Kinetics , Equilibrium , and Thermodynamic Studies on Adsorption of Methylene Blue by Carbonized Plant Leaf Powder

Carbon synthesized from plant leaf powder was employed for the adsorption ofmethylene blue from aqueous effluent. Effects of pH (2, 4, 6, 8, and 9), dye concentration (50, 100, 150, and 200mg/dm), adsorbent dosage (0.5, 1.0, 1.5, and 2.0 g/dm), and temperature (303, 313, and 323K) were studied. e process followed pseudo-second-order kinetics. Equilibrium data was examined with Langmuir and Freundlich isotherm models and Langmuir model was found to be the best �tting model with high R and low chi values. Langmuir monolayer adsorption capacity of the adsorbent was found to be 61.22 mg/g. From the thermodynamic analysis, ΔH, ΔG, and ΔS values for the adsorption of MB onto the plant leaf carbon were found out. From the values of free energy change, the process was found out to be feasible process. From the magnitude of ΔH, the process was found to be endothermic physisorption.


Introduction
Synthetic dyes in large variety and quantity are used by several industries for coloring their products [1][2][3].Considerable amount of the dyes added in the process remain unconsumed and ultimately �nd their way to water bodies.Presence of dyes in water bodies poses serious threat to the environment as the color affects the nature of the water and makes it unsuitable for human consumption.Apart from being aesthetically displeasing, colored water also reduces photosynthetic action by preventing penetration of light [2].Some dyes and/or their metabolites have carcinogenic, mutagenic and teratogenic effects on aquatic life and human beings [2,4].As adsorption is one of the most efficient techniques available for dye removal [5] and the commercial adsorbents like activated carbon are expensive [6], search is carried by several researchers for identifying low-cost adsorbents.

Preparation of Carbon.
Senescent plant leaves were collected from the local garden.Most of these leaves were mainly of teak (Tectona grandis) and Guava (Psidium guajava) trees.e collected plant leaves were dried in hot air oven at 100 ∘ C to complete dryness and then ground in a mixer.e powder was �lled in self-sealed silica crucibles and heated at 500 ∘ C in a muffle furnace for one hour.Carbonized powder was cooled to room temperature in desiccators and screened using BSS (British Standard Screen) test sieves.Particles of mesh size −150 + 200 size (average particle size 90 m) were collected and used for further studies.In the present investigation,      unit, and used without further puri�cation.�ne gram of MB was dissolved in double distilled water to prepare stock solution (1000 mg/dm 3 ).Stock solution was later diluted to required concentrations.Methylene blue is selected in this study for it is (i) widely used by textile industries, (ii) well known for its adsorption characteristics, and (iii) toxic.

Batch Adsorption Studies.
For each run, 100 mL of dye solution of desired concentration was taken in 250 mL conical �asks.pH of the solution was ad�usted by addition T 2: Effect of concentration, adsorbent dosage, and solution temperature on adsorption of MB onto PLC.
0 (mg/dm 3 ) D (g/dm 3 ) Speci�c uptake of dye at any time "" was calculated using the following equation: where   = speci�c uptake (amount of dye adsorbed/amount of adsorbent used, mg/g) at time "t" min,  = amount of adsorbent used (g/dm 3 ), and  0 and   are aqueous phase concentration of MB at time  = 0 and  =  min, respectively (mg/dm 3 ).
Values of  2 and   were estimated by linear regression.

Equilibrium and ermodynamic Analysis.
Most frequently employed isotherm models, namely, Langmuir [30] and Freundlich [31] were used in this study for equilibrium analysis.
Langmuir isotherm is given by the following expression: where   = equilibrium dye concentration in liquid phase (mg/dm 3 ),   = Langmuir adsorption constant (dm 3 mg −1 ),   = Langmuir isotherm parameter, and maximum dye adsorbed/unit mass of adsorbent (mg g −1 ).A dimensionless separation factor   expressed as a function of   is oen employed as indicator of the feasibility of any adsorption process.It is de�ned as   = 1/(1 +    0 ).Adsorption process is considered to be feasible if value of   lies between 0 and 1.

Effect of Initial Solution pH.
One of the variables that most in�uence the adsorption process is pH.us, effect of pH on adsorption of MB on PLC was studied by varying the pH.Equilibrium uptakes of PLC at various initial solution pH are shown in Figure 1 along with corresponding �nal pH.However, earlier reports on adsorption on basic dyes on activated carbon suggest that equilibrium dye uptake increase with increasing initial solution pH.In the case of activated carbon, adsorption was due to the electrostatic attraction between the dye molecules and the adsorbent.As the activated carbon is protonated at low pH, adsorption of cationic dyes is favored by increase in initial solution pH.However, in this paper, uptake was low at both high (9) and low (2) pH.is suggests that electrostatic forces may not be solely responsible for the dye adsorption on PLC.
Since PLC used in this study had not been activated (does not contain active sites), this may be possible.However, this observation suggests that more detailed study is required.Estimated pseudo-second-order kinetic parameters are listed in Table 1.High  2 value con�rms the suitability of pseudosecond-order model to explain the kinetics of MB adsorption onto PLC.However, the remaining studies were conducted at pH 7 to avoid possible operational difficulties involved in the use of low pH (like 4).

