CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim
Copyright © 2017, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-47-1; ISSN 2283-9216

Evaluation of the Effectiveness of Low Cost Adsorbents from 
Oil Palm Wastes for Wastewater Treatment 

Xin Jiat Lee, Billie Yan Zhang Hiew, Lai Yee Lee*, Suyin Gan, Suchithra 
Thangalazhy-Gopakumar 

Department of Chemical and Environmental Engineering, Faculty of Engineering, University of Nottingham Malaysia 
Campus, Jalan Broga, 43500 Semenyih, Selangor, Malaysia  
laiyee-lee@nottingham.edu.my 

In the present research, oil palm wastes such as palm kernel shell (PKS), empty fruit bunch (EFB) and palm 
oil sludge (POS) were converted into biochars through pyrolysis. The charred products of PKS (CPKS), EFB 
(CEFB) and POS (CPOS) were tested for batch adsorption of copper (Cu2+), lead (Pb2+) and cadmium (Cd2+). 
Their adsorption performances were compared with the respective un-charred form, i.e. the biosorbents. The 
adsorption equilibrium was evaluated by varying initial metal concentration. Experimental data were analysed 
by Langmuir, Freundlich, Temkin and Dubinin-Radushkevich models. It was found that for Cu2+ removal by 
POS and Pb2+ removal by CPOS, the equilibria were best represented by Langmuir model exhibiting the 
smallest sum of normalised error (SNE). For Cd2+ adsorption onto POS, the equilibrium was best fitted by 
Freundlich model with the lowest value of SNE.  

1. Introduction
Rapid industrialisation in Malaysia has caused greater heavy metal contamination of the aquatic environment. 
Heavy metals have always been one of the most significant pollutant groups in wastewater due to their non-
biodegradability and high toxicity characteristics. The main sources of heavy metal pollution in the water 
environment are anthropogenic activities such as electroplating, electronics and semiconductor sectors, 
agricultural activities, shipping activities and mining industry (Shazili et al., 2006). Heavy metals such as Cu2+, 
Pb2+, Cd2+, zinc (Zn2+) and nickel (Ni2+), are often discharged at level exceeding the allowable discharge 
standard (Alkarkhi et al., 2008). These harmful metal ions are highly soluble which make them easily absorbed 
by living organisms. Contact with these heavy metals can bring about various adverse health effects such as 
liver damage, kidney damage, dermatitis and cancer (Chowdhury et al., 2016).   
To date, numerous techniques are available for treatment of wastewater contaminated by heavy metals which 
include chemical precipitation, coagulation, membrane filtration and ion-exchange. These treatment methods 
are associated with drawbacks such as high capital and operational costs, low efficiencies and generation of 
secondary sludge (Lam et al., 2016). Adsorption technique provides a better alternative for heavy metals 
removal as it is easier to operate, cost-effective and the spent adsorbent can be regenerated for re-use (Fu et 
al., 2011). Due to its technological flexibility, numerous adsorbing materials have been tested for their heavy 
metals removal efficiencies, such as Pequi fruit skin (Seolatto et al., 2012), Salvinia Natans (Lima et al., 2014), 
and spent coffee grounds (Lavecchia et al., 2016).  
In Malaysia, the oil palm species found in the plantation are mainly Elaeis guineensis, which are also known 
for their high yield of palm oil. Despite being one of the most lucrative industries in Malaysia, palm oil industry 
generates large amount of solid and liquid wastes which are difficult to dispose of. For every 1 kg of crude 
palm oil produced, approximately 4 kg of waste materials are generated (Sulaiman et al., 2011). Of the oil 
palm residues, palm kernel shell (PKS), empty fruit bunch (EFB) and palm oil sludge (POS) are among the 
most cumbersome wastes to be handled. These materials are wastes in industrial scale which contain 
lignocellulosic materials, making them excellent precursors for biosorbent and biochar synthesis. While oil 
palm wastes may be used as biosorbent, their conversion to biochars can be beneficial in terms of increased 
total surface area and extended storage lifespan. Data on comparison of adsorption performance of oil palm 

