Volume 05, Issue 09 (September 2016)

Removal of Lead from Paint Effluent using Low Cost Activated Adsorbent (Fluted Pumpkin Seed Shells)

DOI : 10.17577/IJERTV5IS090533

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T. O Chime, C. C Onyema, P. C. N Ejikeme, 2016, Removal of Lead from Paint Effluent using Low Cost Activated Adsorbent (Fluted Pumpkin Seed Shells), INTERNATIONAL JOURNAL OF ENGINEERING RESEARCH & TECHNOLOGY (IJERT) Volume 05, Issue 09 (September 2016),

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Removal of Lead from Paint Effluent using Low Cost Activated Adsorbent (Fluted Pumpkin Seed Shells)

T.O Chime, C.C Onyema, P.C.N Ejikeme Department of Chemical Engineering,

Enugu State University of Science and Technology, Enugu, Nigeria.

Abstract – Activated carbon produced from pumpkin seed shells was used as an adsorbent to remove lead ion from paint industrial effluent. The activated carbon produced was carbonized at 800oc for 2hours and then chemically produced with 9M KOH solution. Batch adsorption experiments were conducted at different conditions to examine the effects of adsorbent dosage, PH , contact time and temperature on adsorption of Pb2+ from paint effluent. The results obtained showed that, the adsorption of Pb2+ was dependent on the adsorbent dosage, PH, contact time and temperature. The optimum adsorption was recorded at dosage of 0.3g, time of 60 minutes, PH of 6 and temperature of 30oC ; and 97.97% removal efficiency was obtained. The Linear regression coefficient R2 of 0.997 for Langmuir model made the best fit.

Key words: Activated carbon, Adsorption, Isotherm studies, lead

(II) ions, paint effluent

INTRODUCTION

Environmental pollution problems caused by heavy metals cannot be over emphasized. Waste water from numerous industries such as paints and pigments, glass production, mining operations, metal plating and battery manufacturing processes are known to contain contained contaminants such as heavy metal. Heavy metals such as Pb(II), Cd(II), Hg(II), Ni(II), Zn(II), Cu(II) and Fe are present in industrial waste water (Mhemet et al, 2006).

b

b

Lead (Pb(II)) is one of the common heavy metals found in paint industrial waste water. Heavy metals are not biodegradable and tend to be accumulated in organisms and cause numerous diseases and disorders (Ozer and Pirincci, 2006). Chronic exposure to high amount of lead can result in various and considerable damages to system of the body, including nervous and reproductive systems and kidneys. Moreover, high blood pressure, anemia, lead poisoning, coma and death can be considered among the most substantial consequences (PCS, 2001). Lead as P 2+ ion has a large affinity for the thio (-SH) and phosphate ion (PO4) which contain enzymes, ligands and bio-molecules, thereby inhibiting the biosynthesis of heme units, affecting membrane permeability of kidney, liver and brain cells. These result in either reduced functions or complete breakdown of these organs. Lead form complexes with oxo-groups in enzymes to affect virtually all steps in the

process of Hemoglobin synthesis and porphyrin metabolism (Ademorati, 1996).

Therefore, the elimination of heavy metals such as lead from the environment is important as a result of its high toxicity and at least to protect public health(Abdel-Ghani and El-Chaghaby, 2007; Abdel-Ghan et al.,2009; Resmi et al., 2010). Many researchers have reported the removal of heavy metals; Pb(II), using several physiochemical methods such as chemical precipitation, evaporation, ion exchange and reverse Osmosis (Ikhuoria and Omonmhenle, 2006). However, these conventional technologies appear to be inadequate and expensive over the years, adsorption have been shown to be an economically feasible alternative method for removing metal ions (Uzun and Guzel, 2000; Qader and Akhtar, 2005; Onundi et al, 2010, Okoye et al, 2010). The major advantages of an adsorption system for water pollution control are less investment in terms of initial cost and land, simple design and easy operation and no effect of toxic substances compared to conventional biological treatment processes (Markovska et al, 2006)

