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 

Modelling of Cadmium (II) Uptake from Aqueous Solutions 
using Treated Rice Husk: Fixed – Bed Studies   

Abdurrahman Garbaa,b, Noor Shawal Nasri*,c, Hatijah Basria, Husna Mohd Zainc,d, 
Umar S. Hayatuc,e, Abdulrahman Abdulrasheedc,f, Rahmat Mohsinc, Zulkifli Abdul 
Majidc, Norhana Mohamed Rashidc 
aDepartment of Science. Faculty of Science, Technology and Human Development. Universiti Tun Hussein Onn Malaysia, 
a86400 Parit Raja, Batu Pahat, Johor, Malaysia 
bFederal government Girls college Bakori, P.M.B. 6030 Funtua. Katsina State. Nigeria 
cSustainable Waste-To-Wealth Program, UTM-MPRC Institute for Oil and Gas, Resource Sustainability Research Alliance,     
aUniversiti Teknologi Malaysia, 81310 Johor Bahru, Johor, Malaysia 
dDepartment of Energy Engineering, Faculty of Chemical and Energy Engineering, Universiti Teknologi Malaysia, 81310 
dUTM Skudai, Johor, Malaysia 
eDepartment of Chemical Engineering Technology, School of Engineering Technology, Federal Polytechnic P.M.B 35 Mubi, 
dAdamawa State, Nigeria 
fChemical Engineering Department, Abubakar Tafawa Balewa University, Tafawa Balewa Way, PMB 0248 Bauchi, Bauchi 
dstate, Nigeria 
 noorshaw@utm.my 

Rice husk is an agricultural waste material obtained mainly from rice mills. Treated rice husk was evaluated as 
a sorbent for cadmium (II) ions removal from solutions by utilising fixed-bed adsorption mode. In this study, the 
influence of flow rate (3 and 9 mL/min), adsorbent heights of (0.9, 1.8 and 2.8 cm) and influent cadmium ions 
concentration of (5 and 20 mg/L) on the sorption capacity of the adsorbent in a fixed-bed column were 
explored. The highest uptake of 87 % was obtained using 20 mg/L initial Cd (II) solution was achieved at high 
flow rate of 9 mL/min and a bed height of 2.8 cm. The experimental results obtained from the column 
adsorption studies were correlated with the Thomas, Yoon–Nelson and Adams–Bohart models. The modelling 
results for the adsorption indicated that the Adams–Bohart model fitted well over the other models. 

1. Introduction 
Excessive discharge of industrial and municipal waste laden with heavy metals causes environmental pollution 
which is a serious problem that needs immediate attention (Khairy et al., 2014). Heavy metals such as 
cadmium were regarded as environmental pollutants that were listed as category–1 carcinogen and as 
Group–B1 carcinogen by International Agency for Research on Cancer and US Environmental Protection 
Agency (EPA) due to their irreparable effects on the environment. Cadmium being a heavy metal has attracted 
serious attention because of its hazardous nature. It is frequently found in wastewater effluents from chemical, 
metallurgical, paint, coating, mining, nuclear and other related industries. Being a transition metal, cadmium is 
a soft whitish silver or bluish–white coloured metal that has identical chemistry with mercury and zinc. 
Averagely, there is about 0.1 – 0.5 mg/L cadmium concentration in the earth crust and its total world 
production is 22,300 t as at 2010 based on British Geological survey (Hetherington et al., 2008). The 
maximum concentration limit for cadmium that can be present in wastewater and be considered as risk free to 
living organisms was established by different regulatory agencies around the world. The permitted limit set by 
EPA is 0.5 mg/L for wastewater, while WHO guide lines sets 0.003 mg/L as drinking water limit (Barragán et 
al., 2016). 
Cadmium is extensively utilised in plasticisers, pigments, batteries and solar panels. Human exposure to large 
volume of cadmium lead to bone demineralisation, cardiovascular disease, renal dysfunction, arthritis, 
osteoporosis, osteomalacia, anaemia, learning disorder, cancer, itai–itai disease, hypertension, pneumonitis, 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1756039