Effect of Dye Concentration.
Effect of concentration on adsorption of MB onto PLC was studied by varying concentration from 50 to 200 mg/dm 3 .Second-order kinetic parameters are shown in Table 2.It could be noticed that adsorption rate constant  2 decreased with increase in concentration of the dye.Meanwhile, maximum speci�c uptake increased with increase in initial concentration.ese observations were consistent with earlier reports [3,[32][33][34][35][36][37].
In order to predict the kinetic parameters  2 in terms of initial dye concentration following models was proposed [38]: Regression coefficients ( 1 ,  2 , and  3 ) and coefficient of determinations ( 2 ) were determined using nonlinear regression.Substituting the regression coefficients, the following empirical equation was obtained: Comparison of predicted pseudo-second-order kinetics with the experimental data is shown in Figure 2.

Effect of Adsorbent Dosage.
Figure 3 illustrates the effect of adsorbent dosage on adsorption of MB.Dye uptake was found to decrease with increase adsorbent dosage.is was due to the fact that at smaller adsorbent dosages fraction of active sites saturated with dye increases.is was consistent with previous reports [29].It was evident from this �gure that initial rate of adsorption was much higher when the adsorbent dosage was higher.e values of kinetic parameters along with initial adsorption rate are given in Table 2. Initial rate of adsorption is de�ned as the product of kinetic rate constant and square of equilibrium uptake (ℎ =  2  2  , mg g −1 min −1 ) [29].

Effect of Temperature.
Effect of temperature is shown in Figure 4. Pseudo-second-order model �ts the experimental data very well and the kinetic parameters are shown in Table 2 along with the regression coefficients.Uptake decreases with increase in temperature while kinetic constant increase with increase in temperature.Temperature dependency of the rate constant was exponential and follows Arrhenius law [38].A plot of ln  2 versus 1/ was a straight line (plot not shown here).Activation energy of the process was determined from the slope of the Arrhenius plot.It was found to be 33.95kJ/mol.T 3: Equilibrium parameters for adsorption of MB onto PLC.

Langmuir Freundlich
, dm 3 /mg 0.205   , (mg/g) (dm 3 /mg) of Δ indicate the feasibility of the process.Positive value of other Δ indicates that the process is endothermic.Positive Δ indicated increased disorder of the dye molecules on the solid surface aer adsorption.Low value of Δ also suggests that the adsorption may be due to physical binding forces.e earlier observation, increasing dye uptake with increasing temperature, is also consistent with this �nding.

Conclusion
Adsorption of MB onto carbon derived from plant leaves (PLC), an agro-waste, was studied.Effects of variables like initial solution pH, initial dye concentration, amount of adsorbent used, and solution temperature were studied in batch mode.Adsorption kinetics was well described by pseudo-second-order model.Using Arrhenius equation, activation energy of MB adsorption on PLC was estimated to be 33.35kJ/mol.Langmuir monolayer adsorption capacity (  ) was determined to be 61.22 mg/g.From the thermodynamic parameters, it can be concluded that the process was spontaneous endothermic physisorption.From the results of the study, it could be concluded that PLC can be effectively used for the removal of methylene blue from aqueous solutions.
HCl or 0.1 � �aOH as needed.�e�nite quantity of PLC was added to the solution and the mixture was kept in an incubated orbital shaker at 200 RPM.Samples were drawn from the mixture using a �ne tip syringe at regular time intervals for analysis.Samples were centrifuged and concentrations of supernatant solutions were determined by measuring absorbance at  max (662 nm) using UV-Vis spectrophotometer (Systronics 2201).When the absorbance exceeded 1.0, the solution was suitably diluted with doubled distilled water and concentration of diluted solution was determined.
[39][40][41].It was found that Langmuir model �t the data well with high 2and low chi 2 values when compared to that of Freundlich model.eLangmuirandFreundlichisothermparametersat303Karegiven in Table3along with  2 and  2 values[39][40][41].ecomparison of experimental data with the predicted values at 303 K is given in Figure5.Dimensionless parameter   suggests that adsorption of MB onto PLC is a feasible process.Acomparison of adsorption potential of PLC with other adsorbents reported recently in the literature is given in Table4.It could be seen that adsorption of potential of PLC was low compared to that of various activated carbons.s is expected and logical as the PLC reported in this study is not activated.However, the adsorption potential of PLC was better than that of many natural/unmodi�ed alternate adsorbents reported in the literature.3.6.rmodynamicAnalysis.e Lnguir parameter  was used to determine the thermodynamic parameter Gibb's free energy change which is an indicator of feasibility of the adsorption process.Meanwhile, a plot of ln   versus 1/ (�gure not shown here) gives other thermodynamic parameters, namely, enthalpy and entropy changes of adsorption process.sevalues are shown in Table5. Negtive values T 4: Comparison of adsorption capacities of low cost adsorbents.