Agricultural by-products have been used as adsorbents in research work for removal of heavy metals from industrial effluents or other sources. This is due to the toxic effects of heavy metals and disadvantages of conventional methods of removal (Eze et al, 2013). Activated carbon has been used as adsorbent for removal of heavy metal pollutants from wastewater and has proved to be effective (Guen, et al., 2007; Goyal et al., 2008). This is due to its good adsorption properties which depend on its well developed porous structure and large active surface area (Kang et al., 2008) also it can be produced from cheap and locally available materials (Ochonogor and Ejikeme, 2005; Ejikeme and Ochonogor, 2008; Mahvi., 2008; Okpareke et al., 2009). The ability of activated carbon from Fluted Pumpkin seed shells (Telifairia Occidentalis) to remove lead from paint effluent is investigated in the work in the laboratory. Batch adsorption experiments and Adsorption Isotherm modeling were also carried out in the study.

MATERIALS AND METHOD

=

. (1)

MATERIALS

1+

Preparation of activated carbon

The fluted pumpkin seed was collected from New market

The linear form of the isotherm is given as:

Enugu, Nigeria. The shell was separation and was dried for

CAe = 1

CAe

.. (2)

6 days under the sun light to reduce the moisture content of the seed shells. After this, it was collected and stored in a glass jar until use. The dried fluted pumpkin seed shells were crushed to desired mesh size of 1-2mm and then carbonized at 8000C for 2hrs in a stainless steel vertical tubular reactor placed in a tube furnace. The char produced was crushed and sieved with 6OOnm sieve size. The char was soaked in 9M KOH solution with (1:1.5) char to KOH ratio. The mixture was then dehydrated in an oven at 1050C to remove moisture and then was activated under the same condition as carbonization, but to a different final temperature of 8500C for 1hrs. The activated product was then cooled to room temperature and washed with hot deionized water and 0.1 NHCL until PH of washing solution reached 6.4. The preparation of the adsorbent was in accordance of the method used by (Tan et al; 2008) with slight modification.

Adsorbate

4 litres of effluent (waste water) was supplied by Buxtin Paint Ltd Uwani Enugu, Nigeria.

SORPTION EXPERIMENT

BATCH ADSORPTION STUDIES

Experiments/ Study on PH, Dosage, Time and Temperature. To study the effect of PH on adsorption of lead on fluted pumpkin seed shell activated carbon, the experiments were carried out in five different batches. The first batch was at constant temperature of 300C, dosage of 0.1g and time of 20mins. Also at initial PH values of 2,4,6,8 and 10. The second, third, fourth and fifth batches were at different temperatures of 400C, 500C, 600C, 700C, dosage of 0.3g, 0.3g, 0.4g and 0.5g and time of 40mins, 60mins, 80mins, 100mins respectively, but at the same PH value as of the first batch. The PH values were adjusted with 0.1m HCl or using PH meter (Jenway model 3510, England), as centrifuged and the residues wastewater was analyzed using Atomic Absorption Spectrophotometer (AAS). All measurement was made at 661nm, a wave length corresponding to the maximum absorbance.

ISOTHERM STUDIES

Langmuir Isotherm

The Langmuir adsorption isotherm describes quantitatively the buildup of a layer of molecules on an adsorbent surface as a function of the concentration of the adsorbed material in the liquid in which it is in contact (Naseen rauf et al, 2012). This isotherm is based on the assumption that the adsorption process takes place at specific homogenous sites within the adsorbent surface and that once a dye molecule occupies a site, no further adsorption can take place at that site which concluded that the adsorption process is monolayer in nature (Ghaedi et al , 2012). The isotherm can be written as:

qe qoKL +

q

q

o

Where qe is the amount of adsorbate adsorbed per gram of the adsorbent (mg/g), CAe is the concentration of adsorbate in liquid equilibrium, (mg/l). The constant KL and qo relate to energy of adsorption and maximum adsorption capacity respectively. KL is a measure of heat of adsorption utilized to calculate dimensionless separation parameter RL, qo is in mg/g.

