Kaolins: their properties and uses

Jepson, W. B.

doi:10.1098/rsta.1984.0037

Cited by 79 publications

(20 citation statements)

References 51 publications

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“…Prominent among these characteristics are the density of surface charge created by isomorphic substitutions in a mineral structure (denoted tr0) and that created by proton adsorption and desorption reactions with a contiguous aqueous solution (denoted ~). The sign of ~r 0 is always negative for kaolinite, arising either directly from AI(III) substitution for Si(IV) in the tetrahedral sheet of the mineral (Bolland et al 1976), or indirectly from isomorphic substitutions in 2:1 layer type clay mineral inclusions (Lim et al 1980;Jepson 1984;Kim et al 1996). The sign of tr H varies with aqueous solution pH, taking on a zero value at the p.z.n.p.c.…”

Section: Introductionmentioning

confidence: 99%

Surface Charge Properties Of Kaolinite

Schroth

Sposito

1996

MRS Proc.

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-The surface charge components of 2 Georgia kaolinites of differing degrees of crystallinity (KGa-1 and KGa-2) were determined using procedures based on charge balance concepts. Permanent structural charge density (tr0) was determined by measuring the surface excess of Cs, which is highly selective to permanent charge sites. The values of cr0 determined were -6.3 -~ 0.1 and -13.6 ---0.5 mmol kg -~ for kaolinites KGa-1 and KGa-2, respectively. The net proton surface charge density (trn) was determined as a function of pH by potentiometric titration in 0.01 mol dm -3 LiC1. Correction from apparent to absolute values of cr n was made by accounting for A1 release during dissolution, background ion adsorption and charge balance. Lithium and C1 adsorption accounted for the remainder of the surface charge components. Changes in surface charge properties with time were measured after mixing times of 1, 3 and 15 h. the latter representing "'equilibrium". Time-dependenl behavior is believed to be caused by mineral dissolution followed by readsorption or precipitation of A1 on the mineral surface. Both the point of zero net charge (p.z.n.c.) and the point of zero net proton charge (p.z.n.p.c.) changed with mixing time, generally increasing. The "'equilibrium" p.z.n.c, values were approximately 3.6 for KGa-1 and 3.5 for KGa-2, whereas the corresponding p.z.n.p.c, values were about 5.0 and 5.4. The p.z.n.c, results were in good agreement with previous studies, but the values of p.z.n.p.c, were higher than most other values reported for specimen kaolinite.

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Section: Introductionmentioning

confidence: 99%

Surface Charge Properties Of Kaolinite

Schroth

Sposito

1996

MRS Proc.

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“…Kaolinite is a mineral that has a wide variety of applications in industry, particularly as a paper filler and a coating pigment (Jepson, 1984). It is used as an extender in water based paints and ink, as a functional additive in polymers and is a major component of ceramics (Jepson, 1984).…”

Section: Introductionmentioning

confidence: 99%

The Effect of Surface Modification by an Organosilane on the Electrochemical Properties of Kaolinite

Braggs

Fornasiero

Ralston

et al. 1994

Clays and clay miner.

104

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Abstract--The electrochemical properties of kaolinite before and after modification with chlorodimethyloctadecylsilane have been studied by electrophoretic mobility, surface charge titration, and extrapolated yield stress measurements as a function of pH and ionic strength. A heteropolar model of kaolinite, which views the particles as having a pH-independent permanent negative charge on the basal planes and a pHdependent charge on the edges, has been used to model the data. The zeta potential and surface charge titration experimental data have been used simultaneously to calculate acid and ion complexation equilibrium constants using a surface complex model of the oxide-solution interface. The experimental data were modeled following subtraction of the basal plane constant negative charge, describing only the edge electrical double layer properties. Extrapolated yield stress measurements along with the electrochemical data were used to determine the edge isoelectric points for both the unmodified and modified kaolinite and were found to occur at pH values of 5.25 and 6.75, respectively. Acidity and ion complexation constants were calculated for both sets of data before and after surface modification. The acidity constants, pKat = 5.0 and pKa2 = 6.0, calculated for unmodified kaolinite, correlate closely with acidity constants determined by oxide studies for acidic sites on alumina and silica, respectively, and were, therefore, assigned to pH-dependent specific chemical surface hydroxyl groups on the edges of kaolinite. The parameters calculated for the modified kaolinite indicate that the silane has reacted with these pHdependent hydroxyl groups causing both a change in their acidity and a concomitant decrease in their ionization capacity. Infrared data show that the long chain hydrocarbon silane is held by strong bonding to the kaolinite surface as it remains attached after washing with cyclohexane, heating, and dispersion in an aqueous environment.

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“…In his review paper of kaolins, Jepson (1984) reported the range of aspect ratios for Cornish kaolins from 10 : I for coarse particles to 50 : 1 for the fine ones, also determined by transmission electron microscopy. Although measuring the aspect ratio by microscopy is direct and fundamentally simple, it has two serious drawbacks: the method is tedious and becomes subjective when individual kaolin particles cannot be clearly distinguished from clusters and spacial overlaps.…”

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confidence: 99%

Determination of Shape of Kaolin Pigment Particles

Slepetys¹,

Cleland²

1993

Clay miner.

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Characterization of platiness of kaolin pigments was derived from the divergence of measurements of their particle size distribution by two different techniques: sedimentation and light scattering. A numerical shape factor, which is related to the ratio of kaolin particle face diameter to its thickness, can be calculated to provide a quantitative measure of such platiness. Two sets of kaolin pigments were prepared from a Middle Georgia kaolin: delaminated and non-delaminated. Shape factors of delaminated samples were higher than those of non-delaminated ones. Maximum platiness was found between equivalent volume diameters of 1·0 and 2·0 μm. Examples are presented where properties of coated paper are correlated with the size and shape of kaolin pigments.

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Kaolins: their properties and uses

Cited by 79 publications

References 51 publications

Surface Charge Properties Of Kaolinite

Surface Charge Properties Of Kaolinite

The Effect of Surface Modification by an Organosilane on the Electrochemical Properties of Kaolinite

Determination of Shape of Kaolin Pigment Particles

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