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PREPARATION OF CaO-BASED PELLET USING RICE HUSK ASH VIA 

GRANULATION METHOD FOR POTENTIAL CO2 CAPTURE 

FARAH DIANA MOHD DAUD1*,  MUHAMMAD  MIRZA MOHAMAD AZIR1,

MUDRIKAH SOFIA MAHMUD1, NORSHAHIDA SARIFUDDIN,  

HAFIZAH HANIM MOHD ZAKI 

1
Deptartment of Manufacturing and Materials Engineering, Kulliyyah of Engineering, International 

Islamic University Malaysia, P.O. Box 10, 50728 Kuala Lumpur, Malaysia 

*Corresponding author: farah_diana@iium.edu.my

(Received: 11th July 2020; Accepted: 18th November 2020; Published on-line: 4th January 2021) 

ABSTRACT:  CO2 capturing has become very significant option to reduce the emission of 

CO2 in the atmosphere and hence, minimizing environmental issues.Among solid CO2 

sorbent, calcium oxide (CaO) is an attractive regenerable sorbent for CO2 capturing because 

of their reactivity and high CO2 absorption capacity. CaO alone suffers from rapid decay of 

CO2 adsorption during multiple carbonation/calcination reaction cycles. The stability of CaO 

sorbents during cyclic runs can be achieved via the incorporation of additive support 

materials. The silica (SiO2) from natural sources such as rice husk is the best candidate to be 

used as an additive in the sorbents. However, the CaO-based sorbent in finely generated 

powders are prone to severe attrition problems. Therefore, this research focuses on 

preparation of CaO-based pellets by using rice husk ash (RHA) via granulation method. The 

result of the raw materials confirmed that Ca(OH)2 have crystalline structure with finely 

distributed grains and RHA exhibit amorphous structure with randomly oriented size grains. 

Based on the XRD, it is confirmed that the insertion of RHA does not alter the phase structure 

of the pellets. Each ratio yield different intensity value and has formation of new peaks after 

sintering. Meanwhile, the microstructures of the pellets show that the pores reduced as the 

calcination temperature increased while the incorporation of RHA caused the pores size 

increased with randomly oriented shape. These findings indicate that the optimum value for 

the pellets is with the Ca(OH)2:RHA ratio of 80:20 and calcination temperature of 750 °C. 

ABSTRAK: Penangkapan CO2 telah menjadi pilihan yang sangat penting untuk 

mengurangkan pelepasan CO2 di atmosfer serta kesan alam sekitar. Antara penjerap CO2 

pepejal, kalsium oksida (CaO) adalah penyerapan yang menarik untuk CO2 yang ditangkap 

kerana kereaktifan dan kapasiti penyerapan CO2 yang tinggi. CaO sahaja menderita daripada 

pelepasan cepat penjerapan CO2 semasa kitaran tindakbalas karbonasi / kalsinasi. Kestabilan 

CaO penjerap semasa berlaku kitaran boleh dicapai melalui penggabungan bahan sokongan 

tambahan. Silika (SiO2) dari sumber semula jadi seperti sekam padi (RHA) adalah calon 

terbaik untuk digunakan sebagai aditif dalam penjerap. Walau bagaimanapun, penjerap 

berasaskan CaO dalam bentuk serbuk halus yang dihasilkan adalah terdedah kepada masalah 

pergeseran yang teruk. Oleh itu, kajian ini memberi tumpuan kepada penyediaan pelet 

berasaskan CaO dengan menggunakan abu sekam beras melalui kaedah granulasi. Hasil 

bahan mentah mengesahkan bahawa Ca(OH)2 mempunyai struktur kristalografi dengan 

bijirin halus dan RHA yang mempamerkan struktur bukan kristal dengan butiran saiz 

berorientasikan secara rawak. Berdasarkan XRD, ia disahkan bahawa penyisipan RHA tidak 

mengubah struktur kristalografi pelet. Setiap nisbah menghasilkan nilai intensiti yang berbeza 

dan mempunyai pembentukan puncak baru selepas pensinteran. Sementara itu, mikrostruktur 

pelet menunjukkan bahawa pori-pori berkurangan apabila suhu kalsinasi meningkat 

sementara pembentukan RHA menyebabkan saiz pori meningkat dengan bentuk 

berorientasikan rawak. Penemuan ini menunjukkan bahawa nilai optimum bagi pelet adalah 
dengan nisbah Ca(OH)2:RHA 80:20 dan suhu kalsinasi 750 °C. 