To determine if the adsorption process is favorable or unfavorable, for the Langmuir type adsorption process, the isotherm shape can be classified by a term RL a dimensionless constant separation factor which is defined as below (Malkoc and Nuhoglu., 2007).

= 1 .(3)

(1+ )

o

o

L

L

Where KL (L/mg) is the Langmuir constant and Cao is the lowest initial solute concentration (mg/l). a plot of Cao / qe versus CAe from the linear relationship of the model will give 1(q K ) and 1/qo as intercept and slope respectively.

Freundlich Isotherm

The Freundlich Isotherm equation is based on the assumption that the adsorbent has a heterogeneous surface composed of different classes of adsorption site (Marsal et al., 2012). This isotherm does not predict any saturation of the sorbent by the sorbate, indicating multilayer sorption of the surfaces (Donat et al, 2005). The freundlich isotherm is expressed by the following equation.

= (4)

A linear form of the freundlich can be obtained by taking the logarithm to the above equation.

log = + 1 .. (5)

Where KF = freundlich constant. Where KF (mg/g) is the constant related to the adsorption capacity. The value of 1/n ranging between 0 and 1 is a measure of adsorption intensity or surface heterogeneity, becoming more heterogeneous as its value gets closer to zero (Zeynep et al.,2007). A plot of Logqe versus CAe will give intercept as LogKF and slope as 1/n.

Temkin Isotherm Model

The heat of the adsorption and the adsorbate adsorbate interactions in a adsorption process were studied by

14

Lead

Mg/L

0.148

15

Chloride

Mg/L

21.3

16

Sulphate

Mg/L

24.6

17

COD

Mg/L

12.4

18

DO

Mg/L

19.7

19

BOD

Mg/L

143.7

20

Phosphorus

Mg/L

0.029

21

Aluminum

Mg/L

Nil

14

Lead

Mg/L

0.148

15

Chloride

Mg/L

21.3

16

Sulphate

Mg/L

24.6

17

COD

Mg/L

12.4

18

DO

Mg/L

19.7

19

BOD

Mg/L

143.7

20

Phosphorus

Mg/L

0.029

21

Aluminum

Mg/L

Nil

Temkin and Pyzhev (Temkin et al; 1940), and its equation is given as follows:

= +

= (/) (6)

Where T is the absolute temperature in K and R is the universal gas constant 8.3143J/molk. The constant b is related to the heat of adsorption qe(mg/g) and Ce(mg/l) and the equilibrium concentration respectively. A and B are constants related to adsorption capacity and intensity of adsorption. A plot of qe versus Ince yields a slope of B and intercept of BlnA.

Dubinin Raduschkevich (D R)

Dubinin Radushkevich model is similar to the Langmuir model but does not assume a homogenous surface or constant energy potential (Marsal et al., 2012). The D R equation can be written as:

= exp(2) (7) Where is the Polanyi potential (J/mol) given by: =

(1 + 1/)2 . (8)

Linearizing it gives

= 2 (1 + 1/).. (9) Where qe is the amount of sorbate adsorbed at equilibrium (mg/g), qmax is the theoretical saturation capacity (mg/g), BD is a constant related to the adsorption capacity (mg2/l2). A plot of Lng versus (RTLn(1 + 1/Ce) yields a straight line with a slope of -2BD and intercept of Lnqmax. The value of BD can be used to calculate the sorption mean free energy E (KJ/Mol).

= (2)-1/2 . (10)

Taking the logarithm of the D R equation, it becomes

= 2 (11) A plot of Lnqe against gives slope of -2BD and intercept of Lnqmax.

