Colloid And Surface Properties Of Clays And Related MineralsDiscusses measuring the surface properties of flat or particulate solids with contact angles of drops of high-energy liquids deposited on solid surfaces or via the thin-layer wicking technique. It focuses on Lifshitz-van der Waals, Lewis acid-base, and electrical double layer interactions. |
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Results 1-5 of 25
Page xv
... Temperature effects . 219 8.13 Nature of Clay - water Interactions 8.14 Structure of Bound Outer Layer Water 8.15 Swelling of Clays 220 221 221 8.15.1 Nature of the swelling mechanism 8.15.2 Prerequisite properties of swelling clays ...
... Temperature effects . 219 8.13 Nature of Clay - water Interactions 8.14 Structure of Bound Outer Layer Water 8.15 Swelling of Clays 220 221 221 8.15.1 Nature of the swelling mechanism 8.15.2 Prerequisite properties of swelling clays ...
Page 1
... temperatures leads to the chemical and physical breakdown of a wide variety of rock types . Thus , a mineral ( part of ... temperature fluctuations , attacks the mineral and a series of chemical reactions ensue producing a series of new ...
... temperatures leads to the chemical and physical breakdown of a wide variety of rock types . Thus , a mineral ( part of ... temperature fluctuations , attacks the mineral and a series of chemical reactions ensue producing a series of new ...
Page 2
... temperatures ( in a geological sense ) , reaction rates are slow and crystals of these new phases form slowly and imperfectly resulting in very small particle sizes , far smaller than would result from mechanical abrasion of larger ...
... temperatures ( in a geological sense ) , reaction rates are slow and crystals of these new phases form slowly and imperfectly resulting in very small particle sizes , far smaller than would result from mechanical abrasion of larger ...
Page 5
... temperature of only slightly more than 1000 Ā° C . Clays used for brick manufacture can contain a significant proportion of swelling clays which , upon firing tend to cause considerable shrinkage , which is one of the reasons for ...
... temperature of only slightly more than 1000 Ā° C . Clays used for brick manufacture can contain a significant proportion of swelling clays which , upon firing tend to cause considerable shrinkage , which is one of the reasons for ...
Page 6
... temperatures . To that effect refractory ceramics may not contain compounds that melt at the tem- peratures at which they are destined to be used , hi particular Fe - containing compounds must be avoided . The major clay varieties used ...
... temperatures . To that effect refractory ceramics may not contain compounds that melt at the tem- peratures at which they are destined to be used , hi particular Fe - containing compounds must be avoided . The major clay varieties used ...
Contents
XCI | 153 |
XCII | 154 |
XCIII | 156 |
XCIV | 159 |
XCVI | 162 |
XCVII | 163 |
XCIX | 165 |
CI | 166 |
XIX | 13 |
XX | 15 |
XXII | 17 |
XXIII | 19 |
XXIV | 20 |
XXV | 21 |
XXVII | 25 |
XXIX | 28 |
XXX | 36 |
XXXI | 39 |
XXXIII | 41 |
XXXIV | 46 |
XXXV | 47 |
XXXVII | 52 |
XXXVIII | 54 |
XXXIX | 60 |
XL | 61 |
XLI | 64 |
XLIII | 66 |
XLIV | 69 |
XLV | 72 |
XLVI | 79 |
XLVII | 81 |
XLIX | 84 |
L | 87 |
LII | 90 |
LIII | 93 |
LIV | 101 |
LVI | 104 |
LVII | 116 |
LVIII | 119 |
LX | 121 |
LXI | 123 |
LXII | 125 |
LXIII | 127 |
LXIV | 129 |
LXV | 130 |
LXVII | 131 |
LXVIII | 132 |
LXX | 133 |
LXXI | 134 |
LXXIII | 135 |
LXXV | 136 |
LXXVI | 137 |
LXXVII | 138 |
LXXVIII | 139 |
LXXIX | 141 |
LXXX | 142 |
LXXXII | 144 |
LXXXIII | 145 |
LXXXIV | 146 |
LXXXV | 148 |
LXXXVI | 149 |
LXXXVII | 151 |
LXXXVIII | 152 |
CII | 167 |
CIII | 168 |
CV | 169 |
CVII | 170 |
CVIII | 172 |
CIX | 173 |
CXI | 175 |
CXIII | 176 |
CXV | 178 |
CXVII | 181 |
CXVIII | 182 |
CXX | 183 |
CXXII | 184 |
CXXIII | 185 |
CXXIV | 186 |
CXXV | 190 |
CXXVI | 191 |
CXXVII | 193 |
CXXVIII | 194 |
CXXIX | 195 |
CXXXI | 202 |
CXXXII | 203 |
CXXXIV | 204 |
CXXXV | 208 |
CXXXVI | 209 |
CXXXVIII | 212 |
CXXXIX | 213 |
CXLI | 214 |
CXLII | 215 |
CXLIII | 216 |
CXLIV | 218 |
CXLVI | 219 |
CXLVII | 220 |
CXLVIII | 221 |
CL | 223 |
CLI | 224 |
CLII | 225 |
CLIII | 226 |
CLIV | 229 |
CLV | 230 |
CLVI | 235 |
CLVII | 239 |
CLVIII | 244 |
CLIX | 248 |
CLX | 251 |
CLXI | 252 |
CLXIII | 253 |
CLXV | 255 |
CLXVI | 256 |
CLXVII | 257 |
CLXVIII | 258 |
CLXIX | 261 |
CLXX | 285 |
Other editions - View all
Colloid And Surface Properties Of Clays And Related Minerals Rossman F. Giese,Carel J. van Oss No preview available - 2002 |
Colloid And Surface Properties Of Clays And Related Minerals Rossman F. Giese,Carel J. van Oss No preview available - 2002 |
Colloid And Surface Properties Of Clays And Related Minerals Rossman F. Giese,Carel J. van Oss No preview available - 2002 |
Common terms and phrases
adhesion adsorbed adsorption aluminum ammonium anions asbestos C-potential cations Central Atom Ligand Chaudhury chemical chrysotile clay minerals clay particles clinographic view closest packed cohesion Colloid Colloid Interface Sci contact angle contact angle measurements coordination density determined dioctahedral DLVO double layer edited electron electrostatic equation Figure flocculation free energy g/cc Giese glycerol Hamaker hectorite hydration hydrogen bonding hydrophilic hydroxyl illite immersed in water interaction energy interatomic distances interlayer cations ionic strength ions iwi iwi kaolinite layer charge Lifshitz-van der Waals Ligand Distance macroscopic materials mica mineral particles mJ/mĀ² molecular monopolar montmorillonite negatively charged octahedral octahedral sheet octahedral sites orientation oxide Oxygen oxygen atoms parameters phyllosilicate polar liquids polymers potential pyrophyllite radius repulsion silicate minerals silicon smectite solid surface solubility solution stability stacking surface properties surface tension surface thermodynamic Surfactants Table talc temperature tetrahedral thin layer wicking values vermiculite water molecules