KEYWORDS: CO2 capture; CaO-based pellets; RHA; Granulation method. 

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1. INTRODUCTION

In Malaysia, the main contribution of CO2 emission is from the energy sectors such as

fossil fuels, natural gas, and coal power plants. The energy sectors in Malaysia contributed at 

about approximately 36% of the total global CO2 emissions in 2004 and among all of the 

greenhouse gases, CO2 gases responsible for 60% of greenhouse effect that cause the global 

warming [1]. Moreover, Malaysia plans to reduce the amount of CO2 release by 25% reduction 

from all sectors and this is according to Green Technology Master Plan 2017-2030 proposed 

by Malaysia government [2]. Thus, planning and solution must be done in order to control and 

resolve the problems of CO2 emissions and greenhouse gases effect.  

One of the solutions to reduce the CO2 gases emitted to the atmosphere is by introducing 

the carbon capture and storage (CCS) technology. This technology captures up to 90% of CO2 

which led to significant reduction of CO2 level in atmosphere [3]. Among the CO2 capture 

methods, CO2 capture by adsorption into a sorbent is the most common technique used in the 

industry due to its better thermal properties and high amount of CO2 adsorption [4]. The 

adsorbent materials are usually made from ceramic materials such as CaO, MgO, and ZrO2. It 

is well known that ceramic materials possess better thermal properties, and these materials will 

be acceptable to be used in the elevated temperature condition. 

However, the limitation of the recent CO2 adsorbent materials is that it has low stability 

and reduction in reactivity in cyclic operation. Recent studies show that other additives such as 

SiO2, MgO, and Al2O3 reinforced into the sorbents can improve the cycle loop of the CO2 

adsorption [4]. Improvement of the CO2 adsorption is done by designing the CO2 capture 

technologies in the form of pellets rather than sorbents itself and the introduction of biomass 

resources with the pellets is one of the advantages upon using waste and eco green materials 

[5]. Thus, this paper aims to study the effect of cycling loops with the pellets design when 

introducing other additives into the sorbents. Plus, the utilization of waste materials such as 

rice husk ash introduced into the pellets will be a huge impact on the economic and 

environmental factor. 

There are many methods and techniques have been done on previous study to produce 

CaO-based sorbents with the addition of SiO2 including, sol-gel, wet impregnation, bio-

template via infiltration, mixing and extrusion-spheronization methods. Among all the methods 

mentioned above, three of the methods utilizing biomass materials, mainly from the rice husks 

to act as the additives inside the CaO-based sorbents while the other two methods (sol-gel and 

wet impregnation) used silica sources from synthetic means. Rice husk ash used as the 

precursor in the CaO-SiO2 sorbent due to the high content of silica. Plus, the sources of rice 

husk are abundant and easy to obtain as it is being produced as the by-product in paddy field 

makes it the best candidate to be used in the CaO-based sorbent. 

Different parameters used in the preparation of the CaO-SiO2 sorbent play a crucial role 

in determining the performance of the pellet. There are several parameters needed for the 

investigation and different parameters usually will give different effects on the pellet whether 

it will improve the performance or becoming unfavourable. One of them is amount of silica 

sources incorporated with the CaO-based sorbents or the ratio amount between those two 

materials. Previous studies showed that different ratio or amount of silica added exhibits 

different cyclic adsorption performance. In one study, ratio of 3:7 RHA/CaO shown better 

stability over 50 cycles compared to 1:9 RHA/CaO even though 1:9 RHA/CaO has better 

carbonation conversion in early cycles [6]. Meanwhile, in the other study, 10%, 20%, 30%, 

40% and 50% of RHA added into the CaO-based sorbent. Initially, the ratio of 20% RHA 

express the highest CO2 adsorption compare to other ratios but it reduces significantly started 

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at the first cycle. Then, it is observed that 40% and 50% RHA into the CaO sorbent maintained 

the highest CO2 capture over the nine cycles [7]. 

The main objective of this paper is to prepare CaO-based pellet with addition of RHA as 

the sacrificial bio-template through granulation method. The pellets were prepared according 

to two different ratios and undergo calcination process at 750°C. The effect of RHA addition 

and calcination at 750°C on the properties of CaO-based pellets were examined through the 

phase structure and morphological characteristics. 