The analysis was performed physically to ascertain its temperature, odour, conductivity, PH and Turbidity. Also chemically to determine its acidity, alkalinity, total solid, dissolved solid, suspension solid, BOD, COD, DO and presence of some metals such as Cu2+, Fe2+, Zn2+, Pb2+, Cl-, sulphate, phosphorus and aluminum.

APPARATUS AND EQUIPMENTS USED ARE AS FOLLOWS:

conical flasks, beakers, PH meter, weighing balance, crucible, electric shaker, sintered glass crucible, platinum crucible, muffle furnance, desiccators, graduated cylinders, thermometer, filter paper, Atomic Absorption Spectrophotometer, pipette, volumetric flask, shaker incubator, UV Visible spectrophotometer.

Table 2: Characterization of fluted pumpkin seed shells

RESULTS AND DISCUSSION

S/N

Parameter Physical Analysis

Unit

Waste water

1

Temperature

0C

30.4

2

Odour

3

Conductivity

Ns/Cm3

468

4

PH

6.01

5

Turbidity

NuT

18.01

6

Acidity

Mg/L

Nil

7

Alkalinity

Mg/L

20

8

Total solid

Mg/L

0.5

9

Dissolved solid

Mg/L

0.2

10

Suspended solid

Mg/L

0.3

11

Copper

Mg/L

0.40

12

Iron

Mg/L

0.15

13

Zinc

Mg/L

Nil

0.2

S/N

Parameter Physical Analysis

Unit

Waste water

1

Temperature

0C

30.4

2

Odour

3

Conductivity

Ns/Cm3

468

4

PH

6.01

5

Turbidity

NuT

18.01

6

Acidity

Mg/L

Nil

7

Alkalinity

Mg/L

20

8

Total solid

Mg/L

0.5

9

Dissolved solid

Mg/L

10

Suspended solid

Mg/L

0.3

11

Copper

Mg/L

0.40

12

Iron

Mg/L

0.15

13

Zinc

Mg/L

Nil

Table 1: ANALYSIS OF PAINT EFFLUENT

S/N

Parameter

Unit

Raw fluted pumpkin seed shells

Activated fluted pumpkin seed shells

1

Bulk Density

g/ml

0.28

0.48

2

Ash Content

%

4.0

2.0

3

Moisture Content

8.1

6.6

4

Iodine Number

Gl2/100g

290.4

411.4

5

PH

6.4

6.4

6

Tapped Density

g/ml

0.32

0.52

7

Volatile matter

%

48.9

28.0

8

Fixed carbon

%

39.0

63.4

S/N

Parameter

Unit

Raw fluted pumpkin seed shells

Activated fluted pumpkin seed shells

1

Bulk Density

g/ml

0.28

0.48

2

Ash Content

%

4.0

2.0

3

Moisture Content

8.1

6.6

4

Iodine Number

Gl2/100g

290.4

411.4

5

PH

6.4

6.4

6

Tapped Density

g/ml

0.32

0.52

7

Volatile matter

%

48.9

28.0

8

Fixed carbon

%

39.0

63.4

The fluted pumpkin seed shells were characterized based on its raw state and after activation.

Apparatus and Equipments used are as follows:

Stainless steel vertical tabular reactor, tube furnance, crusher, sieves and weighing balance

EFFECT OF PROCESS VARIABLES ON ADSORPTION

Effect of Dosage

Figure1 shows the effect of dosage of the adsorbent used on the adsorption of lead from paint effluent.

