, v. 66, p. 474-476.

Marker,M.E., 1971, Waterfall tufas: a fact of karst geomorphology in South Africa: Zeitschrift fźr Geomorphologie NF, Supplementband 12, p. 138-152.

Murphy, D.M., and Wilkinson, B.H., 1980, Carbonate deposition and facies distribution in a central Michigan marl lake: Sedimentology, v. 27, p.

Pedley, H.M., 1990, Classification and environmental models of cool freshwater tufas: Sedimentary Geology, v. 68, p. 143-154.

Pedley, M., Andrews, J., Ordonez, S., Garcia del Cura, M. A., Gonzalez Martin, J.-A., Taylor, D, 1996, Does climate control the morphological fabric of freshwater carbonates? A comparative study of Holocene barrage tufas from Spain and Britain: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 121, p. 239- 257.

Pentecost, A., 1990, The formation of travertine shrubs: Mammoth Hot Springs, Wyoming: Geological Magazine, v. 127, p. 159-168.

Pentecost, A., 2005 Travertine: Springer, 446 p. (ISBN 1402035233).

Pentecost, A., and Viles, H., 1994, A review and reassessment of travertine classification: Geographie Physique et Quaternaire, v. 48, p. 305-314.

Renault, R.W., Jones, B., and Tiercelin, J.J., 1998, Rapid in situ silicification of microbes at Loburu hot springs, Lake Bogoria, Kany Rift Valley: Sedimentology, v. 45, p. 1083-1103.

Riding, R., 2000, Microbial carbonates: the geological record of calcified bacterial-algal mats and biofilms: Sedimentology, v. 47, p. 179-214.

Szabo, B.J., 1990, Ages of travertine deposits in eastern Grand Canyon National Park Arizona: Quaternary Research, v. 34, p. 24-32.

Viles, H.A., and Goudie, A.S., 1990, Tufas, travertines and allied carbonate deposits: Progress in Physical Geography, v. 24, p. 19-41.

Viles, H.A., and Goudie, A.S., 1990, Reconnaissance studies of the tufa deposits of the Napier Range, N.W. Australia: Earth Surface Processes and Landforms, v. 15, p. 425-443.

Wilkinson, B.H., Popp, B.N., and Owen, R.M., 1980, Nearshore ooid formation in a modern temperate region marl lake: Journal of Geology, v. 88, p. 697-704.

Zhang, D.D., Zhang, Y., Zhu, A., and Cheng, X., 2001, Physical methods of river waterfall tufa (travertine) formation: Journal of Sedimentary Research, v. 71, p. 205-216.

 

 

Selected References on Cathodoluminescence

Baker, A., Genty, D., and Smart, P.L., 1998, High-resolution records of soil humification and paleoclimatic change from variations in speleothem luminescence excitation and emission wavelengths: Geology, v. 26, p. 903-906.

Barker, C.E., Higley, D.K., and Dalziel, M.C., 1991, Using cathodoluminescence to map regionally zoned cements occurring in diagenetic aureoles above oil reservoirs: Initial results from the Velma oil fields of Oklahoma, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 155-160.

Boggs, S., and Krinsley, D., 2006, Application of Cathodoluminescence Imaging to the Study of Sedimentary ROcks: Cambridge, 180 p.

Budd, D.A., Hammes, U., and Ward, B.W., 2000, Cathodoluminescence in calcite cements: new insights on Pb and Zn sensitizing, Mn activation, and Fe quenching at low trace-element concentrations: Journal of Sedimentary Research, v. 70, p. 217- 226.

Fairchild, I.J., 1983, Chemical controls of cathodoluminscence of natural dolomites and calcites: new data and review: Sedimentology, v. 30, p. 579-583.

Fawcett, M.D., 1992, A modification for improved electron gun current control in cold cathode CL microscopy: Journal of Sedimentary Petrology, v. 62, p. 721-724.

Fern‡ndez-D’az, L., Putnis, A., Prieto, M., and Putnis, C., 1996, The role of magnesium in the crystallization of calcite and aragonite in a porous medium: Journal of Sedimentary Research, v.66, p. 482-491.

Filipelli, G.M., and Delaney, M.L., 1993, The effects of Manganese(II) and Iron(II) on the cathodoluminescence signal in synthetic apatite: Journal of Sedimentary Petrology, v. 63, p. 167-173.

Filipelli, G.M., and Delaney, M.L., 1992, Quantifying cathodoluminescent intensity with an on-line camera and exposure meter: Journal of Sedomentary Petrology, v. 62, p. 724-725.

Garlick, G.F.J., 1966, Cathodo- and radioluminescence, in Goldberg, P., ed., Luminescence of inorganic solids: London, Academic Press, p. 685-731.

Grover, G.A., Jr., and Read, J.F., 1983, Paleoaquifer and deep burial related cements defined by regional cathodoluminescent patterns, Middle Ordovician carbonates, Virginia: Amer. Assoc. Petrol. Geol. Bull., v. 67, p. 1275-1303.

Houseknecht, D.W., 1991, Use of cathodoluminescence petrography for understanding compaction, quartz cementation and porosity in sandstones, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 59-66.