2. EXPERIMENTAL 

2.1. Materials 

Calcium hydroxide from R&M Chemical Sdn. Bhd. was selected as the calcium precursor. 

The rice husk ash (RHA) as the biotemplate material was obtained from MARDI Perlis. 

2.2. Preparation of the RHA 

Initially, RHA is oven-dried at 70°C overnight to eliminate moisture. Then, the fine 

powder of RHA is obtained by ball milling process at 200 rpm for 1 hour. Finally, the ball 

milled RHA was sieved at the size range of 50 µm to 90 µm.  

2.3. Preparation of the Sorbent Pellets 

Next, Ca(OH)2 and RHA powders were weighed according to two different ratios as shown 

in Table 1. At first, the weighed materials were vigorously mixed in a granulator machine at 

73 rpm speed for 10 minutes. Then, the mixture undergoes granulation process at the speed of 

1700 rpm and simultaneously wetted by spraying 300 ml of deionized water. After the 

granulation process, the Ca(OH)2-RHA pellet was obtained in spherical shape and randomly in 

size. Lastly, the CaO-SiO2 pellets were obtained after calcination process in furnace at 750°C. 

Table 1: Two different ratios of Ca(OH)2 and RHA with different weight of each ratio 

 

Ratio of Ca(OH)2 and RHA Weight of Ca(OH)2 (g) Weight of RHA (g) 

80:20 800 200 

70:30 700 300 

 

 

2.4 Characterization 

2.4.1 X-Ray Diffraction (XRD) 

The phase structure of Ca(OH)2, RHA and the prepared CaO-SiO2 pellets, before and after 

calcination at 750°C was examined by X-Ray Diffractometer (XRD) model BRUKER D2 

PHASER. 

2.4.2 Scanning Electron Microscopy (SEM) 

The morphological characteristic of raw materials (Ca(OH)2 and RHA) and the prepared 

CaO-SiO2 pellets at different ratio, before and after calcination process was investigated by 

JSM-IT100 Scanning Electron Microscopy (SEM) machine manufactured by JEOL. 

 

  

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3. RESULTS AND DISCUSSION

3.1. Analysis on the Raw Materials 

Fig. 1(a) and 1(b) show the XRD pattern of Ca(OH)2 and RHA at different scale of 

intensity. Based on the Fig. 1(a), sharp peaks at 2θ = 18.1°, 29.45°, 34.15°, 47.25° and 50.85° 

proved the crystalline structure of Ca(OH)2. Whereas Fig. 1(b) indicated broad peak, centered 

at about 2θ = 23° which confirms the amorphous structure of RHA. It is common that silica 

contain in RHA has amorphous structure, and its transformation to crytalline structure will 

occur when temperature is increased beyond 700°C [9] 

. 

Fig. 2 and 3 displayed the SEM micrographs of Ca(OH)2 and RHA. It has been observed 

for Ca(OH)2 that it consist of finely dispersed, small size particles. Under X5000 magnification 

(Fig. 2(c)), the morphology of Ca(OH)2 revealed that the microstructure is in granular and 

agglomerated shape. While for RHA, the SEM images reveals the siliceous nature and with 

some porosity of the ashes. It was observed that RHA has agglomerated particles in various 

sizes and irregular structures.   

Fig.1. XRD pattern of a) Ca(OH)2 and b) RHA.

(a) 

(b)

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3.2. Characterization of the Sorbent Pellets 

3.2.1 Average Size of the Pellets 

Fig. 4 (a) and (b) show the different ratio of CaO-SiO2 pellets obtained from the 

granulation process. As shown in Fig. 4 (a) and (b), the average size of particles for 80:20 and 

70:30 pellets are 3.0 mm and 4.5 mm respectively. 

The utilization of high speed of granulator and optimum amount of deionized water added 

during the granulation process resulted in small size of pellets. A small size of pellets was 

desired as the smaller the pellets, the higher the surface area of the pellets to covered for 

potential CO2 adsorption application. However, the significant difference in the average 

particles size among the two ratios is presumed to occur due to the different amount of RHA, 

as the SiO2 source added in CaO-SiO2 pellets. The smaller size of pellets is obtained when 

lower amount of RHA added. Table 2 summarized the details of granulation process and the 

resulted average particles size for each ratio before undergo calcination process at 750°C. 

Fig 3: SEM micrographs of RHA at magnification of a) 500X and b) x1000X. 