100

80

60

40

20

0

PH of2, 20mins, 30oC

PH of 4, 40mins, 40oC PH of 6, 60mins, 50oC PH of 8, 80mins, 60oC

Phof 10, 100mins, 70oC

100

80

60

40

20

0

PH of2, 20mins, 30oC

PH of 4, 40mins, 40oC PH of 6, 60mins, 50oC PH of 8, 80mins, 60oC

Phof 10, 100mins, 70oC

0.1 0.2 0.3 0.4 0.5

DOSAGE (g)

0.1 0.2 0.3 0.4 0.5

DOSAGE (g)

PERCENTAGE LEAD REMOVAL (%)

PERCENTAGE LEAD REMOVAL (%)

Figure 1 Effect of dosage on percentage removal of lead

From the figure 1, it can be seen that the percentage quantity of lead adsorbed increases linearly with increase in adsorbent dosage. This is as a result of the fact that the quantity of sites for adsorption increases with increase in adsorbent weight (Dahya et al, 2008) similar result was observed by Dave et al 2009) for the adsorption of Cu2+ on commercial activated carbon.

Also, the quantity of lead adsorbed per gram of adsorbent increases with increase in the dosage of the adsorbent used. This is as a result of the fact that the adsorbate ions concentration was constant at all the site available for adsorption on the adsorbent. At the dosage of 0.5g, the highest degree of adsorption was recorded and the lowest degree was recorded at dosage of 0.1g.

Effect of PH

Figure 2 shows the effect of PH of the paint effluent on the adsorption of lead by the activated carbon of fluted pumpkin seed shells.

PERCENTAGE LEAD REMOVAL (%)

PERCENTAGE LEAD REMOVAL (%)

100

80

    1. g, 20mins, 30oC

      60

    2. g, 40mins, 40oC

Significant reduction in removal efficiency was observed for further increase in PH. This may be attributed to the fact that at low PH (1-3), the metal ions (Pb2+) had to compete with H+ ions for adsorption site on the adsorbent surface. As the PH increased, this competition weakened and more metal ions were able to replace H+ ions bound to the adsorbent surface (Ibrahim et al, 2006).

Lead considered in this study has pka value of 8. When the PH of a solution goes beyond the pka, lead chiefly exists as a negative ion and as neutral molecules below pka. Therefore at high PH value greater than 6, for fluted pumpkin activated carbon, the H+ ions becomes more competitive to Pb ion for sorption site. The H+ ions could populate the surface resulting in repulsion of lead ions and thereby causing decreased adsorption.

Therefore, from the experimental results, PH 6 was selected as an optimum PH.

Effect of Time

100

80

60

40

20

0

100

80

60

40

20

0

PH 0f 2, 0.1g, 30oC

PH 0f 2, 0.1g, 30oC

PH of 4, 0.2g, 40oC

PH of 6, 0.3g, 50oC PH of 8, 0.4g, 60oC PH of 10, 0.5g, 70oC

20

PH of 4, 0.2g, 40oC

PH of 6, 0.3g, 50oC PH of 8, 0.4g, 60oC PH of 10, 0.5g, 70oC

20

PERCENTAGE LEAD REMOVAL (%)

PERCENTAGE LEAD REMOVAL (%)

Figure 3 show the effect of contact time on the adsorption of lead (Pb2+) from the waste water.

TIME (mins)

TIME (mins)

40

40

60

60

80

80

100

100

Figure 3 Effect of Time on percentage removal of Lead

In figure 3, there was an initial rapid sorption for about 20 minutes of agitation. After this, the rate of sorption became slower. After 75-85 minutes of agitation, equilibrium was

40

20

0

2 4 6 8 10

PH VALUES

0,3g, 60mins, 50oC

0.4g, 80mins, 60oC 0.5g, 100mins, 70oC

attained. This can be explained by the fact that within the first 20 minutes, the adsorbent still had a vast, number of unoccupied sites unto which the Pb2+ adsorbate could adsorb. As a result, there was a high probability of adsorption for every diffusing molecule of the adsorbate. The lead absorbed within the first 20 minutes lead to a decrease in number of unoccupied sites, this made the

Figure 2 Effect of PH on percentage removal of Lead

The initial PH of an adsorption medium is one of the most important parameters affecting the adsorption process. The effect of PH on the adsorption of lead was studied varying the PH from 2 to 10 shown in figure 2. It was observed that the amount of lead adsorbed occurred at PH 6 for fluted pumpkin seed shells activated carbon.

adsorption to become slower since adsorbent surface was approaching, saturation. After 85 to 100 minutes, the adsorbent sites were completely occupied by the adsorbate particles. At this stage, the system attained equilibrium at which the rate of adsorption becomes equal to rate of desorption.