 

   

DOI: 10.3303/CET1756157

 
 
 
 

 
 
 
 
 
 
 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Lee X.J., Lee L.Y., Hiew B.Y.Z., Gan S., Thangalazhy-Gopakumar S., 2017, Evaluation of the effectiveness of low 
cost adsorbents from oil palm wastes for wastewater treatment, Chemical Engineering Transactions, 56, 937-942  DOI:10.3303/CET1756157   

937



waste biosorbents with that of their charred forms are scarce in the literature. This research work explores the 
potential of converting oil palm wastes into value added products, such as biosorbents and biochars, for 
application in wastewater treatment. The adsorption equilibrium of the oil palm waste-based biosorbent was 
compared with that of the biochar. The main focus of this study was to establish the biosorption model for 
removal of heavy metal in industrial wastewater.  

2. Methodology 
2.1 Biosorbents and biochars preparation  

Oil palm wastes of PKS, EFB and POS were collected from Seri Ulu Langat Palm Oil Mill Sdn. Bhd., Dengkil, 
Selangor, Malaysia. All collected materials were washed with distilled water and dried in an oven (Memmert) 
for 72 h at 80 °C. They were then cut into smaller pieces using a sieve grinder (Retsch) and sieved to obtain 
particles with sizes ranging from 0.5 – 2 mm. The dried PKS, EFB and POS particles were pyrolysed for 1 h 
under nitrogen atmosphere. The three charred products were thereafter denoted as charred PKS (CPKS), 
charred EFB (CEFB) and charred POS (CPOS). Proximate analysis was performed using thermogravimetric 
analyser (TGA, Mettler Toledo). To evaluate the adsorption potential, the prepared adsorbents were tested on 
removal of Cu2+, Pb2+ and Cd2+ in aqueous solution. A series of Erlenmeyer flasks containing 50 mL of heavy 
metal solutions of different concentrations (10 - 300 mg/L) were contacted with 0.5 g of adsorbent. The 
solutions were shaken in a waterbath shaker (Protech) for 4 h at 100 rpm and 30 °C. Thereafter, the solution 
was filtered and the final concentration was determined by atomic absorption spectrophotometer (Perkin-
Elmer AA400). The percentage removal (R, %) and adsorption capacity (qe, mg/g) were determined by Eq(1) 
and Eq(2),  

R	 % 	=	C − CC x 100 %  (1) 
q 	=	 C − C VW   (2) 

where C0 and Ce (mg/L) are the initial and final concentrations, V (L) is the solution volume and W (g) is the 
adsorbent mass. Experimental adsorption data were fitted to adsorption isotherm models such as Langmuir, 
Freundlich, Temkin and Dubinin-Radushkevich (D-R) models (Table 1). Langmuir model assumes monolayer 
sorption occurring on homogenous sites (Langmuir, 1918). The favourability of adsorption can be assessed by 
Hall separation factor, RL (dimensionless) (Hall et al., 1966) whereby the process is irreversible if RL = 0, 
favourable if 0 < RL < 1, linear if RL = 1 and unfavourable if RL > 1. Freundlich model considers the adsorption 
energy reduces exponentially with increase in surface coverage of the adsorbent (Freundlich, 1906). Temkin 
model assumes that the adsorption energy reduces linearly with an increase in degree of completion of sites 
(Temkin and Pyzhev, 1940). D-R model assumes adsorption occurs on heterogeneous solid surface (Dubinin 
et al., 1947). The model parameters were determined by non-linear regression using Microsoft Excel Solver 
based on the error functions listed in Table 1. The criteria for selecting the optimum model parameters was 
based on smallest SNE value (Lee et al., 2015). 