Fig. 2. SEM micrographs of Ca(OH)2 at magnification of a) 500X, b) 1000X and c) 

5000X.

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Table 2: Summary of the pellets obtained from two different ratios. 

Fig. 5 shows that CaO-SiO2 pellets after the calcination process at 750°C. As can be 

observed in Fig. 5, all pellets have significant reduction in the size of pellet which is much 

smaller compared to the one before the calcination. This is probably due to the elimination of 

moisture from the pellets and significant reduction/shrinkage in pellets size after the calcination 

indicates huge amount of moisture content in each pellets. 

3.2.2 Different Ratio of CaO-SiO2 Pellets Before Calcination 

The phase structure of CaO-SiO2 pellets for each ratio before the calcination process was 

characterized by XRD analysis, as displayed in Fig. 6 (a) and (b). The peak characteristics of 

Ca(OH)2 and SiO2 are detected in XRD pattern of all CaO-SiO2 pellets. According to Fig. 6, it 

is evident that the main crystalline peaks of Ca(OH)2 were detected at about 2θ = 28.76°, 

Ratio of Ca(OH)2 

and RHA 

Impeller and Chopper 

Speed (rpm) 

Amount of Deionized 

Water (ml) 

Average Size 

(mm) 

80:20 73, 1700-1800 300 3.0 

70:30 73, 1700-1800 300 4.5 

Fig. 4 .The obtained pellets from the granulation process of (a) ratio 80:20 

and (b) ratio 70:30. 

Fig. 5. Pellets after calcination of different ratio ;(a)  80:20 and (b) 70:30. 

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34.17°, 47.21° and 62.78°. However, the intensity for each peak was decreased with increasing 

amount of RHA added. Besides, the characteristics peak of silica also could be observed from 

the XRD pattern, however, the intensity of the peaks was very low due to its amorphous nature. 

The silica peak centered about 2θ = 23° was observed in both XRD spectras of pellets prepared. 

Fig. 6. XRD spectra for different ratio of CaO-SiO2 before calcination, (a) 80: 20 and 

(b) 70:30

Different ratio of RHA addition in the CaO-SiO2 pellets as the biomass sacrificial template 

did not disrupted the crystalline structure of the calcium precursor. This is proved by the almost 

similar XRD pattern obtained from the CaO-SiO2 pellets with the XRD pattern of the raw 

Ca(OH)2. Besides, the detection of similar major diffraction peaks from XRD pattern of all 

pellets evidenced the incorporation of sacrificial biomass template materials did not modify the 

crystallinity of the pellets produced [8]. 

The SEM micrograph of the prepared CaO-SiO2 pellets at different ratios were shown in 

Fig. 7 and 8. All the micrographs illustrated that addition of RHA had significantly altered the 

morphology of CaO-SiO2 pellets prepared, according to the ratio. Based on Fig. 8, 80:20 pellet 

shows large and irregular grains size with random distribution. Meanwhile, 70:30 pellet 

exhibits randomly distributed, irregular, and smaller shape of microstructures. Some small 

needle-like or flake structure could be observed which indicates the presence of ash or biomass 

material inside the pellets that have been prepared. According to the micrographs obtained, 

increasing amount of RHA added caused the grains size to decrease significantly which lead 

to the development of irregular microstructures.  

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Fig.7. SEM micrographs of CaO-SiO2 pellets ratio 70:30 before calcination at different 

magnification a) 500X and b) 1000X  

Fig.8. SEM micrographs of CaO-SiO2 pellets ratio 80:20 before calcination at two different 

spots by magnification of 500X 

3.2.3 Effect of Different Ratio after 750 °C Calcination 

The effect of calcination at 750°C on the phase structure of CaO-SiO2 pellets prepared is 

shown in Fig. 9. Sharp peaks were detected from all of the XRD pattern obtained which 

confirmed the existance of crystalline phase. This is due to the formation of CaO after sintering 

at 750°C. The CaO peaks can be observed at 2θ = 29.76°, 33.02°, 39.49°, 47.56°, 51.91° and 

54.58°.  

However, there is significant difference in intensity of peak at 2θ = 29.76°. The highest 

peak intensity was observed in 70:30 pellet followed by 80:20 pellet. Supposedly, if the amount 

of CaO is higher compared to the silicate, the significant increment in peak intensity of CaO 

should be obtained whereas the silicate peaks should remain unchanged [10]. But from the 

XRD pattern obtained, pellet with low amount of CaO (70:30 pellet specifically) possessed the 

highest peak of CaO. This is presumed to occur due to the calcination process at 750°C might 

have altered the phase structure of silica in RHA and thus modified the XRD pattern of all 

pellets. 