Effect of Temperature

Figure 4 shows the effect of adsorption temperature on the adsorption of lead by the activated carbon.

TEMPERATURE (oC)

TEMPERATURE (oC)

120

100

80

60

40

20

0

120

100

80

60

40

20

0

PH of2, 20mins, 0.1g

PH of2, 20mins, 0.1g

PH of 4, 40mins, 0.2g

PH of 6, 60mins, 0.3g PH of 8, 80mins, 0.4g PH of 10, 100mins, 0.5g

30 40

PH of 4, 40mins, 0.2g

PH of 6, 60mins, 0.3g PH of 8, 80mins, 0.4g PH of 10, 100mins, 0.5g

30 40

50

50

60 70

60 70

0

0

-4

-4

-3

-3

-2

-2

-1

-1

0

0

-0.5

y = -0.4155x – 1.918 -1

R² = 0.94

y = -0.3264x – 2.4391

-0.5

y = -0.4155x – 1.918 -1

R² = 0.94

y = -0.3264x – 2.4391

303K

313k

323k

303K

313k

323k

-1.5

-1.5

-2

-2

333k

343k

333k

343k

PERCENTAGE OF LEAD REMOVAL (%)

PERCENTAGE OF LEAD REMOVAL (%)

log qe

log qe

Figure 4 Effect of Temperature on percentage removal of Lead

From the results and figure 4, it is seen that the adsorption decreased as temperature increased. This is in agreement with the result obtained by (Teker et al, 1999). This decrease in adsorption capacity with increase in temperature indicates that the adsorption process were exothermic in nature as there is decrease in the number of microstates and decrease in the freedom of movement of molecules.

Because of this reason, the highest absorption of lead occurred at 300c with approximately 98% removal.

ISOTHERM STUDIES

3

3

y = 85.891x – 0.1024

y = 85.891x – 0.1024

R² = 0.9978

R² = 0.9974

R² = 0.9978

R² = 0.9974

303K

313K

323k

333k

343k

303K

313K

323k

333k

343k

ce/qe

ce/qe

The isotherm data obtained for the adsorption processes were analyzed using the Langmuir, Freundlich, Temkin and Dubinin Kadushkevich isotherms.