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Garba A., Nasri N.S., Basri H., Zain H.M., Hayatu U.S., Abdulrasheed A., Mohsin R., Majid Z.A., Rashid N.M., 2017, 
Modeling of cadmium (ii) uptake from aqueous solutions using treated rice husk: fixed – bed studies, Chemical Engineering Transactions, 56, 
229-234  DOI:10.3303/CET1756039   

229



lung insufficiency and weight loss (Nessa et al., 2016). A number of techniques were adopted for cadmium 
removal from solutions which include precipitation, evaporation, filtration, membrane separation, ion 
exchange, coagulation/flocculation, complexation, cementation, electrochemical operation and adsorption 
(Lavecchia et al., 2016). Adsorption process has been adopted for cadmium removal because it is cost–
effective, environmental friendly, sustainable and the spent adsorbent can easily be regenerated (Garba et al., 
2016).  
The aim of this study is to explore the removal of cadmium ions using cheap, sustainable and efficient 
agricultural waste materials that undergoes simple treatment process which requires little amount of chemicals 
in order to reduce chemical pollution and at same time keep the cost of the adsorbent as cheap as possible. 

2. Experimental 
2.1 Materials and methods 
Sodium hydroxide pellets, hydrochloric acid and cadmium stock solution (1,000 mg/L) were all supplied by 
Merck chemicals Malaysia. Rice husk was purchased from a local mill in Parit Raja, Johor, Malaysia. The 
fresh rice husk designated as (RH–Raw) was washed dried at 60 °C for 24 h, milled and sieved using sieve 
and shakers. The RH–Raw fractions that passed through 250 – 500 µm were retained as starting material. 
The retained sample was then soaked in 2 % NaOH solution for 4 h. the excess NaOH was washed off using 
deionised water, then oven dried at 60 °C over a period of 24 h. The treated rice husk was designated as RH–
NaOH. 

2.2 Wastewater preparation 
The synthetic cadmium ion solution was prepared by dilution of appropriate amount of the cadmium stock 
solution (1,000 mg/L) using deionised water to obtain concentrations of 5 mg/L and 20 mg/L. 

2.3 Fixed–bed adsorption studies 
The fixed–bed adsorption studies were performed at pH 6.5 and at room temperature using a glass column 
(1.2 cm internal diameter x 19.5 cm height). The synthetic cadmium ions solution was introduced into the 
column from the top using a peristaltic pump. Figure 1 shows the experimental set-up of the cadmium 
adsorption. Three adsorption parameters were investigated, initial cadmium concentration (5 and 20 mg/L), 
cadmium solution flow rate (3 and 9 mL/min) and adsorbent height (0.9, 1.8, and 2.8 cm). Cadmium ions 
concentration adsorbed on the sample were determined using atomic adsorption spectrophotometer 
(PerkinElmer HGA 900 model) by collecting effluents from the column at intervals. 
 

 

Figure 1: The cadmium adsorption set-up 

2.1 Characterisation of the sample 
The treated rice husk was characterised using X-ray powder diffraction (XRD), scanning electron microscopy 
attached with Energy dispersive spectroscopy (SEM–EDS) and Fourier transform infrared spectroscopy 
(FTIR) 

230



3. Results and discussion 
3.1 Fourier transform infrared spectroscopy (FTIR) 
The FTIR analysis is an important tool for identification of surface functionalities which are instrumental in 
adsorption of the heavy metal ions. The FTIR results (Figure 2) of the raw rice husk indicated bands at 3,370, 
2,920, 1,423 and 1,048 cm-1  which corresponds to peaks for –OH stretching vibration with range between 
3,100 – 3,500 cm-1, –CH2 asymmetric stretching vibration, –COO vibration or the aromatic ring absorption for 
C=C–C arising from lignin since it contains aromatic rings and stretching vibrations related to C–C–O from 
carbohydrates or Si–O–Si stretching vibration (Zhang et al., 2013). After treatment with sodium hydroxide, the 
broad band at 1,048 shift to 1,034 and new band at 861 cm-1 disappear due to removal of lignin from the 
sample. 