3. Results and discussion  
The thermal stability of PKS, EFB and POS was evaluated by TGA, in which the samples were heated at 5 
°C/min. Figure 1 shows the TGA plots for PKS, EFB and POS. The stages of mass loss were in the following 
order: moisture removal (25 – 110 °C) and devolatilisation (110 – 800 °C) under a nitrogen purge (50 mL/min), 
as well as combustion (800 – 900 °C) under oxidative condition. The final remaining mass was the ash 
content. PKS, EFB and POS had moisture contents of 4.53, 3.47 and 5.67 %, respectively. Among the three 
samples, EFB contained the highest volatile compounds (72.88 %) compared to PKS and POS. PKS was 
found to be the more promising precursor for biochar as its fixed carbon content (24.91 %) was the highest, 
followed by EFB and POS.  
Figure 2 depicts the effect of initial metal concentration on adsorption capacities of Cu2+, Pb2+ and Cd2+ onto 
the different biosorbents and biochars. As the initial concentration was increased, the adsorption capacities for 
heavy metals were increased. This was because at higher heavy metal concentration, a stronger 
concentration gradient would be formed which could overcome the mass transfer resistance between the solid 
and liquid phases during adsorption. Adsorbents such as PKS, EFB, CPKS and CEFB reached a plateau at 
the lower range of initial concentrations and further increment of initial concentration showed no improvement 
on their adsorption capacities. This trend indicated that the adsorbents might have limited sorption sites.  

938



Table 1:  Equilibrium isotherm and error functions. 

Model/ Error Function  Equation Reference 
Langmuir 

1
m L e

e

L e

q K C
q

K C
=

+
 (Langmuir, 1918) 

Hall separation factor =
+ 0

1

1
L

L

R
K C

 (Hall et al., 1966) 

Freundlich 
=

1

n
e F eq K C  

(Freundlich, 1906) 

Temkin loge e
RT

q AC
B

=  (Temkin et al., 1940) 

Dubinin-Radushkevich βε= − 2exp( )e DRq q (Dubinin et al., 1947) 

Marquardt’s percent standard 
deviation (MPSD) 

=

 −
  −  


2

,exp ,

,exp1

1
100

N
e e cal

s ei

q q

n p q
 

(Marquardt,1963) 

Chi-square (χ2) 

=

−


2
,exp ,

,1

( )N e e cal

e cali

q q

q
 (Ho, 2004) 

Average relative error (ARE) 

=

−
 ,exp ,

,exp1

100
N

e e cal

S ei

q q

n q
 (Ng et al., 2003) 

Sum of absolute errors (EABS) 

=

− ,exp ,
1

N

e e cal

i i

q q  
(Ho et al., 2002) 

Sum of the squares of the errors 
(ERRSQ) ( )

=

−
2

,exp ,

1

N

e e cal

i i

q q  
(Ho et al., 2002) 

Residual root mean square error 
(RSME) ( )

=

−
− 

2

,exp ,

1

1

2

N

e e cal

s i

q q
n

 
(Hadi et al., 2010) 

Nomenclature: qm (mg/g) – Langmuir maximum adsorption capacity, KL (L/mg) – Langmuir binding energy, KF 
((mg/g)(L/mg)1/n) – Freundlich constant, n (dimensionless) – Freundlich exponent, A (L/mg) – maximum 
binding energy, B (J/mol) – Temkin constant related to the variation of adsorption heat, R (8.314 J/mol K) – 
universal gas constant, T (K) – absolute temperature, qDR (mg/g) – D-R maximum adsorption capacity, β 
(g2/J2) – activity coefficient related to adsorption energy, ε (= RT/M log (1+1/Ce), J/g) – Polanyi potential, M 
(g/mol) – adsorbate molar weight, qe,exp (mg/g) – experimental equilibrium adsorption capacities, qe,cal (mg/g) – 
calculated equilibrium adsorption capacities based on isotherm models, ns – number of data and p – number 
of isotherm parameters. 
 
