When lignosulfonate concentration w

When lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at pWhen lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at pWhen lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at pWhen lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at pWhen lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at pWhen lignosulfonate concentration was further increased to as
high as 15 mg/L which equals to higher than 200 g/t lignosulfonate
in flotation tests, attraction forces between the AFM tip and
Table 2
Fitting results of the adsorption of lignosulfonate on kaolinite and pure coal surfaces in deionised or synthetic saline water.
Mineral Water Langmuir equation Freundlich equation
Fitting equations R2 Fitting equations R2
Kaolinite Deionised water 1/q = 136.06(1/c) + 1.6085 0.961 log10(q) = 0.443(log10c)  1.4677 0.811
Saline water 1/q = 22.038(1/c) + 0.2805 0.998 log10(q) = 0.5459(log10c)  0.8851 0.903
Pure coal Deionised water 1/q = 21.334(1/c) + 0.616 0.989 log10(q) = 0.4818(log10c)  0.9326 0.973
Saline water 1/q = 16.042(1/c) + 0.3911 0.995 log10(q) = 0.4745(log10c)  0.7587 0.935
Fig. 6. Approach force curves between a silicon nitride tip and graphite substrate in
deionised water and synthetic saline water at p