Batch Adsorption Test of Phenol on Soils Mohd Raihan Taha Dept. of Civil & Structural Engineering, and Institute for Environment & Development (LESTARI) Universiti Kebangsaan Malaysia
Contents Introduction Batch Adsorption Test Adsorption Isotherms Test Materials Test Results Conclusion
Introduction: Malaysia
Introduction: Geology of Peninsular Malaysia Thailand Penang Kuala Lumpur Universiti Kebangsaan Malaysia North-South Highway Singapore
Introduction: Sorption Adsorption = Sticking on the soil surface contaminant soil Absorption = Penetrates into the soil particle contaminant soil
Introduction: Cross section of a landfill Geomembrane Waste to be placed in here Soil/Clay liner = low hydraulic conductivity, good stability against chemicals/contaminant, high adsorption/attenuation characteristics, etc.
Batch Adsorption Test Volume of chemical V (ml) Soil of mass M (g) Shake a mixture of known chemical concentration (C o ) and soil (M) between 18 to 24 hrs. Then final concentrations (C e ) were taken after 2 weeks of equilibration. Calculate the amount adsorbed (q) from the following formula: q= V ( C C ) M o e
Adsorption Isotherms: Linear Adsorption Isotherm q K d = Partition or distribution coefficient K d C e 1-D Advective-Dispersive Model for Contaminant Transport in Soil 2 L x C R = D t R C v 2 x ρ 1 + K n = d C x
Adsorption Isotherms: Freundlich Isotherm q 1 q= KC e n Ln q ln q= lnk+ 1 C n e linearised 1/n Ln K C e Ln C e K = Freundlich constant n = empirical constant
Adsorption Isotherms: Langmuir Isotherm q q = α β C e 1+ α Ce 1/q 1 q 1 = αβ 1 C 1 + e β linearised 1/αβ 1/β C e α = adsorption constant related to the binding energy or the "affinity" parameter 1/C e β = maximum amount of solute that can be adsorb by the soil
Test Materials: Grain Size Distrubution 120 100 % passing 80 60 40 20 residual soil kaolinite 0 0.001 0.01 0.1 1 10 Particle size (mm)
Test Materials: Some Basic Soil Properties Physical properties Granite residual Kaolinite soil Specific gravity 2.55 2.63 Natural moisture content(%) 31 - Liquid limit(%) 76.3 74.2 Plastic Limit (%) 27.5 41.5 ph 4.6 5.16 Organic Carbon Content (%) 1.37 0.88 Cation exchange capacity, 8.96 9.91 CEC, (mmol charge/100g) % clay fraction (<2 µm) 46 31
Test Materials: Phenol Phenol is an organic compound widely used in industries such as in the manufacturing plastics, lubricants, paints, pharmaceuticals, herbicides, and resins. Chemically, phenol is a hazardous chemical and if absorbed through skin, inhaled, or swallowed may lead to serious injuries and/or fatalities. One of the major hazard of phenol is its ability to penetrate the skin rapidly. Therefore most phenolic compounds are priority pollutants. For example, the United States Environmental Protection Agency (USEPA) established the drinking water standard for phenol at 1 ppb or less (Acar et al. 1992). As such its disposal have been and still a major issue especially in many developing countries where waste management industries are still in its infancy.
Test Results: Linear Adsorption Isotherm Phenol-Residual Soil Phenol-Kaolinite q (mg/kg) 40 35 30 25 20 15 10 5 0 0 1 2 3 4 q (mg/kg) 15 12 9 6 3 0 0 2 4 6 8 C e (mg/l) C e (mg/l) Figure 2 Linear adsorption isotherm for phenol-residual soil series at low concentrations. K d = 10.48 L/kg Figure 3 Linear adsorption isotherm for phenol-kaolinite series at low concentrations. K d = 1.18 L/kg Observation: 1. Plot is linear; 2. The residual soil has greater adsorption capacity
Test Results: Freundlich & Langmuir Isotherms Linearised Freundlich Linearised Langmuir Ln q 4 3 2 1 0-1 -2-3 -4 Granite residual soil Kaolinite -1 0 1 2 3 4 1/q 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 Kaolinite Granite residual soil 0 1 2 3 4 5 ln C e 1/C e Residual Soil Kaolinite Figure 4 Linearised Freundlich adsorption isotherm for phenolsoil interaction (low concentrations). K = 3.01 mg/kg 0.06 mg/kg Residual Soil Kaolinite Figure 5 Linearized Langmuir adsorption isotherm for phenolsoil interaction. α = 17.54 L/mg 6.33 L/mg n = 1.29 kg/l 0.93 mg/kg β = 238.1 mg/kg 23 mg/kg Observation: The parameters further indicate that the residual soil has greater adsorption capacity compared to the commercial kaolinite
Test Results: High Concentrations q (mg/kg) 300 250 200 150 100 50 0 Granite residual soil Kaolinite 0 20 40 60 80 100 Ce (mg/l) Observation: Use of linear K d is not justified Figure 6 A linear adsorption isotherm for phenol-soil interaction for all test results.
Test Results: High Concentrations Linearised Freundlich Linearised Langmuir Ln q 6 Granite residual soil 5 4 3 Kaolinite 2 1 0-2 0 2 4 6 1/q 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 Kaolinite Granite residual soil 0 1 2 3 4 5 Ln C e 1/C e Figure 7 Linearized Freundlich adsorption isotherm for phenol-soil interaction for all test data. Figure 8 Linearized Langmuir adsorption isotherm for phenol-soil interaction for all test data. Observation: A highly non-linear plot can be significantly linearised in Freundlich and Langmuir s isotherm
Test Results: High Concentrations q (mg/kg) 300 250 200 150 100 50 0 Granite residual soil Kaolinite 0 20 40 60 80 100 Ce (mg/l) Maximum adsorption = 245 mg/kg (compare with 238.1 mg/kg from low range adsorption). Maximum adsorption = 28 mg/kg (compare with 23 mg/kg from low range adsorption). Observation : Low range prediction can be used to estimate maximum adsorption
Conclusion 1. Adsorption test is one of the tests that can be used to evaluate the potential of a soil for a clay liner material. 2. The granite residual soil adsorb greater amounts of phenol compared to the commercial kaolinite. 3. Tests at low concentration yields linear K d whereas at low concentrations did not. 4. Low concentration tests can be used to estimate maximum adsorption capacity of soil.
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