The adsorption isotherms, both experimentally and theoretically derived, are plotted in Figure 3. From the 
plots, the adsorption capacity of the adsorbents was evaluated. It was found that most biochars exhibited 
lower adsorption capacities when compared to their un-charred form. This suggests that pyrolysing the raw 
biomasses has not improved the adsorption performances for the heavy metals assayed. The reduction in 
adsorption performance of the biochars might be due to elimination of some chemical functional groups 
present in the raw biomasses. It is known that chemical functional groups play an important role in binding 
heavy metals. POS showed the highest adsorption capacities for Cu

2+ (14 mg/g) and Cd2+ (25 mg/g). Among 
the three biochars, CPOS showed the highest adsorption capacity for Pb2+ (19 mg/g). With regard to the 
isotherm curves, most of the heavy metal adsorptions onto the biosorbents and biochars exhibited a convex 
trend, indicating that their adsorption processes were favourable. The adsorption of Pb2+ onto POS was 
unfavourable as indicated by its concave upward isotherm (McCabe et al., 2005). The adsorption of Pb2+ onto 
CPOS exhibited a convex curve and hence pyrolysis has improved the adsorption favourability of Pb2+ on 
CPOS. These sludge-based adsorbents showed promising results in heavy metals removal. To further assess 
the maximum adsorption capacity, the experimental data of Cu2+ adsorption onto POS, Pb2+ onto CPOS and 
Cd2+ onto POS were fitted with equilibrium isotherms such as Langmuir, Freundlich, Temkin and D-R models. 
As can be seen in Table 2, the adsorption of Cu2+ onto POS and Pb2+ onto CPOS were well-represented by 
Langmuir model because of their SNE smallest values. This indicates that uptake of the heavy metals is likely 
to be governed by monolayer adsorption onto POS and CPOS. Their qm values were in close proximity with 

939



the experimental values along with the RL values which were within the region of adsorption favourability. The 
adsorption of Cd2+ by POS was however best correlated with Freundlich model with the smallest SNE, KF of 
2.826 (mg/g)(L/mg)1/n and n of 2.226 which was greater than unity. This implied that Cd2+ was favourably 
adsorbed onto the surface of POS.  
 

 

Figure 1: Thermogravimetric plot of PKS (solid line), EFB (dash line) and POS (round dot line).  

 

 

 

 
Figure 2: The effect of initial concentration on the adsorption capacities of (a) Cu2+, (b) Pb2+ and (c) Cd2+ onto 
different biosorbents, and of (d) Cu2+, (e) Pb2+ and (f) Cd2+ onto different biochars. 

0.00

2.00

4.00

6.00

8.00

10.00

12.00

14.00

16.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00 350.00

A
d

s
o

rp
ti
o

n
 C

a
p
a

c
it
y
 (

m
g

/g
)

Initial Concentration (mg/L)

PKS EFB POS

0.00

2.00

4.00

6.00

8.00

10.00

12.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00 350.00

A
d
s
o
rp

ti
o
n
 C

a
p
a
c
it
y
 (

m
g

/g
)

Initial Concentration (mg/L)

CPKS CEFB CPOS

0.00

5.00

10.00

15.00

20.00

25.00

30.00

35.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00 350.00

A
d
s
o
rp

ti
o
n
 C

a
p
a
c
it
y 

(m
g

/g
)

Initial Concentration (mg/L)

PKS EFB POS

0.00

5.00

10.00

15.00

20.00

25.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00 350.00

A
d
s
o
rp

ti
o
n
 C

a
p
a
c
it
y
 (

m
g

/g
)

Initial Concentration (mg/L)

CPKS CEFB CPOS

0.00

5.00

10.00

15.00

20.00

25.00

30.00

0 50 100 150 200 250 300 350

A
d
so

rp
tio

n
 C

a
p
a
ci

ty
 (

m
g
/g

)

Initial Concentration (mg/L)

