Kinetics of calcite precipitation induced by ureolytic bacteria at 10 to 20°C in artificial groundwater
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Vernon R. Phoenix | Y. Fujita | R. Smith | F. G. Ferris | V. Phoenix | Yoshiko Fujita | Robert W. Smith | F. Ferris
[1] W. House. Kinetics of crystallisation of calcite from calcium bicarbonate solutions , 1981 .
[2] W. W. Wood,et al. Aqueous geochemistry and diagenesis in the eastern Snake River Plain aquifer system, Idaho , 1986 .
[3] J. Gómez-Morales,et al. Nucleation of calcium carbonate at different initial pH conditions , 1996 .
[4] B. Lollar,et al. Microbial precipitation of a strontium calcite phase at a groundwater discharge zone near rock Creek, British Columbia, Canada , 1995 .
[5] J. Xu,et al. Fertilizer and temperature effects on urea hydrolysis in undisturbed soil , 1993, Biology and Fertility of Soils.
[6] Frederick S. Colwell,et al. Subscribed Content Calcium Carbonate Precipitation by Ureolytic Subsurface Bacteria , 2000 .
[7] T. Jahns,et al. Ammonium/urea-dependent generation of a proton electrochemical potential and synthesis of ATP in Bacillus pasteurii , 1996, Journal of bacteriology.
[8] A. E. Nielsen. Kinetics of precipitation , 1964 .
[9] P. Dove,et al. Kinetics of calcite growth: Surface processes and relationships to macroscopic rate laws , 2000 .
[10] A. Gutjahr,et al. Studies of the growth and dissolution kinetics of the CaCO3 polymorphs calcite and aragonite. II: The influence of divalent cation additives on the growth and dissolution rates , 1996 .
[11] C. E. Cowan,et al. Sorption of divalent metals on calcite , 1991 .
[12] Susan L. Brantley,et al. Kinetics of near-equilibrium calcite precipitation at 100°C: An evaluation of elementary reaction-based and affinity-based rate laws , 1995 .
[13] P. Zuddas,et al. Kinetics of Calcite Precipitation from Seawater: II. The Influence of the Ionic Strength , 1998 .
[14] P. Karplus,et al. The crystal structure of urease from Klebsiella aerogenes. , 1995, Science.
[15] T. Onstott,et al. Recent calcite spar in an aquifer waste plume: a possible example of contamination driven calcite precipitation , 2000 .
[16] R. C. Bartholomay,et al. CHEMICAL CONSTITUENTS IN THE DISSOLVED AND SUSPENDED FRACTIONS OF GROUND WATER FROM SELECTED SITES, IDAHO NATIONAL ENGINEERING LABORATORY AND VICINITY, IDAHO, 1989 , 1992 .
[17] G. H. Nancollas,et al. The crystallization of calcium carbonate , 1971 .
[18] D. G. Smith,et al. Hydrolysis of urea by Ureaplasma urealyticum generates a transmembrane potential with resultant ATP synthesis , 1993, Journal of bacteriology.
[19] L. Bakken,et al. Nitrification potential and urease activity in a mineral subsoil , 1998 .
[20] J. M. Zachara,et al. Chemical contaminants on DOE lands and selection of contaminant mixtures for subsurface science research , 1992 .
[21] A. Pentecost,et al. Stable carbon and oxygen isotope composition of calcites associated with modern freshwater cyanobacteria and algae , 1990 .
[22] Petros G. Koutsoukos,et al. Kinetics of Precipitation of Calcium Carbonate in Alkaline pH at Constant Supersaturation. Spontaneous and Seeded Growth , 1998 .
[23] R. Dawe,et al. The kinetics of calcite precipitation from a high salinity water , 1998 .
[24] J. Sørensen,et al. Significance of microbial urea turnover in N cycling of three Danish agricultural soils , 1998 .
[25] F. G. Ferris,et al. Bacteriogenic mineral plugging , 1996 .
[26] S. Bang,et al. Microbiological precipitation of CaCO3 , 1999 .
[27] R. Burne,et al. Construction and characterization of a recombinant ureolytic Streptococcus mutans and its use to demonstrate the relationship of urease activity to pH modulating capacity. , 1997, FEMS microbiology letters.
[28] O. Söhnel,et al. Kinetics of growth of calcite crystals in presence of ammonium ions , 1990 .
[29] J. Pankow,et al. Solid solution partitioning of Sr2+, Ba2+, and Cd2+ to calcite , 1996 .
[30] Donald L. Suarez,et al. Calcite nucleation and precipitation kinetics as affected by dissolved organic matter at 25°C and pH > 7.5 , 1996 .
[31] T. Beveridge,et al. Nucleation of Celestite and Strontianite on a Cyanobacterial S-Layer , 1994, Applied and environmental microbiology.
[32] J. Sternbeck,et al. A mechanistic model for calcite crystal growth using surface speciation , 1999 .
[33] Terry J. Beveridge,et al. Surface-mediated mineral development by bacteria , 1997 .
[34] S. Ciurli,et al. Bacillus pasteurii urease: A heteropolymeric enzyme with a binuclear nickel active site , 1996 .
[35] Frederick S. Colwell,et al. Calcium Carbonate Precipitation by Ureolytic Subsurface Bacteria , 2000 .
[36] Yuping Zhang,et al. Influence of Mg2+ on the kinetics of calcite precipitation and calcite crystal morphology , 2000 .
[37] F. G. Ferris,et al. Cyanobacterial precipitation of gypsum, calcite, and magnesite from natural alkaline lake water , 1990 .
[38] P. Maurice,et al. Microbially Mediated Calcium Carbonate Precipitation: Implications for Interpreting Calcite Precipitation and for Solid-Phase Capture of Inorganic Contaminants , 2001 .
[39] W. S. Fyfe,et al. Precipitation of carbonate minerals by microorganisms: Implications for silicate weathering and the global carbon dioxide budget , 1994 .