6

5

4

y = 123.63x – 1.0395

R² = 0.9921 y = 106.44x – 0.5365

R² = 0.9951 y = 93.665x – 0.2481

6

5

4

y = 123.63x – 1.0395

R² = 0.9921 y = 106.44x – 0.5365

R² = 0.9951 y = 93.665x – 0.2481

0.02

0.04

0.06

0.02

0.04

0.06

ce

ce

2

1

0

-1 0

2

1

0

-1 0

y = 67.091x – 0.1323

R² = 0.5575

y = 67.091x – 0.1323

R² = 0.5575

Figure 5, Langmuir isotherm plot for Lead Adsorption of FPSS activated carbon

R² = 0.9687

log ce

R² = 0.9687

log ce

R² = 0.9702

y = -0.0791x – 2.035 R² = 0.8663

y = -0.1585x – 2.1738

y = -0.2333x – 2.2979 R² = 0.9715

R² = 0.9702

y = -0.0791x – 2.035 R² = 0.8663

y = -0.1585x – 2.1738

y = -0.2333x – 2.2979 R² = 0.9715

-2.5

-2.5

y = –

y = –

y = -0.0028x + 0.0017

R² = 0.9767

0.0453x – 0.1492

R² = 0.4584

y = -0.0028x + 0.0017

R² = 0.9767

0.0453x – 0.1492

R² = 0.4584

0.18

0.16

0.14

0.12

0.1

0.08

0.06

0.04

0.02

0

0.18

0.16

0.14

0.12

0.1

0.08

0.06

0.04

0.02

0

303K

313K

323k

333k

343k

303K

313K

323k

333k

343k

qe

qe

Figure 6, Freundlich Isotherm plot for Lead Adsorption on FPSS activated carbon

y = -0.001x + 0.0085

R² = 0.8746

y = -0.001x + 0.0085

R² = 0.8746

-8

-8

y = -0.0022yx =+ -00..0000323x + 0.0045

R² =-06.9371R² = l0n-.94c7e73 -2

y = -0.0022yx =+ -00..0000323x + 0.0045

R² =-06.9371R² = l0n-.94c7e73 -2

0

0

-1

y = 0.0001x – 5.5731

-2 R² = 0.6738

y = 6E-05x – 5.0318 y = 9E-05x – 5.3182

-1

y = 0.0001x – 5.5731

-2 R² = 0.6738

y = 6E-05x – 5.0318 y = 9E-05x – 5.3182

R² = 0.9699

y = -0.0004x + 0.0092 R² = 0.9926

y = 6E-05x – 4.9381

R² = 0.7463

RTln(1+1/Ce)

R² = 0.9699

y = -0.0004x + 0.0092 R² = 0.9926

y = 6E-05x – 4.9381

R² = 0.7463

RTln(1+1/Ce)

ln qe

ln qe

Figure 7, Temkin Isotherm plot for Lead Adsorption on FPSS activated carbon

0

0

0

5000

10000

15000

0

5000

10000

15000

303k

313k

323k

333k

-4 343k

303k

313k

323k

333k

-4 343k

-5

-5

-3

-3

R² = 0.9678

R² = 0.9678

Figure 8, Dubinin Radushkevich Isotherm plot for Lead Adsorption on FPSS Activated carbon

ISOTHER M MODEL

PARAMETERS

Langmuir

Temp (K)

qo(mglg)

KL(L/mg

)

RL

R2

Isotherm

303

0.0149

-0.0019

1.0

0.557

313

0.0116

-1.1832

1.0

0.997

323

0.0107

-0.0027

1.0

0.997

333

0.0094

-0.0050

1.0

0.995

343

0.0081

-0.0084

1.0

0.992

Freundlich

Temp (K)

1

n

KF

R2

Isotherm

303

-0.415

-2.41

0.012

0.940

313

-0.079

-2.66

0.009

0.866

323

-0.158

-6.34

0.007

0.971

333

-0.233

-4.29

0.005

0.968

343

-0.326

-3.07

0.004

0.970

Temkin Isotherm

Temp (k)

B

A

b

R2

303

-0.045

27.41

-55.98

0.458

313

-0.001

0.00

– 2602.3

0.874

323

-0.002

0.14

– 1342,1

11

0.977

333

-0.002

0.61

– 138438

1

0.976

343

-0.002

0.22

– 1425,8

51

0.937

Dubinin Radushkev ich Isothern

Temp(k)

Q1

(mg/g)

BD

E

(kJ/mol)

R2

303

1.00

0.005

0.00

0.992

313

1.04

2.469

0.45

0.746

323

1.04

2.516

0.46

0.969

333

1.06

2.149

0.48

0.967

343

1.00

2.787

0.42

0.673

ISOTHER M MODEL

PARAMETERS

Langmuir

Temp (K)

qo(mglg)

KL(L/mg

)

RL

R2

Isotherm

303

0.0149

-0.0019

1.0

0.557

313

0.0116

-1.1832

1.0

0.997

323

0.0107

-0.0027

1.0

0.997

333

0.0094

-0.0050

1.0

0.995

343

0.0081

-0.0084

1.0

0.992

Freundlich

Temp (K)