PKS EFB POS

0.00

1.00

2.00

3.00

4.00

5.00

6.00

7.00

8.00

9.00

0 50 100 150 200 250 300 350

A
d
s
o

rp
ti
o
n

 C
a

p
a
c
it
y 

(m
g

/g
)

Initial Concentration (mg/L)

CPKS CEFB CPOS

0

10

20

30

40

50

60

70

80

90

100

0 200 400 600 800 1000

W
e
ig

h
t 
L
o
s
s
 (

%
)

Temperature (°C)

PKS

EFB

POS

1000 0 200 400 600 800 

(a) (b) 

(c) (d) 

(e) (f) 

940



 

 
 

 

 
Figure 3: The isotherm plots of (a) Cu2+, (b) Pb2+ and (c) Cd2+ adsorption onto different biosorbents, and of (d) 
Cu2+, (e) Pb2+ and (f) Cd2+ adsorption onto different biochars. 

Table 2: SNE analysis for Langmuir, Freundlich, Temkin and D-R models. 

Model Model parameters Adsorption Matrix 
Cu2+ on POS Pb2+ on CPOS Cd2+ on POS 

Langmuir qm (mg/g) 16.56 25.64 20.65 
 KL (L/mg) 0.0521 0.0441 0.1274 
 RL 0.0601 0.0703 0.0255 
 SNE 1.369 1.383 4.781 
Freundlich KF ((mg/g)(L/mg)

1/n) 1.457 1.747 2.826 
 N 2.064 1.811 2.226 
 SNE 9.308 7.512 2.027 
Temkin B (J/mol) 732.7 477.7 981.2 
 A (L/mg) 0.6199 0.5709 11.26 
 SNE 2.469 2.550 2.717 
D-R qDR (mg/g) 12.54 18.11 23.32 
 Β (g

2/J2) 0.0291 0.5030 0.2487 
 SNE 3.277 3.478 8.870 

0.00

2.00

4.00

6.00

8.00

10.00

12.00

14.00

16.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

PKS EFB POS

0.00

2.00

4.00

6.00

8.00

10.00

12.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

CPKS CEFB CPOS

0.00

2.00

4.00

6.00

8.00

10.00

12.00

14.00

16.00

18.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

PKS EFB POS

0.00

5.00

10.00

15.00

20.00

25.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

CPKS CEFB CPOS

0.00

5.00

10.00

15.00

20.00

25.00

30.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

PKS EFB POS

0.00

1.00

2.00

3.00

4.00

5.00

6.00

7.00

8.00

9.00

0.00 50.00 100.00 150.00 200.00 250.00 300.00

q
e

(m
g

/g
)

Ce (mg/L)

CPKS CEFB CPOS

(a) (b) 

(c) 
(d) 

(e) (f) 

941



4. Conclusions 
Pyrolysis of PKS, EFB and POS was successfully carried out. TGA results showed that PKS had high 
potential to be developed as biochars. The biosorbents and obtained biochars were tested on the removal of 
Cu2+, Pb2+ and Cd2+ in batch mode. The results indicated that Cu2+ and Cd2+ were best removed by POS while 
Pb2+ was best removed by CPOS. The equilibria of Cu2+ adsorption onto POS and Pb2+ onto CPOS were well 
represented by Langmuir model while the equilibrium of Cd2+ adsorption onto POS was well correlated to 
Freundlich model. 

Acknowledgements 

The authors gratefully acknowledge the financial support provided by Fundamental Research Grant Scheme 
(FRGS/1/2015/SG06/UNIM/02/1) and Faculty of Engineering, University of Nottingham Malaysia Campus. 

References  

Alkarkhi A.F.M., Ahmad A., Ismail N., Easa A.M., 2008, Multivariate analysis of heavy metals concentrations in 
river estuary, Environmental Monitoring and Assessment 143, 179-186. 

Chowdbury S., Mazumder M.A., A-Attas O., Husain T., 2016, Heavy metals in drinking water: Occurrences, 
implications, and future needs in developing countries, Science of the Total Environment 569-570, 476-
488. 