 

Figure 2: FTIR spectra of the raw and NaOH treated rice husk 

3.2 Scanning electron microscopy – Energy dispersive X-ray spectroscopy (SEM- EDS) 
The SEM image of the raw rice husk as presented in Figure 3 indicated that the raw rice husk has no 
developed pores and the surface was highly rough. The NaOH treated rice husk surface was converted to a 
more ordered surface with heterogeneous pores due to partial removal of hemicellulose and reduction in 
crystallinity of the cellulose in the material (Ashrafi et al., 2016). From Figure 4, the EDS spectra of the 
untreated rice husk surface contain only elements C, O and Si. After treatment of the rice husk with NaOH 
solution, Na was fixed on their surface and the peak intensity of Si increases (Wang et al., 2010). 
 

  
(a) (b) 

Figure 3: SEM micrograph of (a) raw, (b) treated rice husk   

 
 

(a) (b) 

Figure 4: EDS results of (a) raw and (b) treated rice husk 

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3.3 Effects of initial cadmium concentration 
The influence of initial cadmium concentration on the breakthrough curves at constant adsorbent height of 2.8 
cm and flow rate of 3 mL/min was presented in Figure 5. The results showed that the breakthrough time 
decreased from 780 to 660 min when the cadmium concentration was increased from 5 to 20 mg/L. The result 
means that, the breakthrough curve and time of saturation decreases as the concentration of the influent 
cadmium solution is increased. The result revealed that, high initial cadmium concentration saturates the rice 
husk more rapidly and the breakthrough was reached before all the pores were filled by the cadmium ions. 
High cadmium ions concentration initiates high driving force for the adsorption process and this explains why 
higher adsorption capacities were obtained at high cadmium ion concentrations (Ji et al., 2013). 
 

0 200 400 600 800

0.0

0.2

0.4

0.6

0.8

1.0

c t/
c 0

Time (min)

 5 mg/L
 20 mg/L

 

Figure 5: Effect of cadmium concentration at fixed bed height of 2.8 cm and flow rate of 3 mL/min 

3.4 Effects of cadmium solution flow rate 
The effect of cadmium solution flow rate was determined by running the column at two flow rates of 3 mL/min 
and 9 mL/min at fixed initial cadmium concentration of 5 mg/L and bed height of 2.8 cm. From Figure 6, it can 
be noted that the exhaustion time decreases from 780 to 180 min as flow rate increases from 3 to 9 mL/min. 
This could be attributed to an increase in the zone speed as the cadmium solution flow rate increases which 
results to reduction in the time required to achieve both breakthrough and exhaustion times. Decrease in flow 
rates provides appropriate residence time for the adsorbent – adsorbate interactions which results to obtaining 
a longer exhaustion time. These results were in agreement with other reported studies (Ahmad and Haydar, 
2016). 
 

.
0 200 400 600 800

0.0

0.2

0.4

0.6

0.8

1.0

c t/
c 0

Time (min)

 3mL/min
 9 mL/min

 

Figure 6: Effect of cadmium solution flow rate at constant bed height of 2.8 cm and 5 mg/L concentration 

3.5 Effects of bed depth 
From Figure 7, that the sharp breakthrough curve and lower breakthrough times were obtained at lower bed 
heights. This is because, as the bed height reduce, there will be less adsorption sites for the cadmium uptake. 
As the bed height increases, more sites were available for cadmium adsorption. The breakthrough curve 
becomes steeper and the breakthrough time becomes bigger (Mondal, 2009). The results agreed well with 
other studies reported (Li and Champagne, 2009). 

232



0 200 400 600 800

0.0

0.2

0.4

0.6

0.8

1.0
c t/

c 0

Time (min)

 0.9 cm
 1.8 cm
 2.8 cm

 

Figure 7: Effect of bed heights at 5 mg/L concentration and flow rate of 3 mL/min 

3.6 Breakthrough curve modelling 

Table 1: The Adams–Bohart, Thomas and Yoon–Nelson model constants for cadmium adsorption by treated 

rice husk packed column. 