Kanaori, Y., 1986, A SEM cathodoluminescence study of quarts in mildly deformed granite from the region of Atotsugawa fault, central Japan: Tectonophysics, v. 131, p. 133-146.

Kaufman, J., Cander, H.S., Daniels, L.D., and Meyers, W.J., 1988, Calcite cement stratigraphy and cementation history of the Burlington-Keokuk Formation (Mississippian), Illinois and Missouri: Jour. Sed. Petrol., v. 58, p. 312-326.

Long, J.V.P., and Agrell, S.O., 1965, The cathodo-luminescence of minerals in thin section: Mineralogical Magazine, v. 34, p. 318-326.

Machel, H.-G., 1986, Cathodoluminescence in calcite and dolomite and its chemical interpretation: Geosci. Canada, v. 12, p. 139-147.

Machel, H.G., and Burton, E.A., 1991, Factors governing cathodoluminescence in calcite and dolomite and their implications for studies of carbonate diagenesis, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 37-57.

Machel, H.G., Mason, R.A., Mariano, A.N., and Mucci, A., 1991, Causes and measurements of luminescence in calcite and dolomite, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 9-26.

Major, R.P., 1991, Cathodoluminescence in post-Miocene carbonates, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 149-154.

Marshall, D.J. 1978, Suggested standards for the reporting of cathodoluminescence results: Jour. Sed. Petro., v. 48, p. 651-653.

Marshall, D.J., 1988, Cathodoluminescence of Geological Materials: Boston, Unwin Hyman, 146 p.

Marshall, D.J., 1991, Combined cathodoluminescence and energy dispersive spectrometry, in Barker, C.E., and Kopp, O.C., eds., Luminescence microscopy: Qualitative and quantitative applications: SEPM Short Course Notes No. 25, p. 27-36.

Mason, R.A., 1994, Effects of the heating and prolonged electron bombardment on cathodoluminescence emission from synthetic calcite: Chemical Geology, v. 111, p. 245-260.

Mason, R.A., 1998, The response of luminescence in synthetic calcite to laboratory heating: Canadian Mineralogist, v. 36, p. 1089-1104.

Meyers, W.J., 1974, Carbonate cement stratigraphy of the Lake Valley Formation (Mississippian), Sacramento Mountains, New Mexico: Jour. Sed. Petrol., v. 44, p. 837-861.

Pacey, N.R., 1986, Luminescent properties of calcite in the English chalk: Modern Geology, v. 10, p. 29-38.

Pierson, B.J., 1981, The control of cathodoluminescence in dolomite by iron and manganese: Sedimentology, v. 28, p. 601-610.

Ramseyer, K., Baumann, J., Matter, A., And Mullis, J., 1988, Cathodoluminescence colours of a-quartz: Mineral. Mag., v. 52, p. 669-677.

Ramseyer, K., Fischer, J., Matter, A., and Eberhardt, P. and Geiss, J., 1989, A cathodoluminescence microscope for low intensity luminescence: Jour. Sed. Petrol., v. 59, p. 619-622.

Reed, R.M., and Milliken, K.L., 2003, How to overcome imaging problems associated with carbonate minerals on SEM-based cathodoluminescence systems: Journal of Sedimentary Research, v. 73, p. 328-332. Searl, A., 1991, Sawtooth zoned calcite cements in Dinantian grainstones from South Wales (U.K.): Jour. Sed. Petrol., v. 61, p. 195-201.

Sommer, S.E., 1972, Cathodoluminescence of carbonates, I. Characterization of cathodoluminescence from carbonate solid solutions: Chemical Geology, v. 9, p. 257-273.

Sprunt, E.S., 1981, Causes of quartz cathodoluminescence colors: Scanning Electron MIcroscopy/1981, v. 1, p. 525-535.

Sprunt, E.S., Dengler, L.A., and Sloan D., 1978, Effects of metamorphism on quartz cathodoluminescence: Geology, v. 6, p. 305-308.

Walkden, G.M., and Berry, J.R., 1984, Syntaxial overgrowths in muddy crinoidal limestones: cathodoluminescence sheds new light on an old problem: Sedimentology, v. 31, p. 251-267.

Wang, Y., and Merino, E., 1992, Dynamic model of oscillatory zoning in calcite: Double layer, inhibition, and self-organization: Geochim. Cosmochim. Acta, v. 56, p. 587-596.

Wogelius, R.A., Fraser, D.G., Wall, R.T., and Grime, G.W., 1997, Trace element and isotopic zonation in vein calcite from the Mendip Hills, UK, with spatial-process correlation analysis: Geochimica et Cosmochimica Acta, v. 61, p. 2037-2051.

Wright, V.P., and Peeters, C., 1989, Origins of some Early Carboniferous calcrete fabrics revealed by cathodoluminescence: implications for interpreting the sites of calcrete formation: Sedimentary Geology, v. 65, p. 345-353.

Yacobi, B.G., and Holt, D.B., 1990, Cathodoluminescence Microscopy of Inorganic Solids: New York, Plenum, 292 p.

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