Dubinin M.M., Radushkevich L.V., 1947, The equation of the characteristic curve of the activated charcoal, 
Proceedings of the Academic of Sciences USSR 55, 331-333. 

Freundlich H.M.F., 1906, Over the adsorption in solution, J. Phys. Chem. 57, 385-470. 
Fu F., Wang Q., 2011, Removal of heavy metal ions from wastewaters: A review, Journal of Environmental 

Management 92, 407-418. 
Hadi M., Samarghandi, M.R., McKay G., 2010, Equilibrium two-parameter isotherms of acid dyes sorption by 

activated carbons: Study of residual errors, Chemical Engineering Journal 160, 408-416. 
Hall K.R., Eagleton L.C., Acrivos A., Vermeulen T., 1966, Pore and solid diffusion kinetics in fixed-bed 

adsorption under constant-pattern condition, Industrial and Engineering Chemistry Fundamental 5, 212-
213. 

Ho Y.S., Porter J.F., Mckay G., 2002, Equilibrium isotherm studies for the sorption of divalent metal ions onto 
peat: copper, nickel and lead single component systems, Water, Air, and Soil Pollution 141, 1-33. 

Ho Y.S., 2004, Selection of optimum sorption isotherm, Carbon 42, 2115-2116. 
Lam Y.F., Lee L.Y., Chua, S.J., Lim S.S., Gan S., 2016, Insights into the equilibrium, kinetic and 

thermodynamics of nickel removal by environmental friendly Lansium domesticum peel biosorbent, 
Ecotoxicology and Environmental Safety 127, 61-70. 

Langmuir I., 1918, The adsorption of gases on plane surfaces of glass, mica and platinum, Journal of the 
American Chemical Society 40, 1361-1403. 

Lavecchia R., Medici F., Patterer M.S., Zuorro A., 2016, Lead Removal from Water by Adsorption on Spent 
Coffee Grounds, Chemical Engineering Transactions 47, 295-300. 

Lee X.J., Chemmangattuvalappil N., Lee L.Y., 2015, Adsorptive removal of salicylic acid from aqueous 
solutions using new graphene-based nanosorbents, Chemical Engineering Transactions 45, 1387-1392. 

Lima L.K.S., Silva J.F.L., Silva M.G.C., Vieira M.G.A., 2014, Lead Biosorption by Salvinia Natans biomass: 
Equilibrium Study, Chemical Engineering Transactions 38, 97-102. 

Marquardt D.W., 1963, An algorithm for least-squares estimation of nonlinear parameters, Journal of the 
Society for Industrial and Applied Mathematics 11, 431-441. 

McCabe W.L., Smith J.C., Harriott P., 2005, Unit operations of chemical engineering, Seventh Edition, 
McGraw Hill, New York, United States. 

Ng J.C.Y., Cheung W.H., McKay G., 2003, Equilibrium studies for the sorption of lead from effluents using 
chitosan, Chemosphere 52, 1021-1030. 

Seolatto A.A., Filho C.J.S., Mota D.L.F., 2012, Evaluation of the Efficiency of Biosorption of Lead, Cadmium, 
and Chromium by the Biomass of Pequi Fruit Skin (Caryocar brasiliense Camb.), Chemical Engineering 
Transactions 27, 73-78. 

Shazili N.A.M., Yunus K., Ahmad A.S., Abdullah N., Rashid M.K.A., 2006, Heavy metal pollution status in the 
Malaysian aquatic environment, Aquatic Ecosystem Health & Management 9 (2), 137-145. 

Sulaiman F., Abdullah N., Gerhauser H., Shariff A., 2011, An outlook of Malaysian energy, oil palm industry 
and its utilization of wastes as useful resources, Biomass and Bioenergy 35, 3775-3786. 

Temkin M.I., Pyzhev V.M., 1940, Kinetics of ammonia synthesis on promoted iron catalyst, Acta Physiochim. 
USSR 12, 327-356. 

942