1

n

KF

R2

Isotherm

303

-0.415

-2.41

0.012

0.940

313

-0.079

-2.66

0.009

0.866

323

-0.158

-6.34

0.007

0.971

333

-0.233

-4.29

0.005

0.968

343

-0.326

-3.07

0.004

0.970

Temkin Isotherm

Temp (k)

B

A

b

R2

303

-0.045

27.41

-55.98

0.458

313

-0.001

0.00

– 2602.3

0.874

323

-0.002

0.14

– 1342,1

11

0.977

333

-0.002

0.61

– 138438

1

0.976

343

-0.002

0.22

– 1425,8

51

0.937

Dubinin Radushkev ich Isothern

Temp(k)

Q1

(mg/g)

BD

E

(kJ/mol)

R2

303

1.00

0.005

0.00

0.992

313

1.04

2.469

0.45

0.746

323

1.04

2.516

0.46

0.969

333

1.06

2.149

0.48

0.967

343

1.00

2.787

0.42

0.673

Table 3: Isotherm Parameters for lead Adsorption on fluted pumpkin seed shells activated carbon.

Langmuir Isotherm

The value of a dimensionless separation factor, RL, indicates the type of the isotherm to be either unfavourble

if (RL > 1, linear (RL = 1), favourable (O Rl <1) or

Freundlich Isotherm

The values of freundlich constants and correlation coefficients (R2) are given in table 3 The value of Kf and n changed with the rise in temperature. The values on n less than 1, did not strongly favour the nature of the adsorbent. The correlation coefficient which ranges from 0.866 to 0.971 shows that the data fit well with Freundlich equation at temperature of 323k where R2 0.971 is closer to unity.

The Freundlich constant n indicates the degree of favourablility and should lie in the range 1-10 to be classified as favourable adsorption (Rao et al 2001; Raji et al, 1997). This work was not in line with the work done by (Okoye et al, 2010).

Temkin Isotherm

The Temkin isotherm constants and coefficients of determination are presented in table 3. This shows that the equilibrium binding constant; A (L/mg), corresponds to the maximum binding energy. This energy was maximum at PH of 2. The constant b which relates to heat of adsorption, increased with increase in temperature. The correlation coefficient R2, 0.977 at temperature of 323 fitted well with Temkin isotherm model.

Dubinin Radushkevich Isotherm

The Dubinin-Radushkevich Isotherm gives information about the chemical or physical properties of the sorption which mean free energy, E (Naseenrauf et al, 2012). The values of the mean adsorption energy that is less than 8 kglmol, indicates that the adsorption of lead was more a physical process rather than a chemical process (Marsal et al, 2012; Chen et al, 2009).

The correlation coefficient R2 if the isotherm in table 3 shows that Dubinin Radushkevich equation was well fitted. The R.D was fitted well at temperature of 303k where its R2 is 0.992. This work was in agreement with the work done by (Ejikeme, 2010).

CONCLUSION

The result obtained from this work shows the possibility of production of activated carbon with good properties from fluted pumpkin seed shells. Adsorption decreased with

irreversible (RL = 0). The plot of

versus Ce indicated

increase in adsorption temperature and increased with

increase in dosage and time in all the cases considered.

the application of Langmuir adsorption isotherm Langmuir constants q0 and K1 which were calculated from the slopes and intercepts are given in table 3 along with the correlation coefficient (R2) and separation factor (RL). The average value of Rl for each of the temperature and PH used were 1.0, which indicates a linear adsorption of lead. This was not in agreement with the work done by (Emad et al, 2006). However, the correlation coefficient R2 which is highest at temperatures of 313k and 323k (0.997) respectively indicates that it fitted well with the model.

Adsorption also increased with increase in PH of the waste water up to PH of 6, beyond which metal ions were precipitated out of their solutions. The kinetic model was best described using first order equation as it has the best R2 values. The isotherm analysis showed that the adsorption process of Langmuir, isotherm fitted better than other studies.

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