Conditions Adams–Bohart Thomas Yoon – Nelson 
pH Z Q Ci KAB N0 R2 KTh qo R2 KYN τ R2 
6.0 3 0.9 5 0.0011 -746 0.7923 -0.0107 -757 0.9417 0.011 -0.0044 0.9417 
6.0 9 0.9 5 0.0007 -66 0.7560 -0.0218 249 0.7609 0.022 0.04 0.7609 
6.0 3 1.8 5 0.00134 -102 0.8 -0.011 -638 0.9364 0.011 -0.0026 0.9364 
6.0 3 2.8 5 0.0014 -118 0.8132 -0.0113 -466 0.9599 0.011 -0.0023 0.9599 
6.0 3 0.9 20 0.0002 -241 0.9842 -0.0112 -344 0.8904 0.011 -0.0097 0.8904 
6.0 9 0.9 20 0.0001 -540 0.9823 -0.0121 219 0.8663 0.012 0.0458 0.8663 
RMSE (%) 2.60 3.70 3.67 
SSE (%) 2.60 3.70 3.67 
R2 0.9935 0.9914 0.9914 

3.7 Adams – Bohart model 
From Table 1, the Adams–Bohart rate constant (KAB) decreases with an increase in both flow rate (3 to  
9 mL/min) and initial cadmium ions concentration (5 to 20 mg/L). The rate constant increases as bed height 
increases (from 0.9 to 2.8 cm). The column saturation concentration (N0) values increases with increase in 
flow rate of 3 to 9 mL/min, but it decreases with both increase in cadmium ion concentrations from 5 to 20 
mg/L and adsorbent bed height of 0.9 to 2.8 cm. Adams – Bohart model gives the best fit because, the model 
has the highest coefficient of determination of 0.9935, but lower RMSE and SSE values. The results agree 
with those reported by Li et al. (2016) on removal of manganese from aqueous solution using rice husk ash in 
a fixed column. 

3.8 Thomas model 
From the results presented in Table 1, the Thomas rate (KTh) constant decreases with increase in flow rate (3 
to 9 mL/min), but increases with increase in cadmium ions concentration from 5 to 20 mg/L. A mixed trend 
was observed when the adsorbent bed height increases from 0.9 to 1.8 cm in which the rate constant at first 
increases. The equilibrium cadmium sorption capacity constant increases with increase in both flow rate from 
3 to 9 mL/min and initial cadmium ions concentration from 5 to 20 mg/L. The Thomas model has high number 
of experiments with coefficient of determination greater than 0.9, but it did not fit the experimental results. This 
is because, the model has lower R2 value compared to the Adams–Bohart model and as well it has larger 
values for both RMSE and SSE. The results was in agreement with those reported by Sarma et al. (2015) on 
removal of Copper and Lead from aqueous solution using cheap agricultural wastes. 

3.9 Yoon – Nelson model 
The model rate constant (KYN) appreciates with an increase in the flow rate, but decreases when the cadmium 
concentration increases. The constant decreases with increase in bed height and the time needed for 50 % 
breakthrough (τ) increases with increase in solution flow rate. The 50 % breakthrough time decreases with 
both increase in bed height and increase in cadmium ions concentration. The model has the highest 
coefficient of determination, but does not give good fit because of higher RMSE and SSE values compared to 
Adams–Bohart model. The results agree with those reported by Farooq et al. (2013) on biosorption of Lead 
and Chromium ions on a wheat straw. 

233



4. Conclusions 
The study explores the ability of a treated rice husk as low cost adsorbent for the uptake of cadmium ions from 
solution in fixed-bed mode. The cadmium uptake was affected by column parameters such as initial cadmium 
ions concentration, adsorbent bed–height and solution flow rate. The Adams–Bohart model fitted the 
experimental data well over the other models employed. This indicates the potentials of using rice husk as 
cheap adsorbent that requires small amount of treatment, but gives a reasonable removal capacity for 
cadmium. 

Acknowledgment 

The authors appreciate the financial support provided by the Ministry of Higher Education Malaysia and 
Universiti Teknologi Malaysia through the Research University Grant Q.J130000.2509.06H79 and 
Q.J130000.2509.10H89. Special thanks to the Sustainable Waste-To-Wealth Program of UTM-MPRC Institute 
for Oil and Gas, Universiti Teknologi Malaysia for the provision of technical support and services, and also its 
technical services grant 01D08. 

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