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Fig.9. XRD spectra for different ratio of CaO-SiO2 pellet calcined at 750°C 

Morphology of the calcined CaO-SiO2 pellets for each ratio are shown in Fig. 10 and 11. 

After calcination at 750°C, the formation of pores was observed in micrographs acquired. For 

80:20 pellet, grains with random sized have been developed after sintering at 750°C with the 

presence of needle-like structure. The presence of needle-like structure suggests formation of 

a new compund resulted from the calcination of CaO-RHA which mainly composed of Ca, Si 

and O elements [11]. As for 70:30 pellet, the morphology consists of randomly scattered grains 

which is small in size as shown in Fig. 11. 70:30 pellet has irregular pores structure but not as 

large as compared to the pore stucture in 80:20 pellet. However, 80:20 pellet shows better 

porosity as the pores size were larger which caused an increased in porosity. Higher amount of 

well-structured pores were more preferred for CO2 capture application; in which it would 

contribute to an excellent performance of CO2 adsorption. 

Fig.10. SEM micrographs of CaO-SiO2 pellets ratio 80:20 after calcination at 750°C 

with different magnification a) 100X and b) 500X. 

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4. CONCLUSION

This study presented the CaO-based pellets with addition of RHA as the sacrificial bio-

template had been successfully prepared via granulation method. The calcium precursor, 

Ca(OH)2 has agglomerates and granular microstructures and RHA has an irregular and in 

definitive shape of microstructures. Based on the XRD analysis, the Ca(OH)2 has crystalline 

structure, while RHA has amorphous structure. XRD analysis proved that the inclusion of RHA 

in the Ca(OH)2 did not disrupted the crystalline structure of the samples and intensity of the 

peaks were reduced with increasing amount of RHA added. However, the calcination at 750°C 

has significantly modified the XRD pattern of all CaO-SiO2 pellets. The sharp peaks indicated 

the development of crystalline CaO and different ratio has different peak intensity. The pellets 

with low amount of RHA has finer grain structure observed as for increased the amount of 

RHA caused the pores became agglomerate, increase in size and randomly distributed. To 

conclude, based from the characterization result it indicates that ratio 80:20 and calcination 

temperature of 750 °C were the optimum parameters to be used for the pellets production. 

REFERENCES 

[1] Rawshan AB, Kazi S, Sharifah Mastura SA, Mokhtar J. (2015) CO2 emissions, energy

consumption, economic and population growth in Malaysia. Renew.Sust. Energ. Rev., 41:594–601.

[2] Alifah Z. (2017). Malaysia to slash another 25% of CO2 emission by 2030. Retrieved from:

https://themalaysianreserve.com/2017/06/21/malaysia-slash-another-25- co2-emission-2030/

[3] Naeem MA, Armutlulu A, Kierzkowska A & Müller CR. (2017) Development of High-

performance CaO-based CO2 Sorbents Stabilized with Al2O3 or MgO. Energy Procedia, 114: 158–

166.

[4] Zhang Z, Tohid NGB, Muftah HEN. (2018) Carbon Capture. Chapter 4.5, Exergetic, Energetic

Environ. Dimensions, 997-1016.

[5] Wang J, Huang L, Yang R, Zhang Z, Wu J, Gao Y, Wang Q, O'Hare D, Zhong Z. (2014) Recent

advances in solid sorbents for CO2 capture and new development trends. Energy. Environ. Sci.,

7:3478–3518.

Fig.11. SEM micrographs of CaO-SiO2 pellets ratio 70:30 after calcination at 750 

°C with different magnification a) 100X and b) 500X. 

243



IIUM Engineering Journal, Vol. 22, No. 1, 2021 Mohd Daud et al. 

https://doi.org/10.31436/iiumej.v22i1.1544 

[6] Monica BG, Jose, MV, Antonio P, Pedro ESJ, Luis APM. (2018) Low-cost Ca-based composites

synthesized by biotemplate method for thermochemical energy storage of concentrated solar power.

Appl.Energy, 210:108–116.

[7] Mustakimah M, Suzana Y, Armando TQ, Tetsuya K. (2018) Utilization of rice husk to enhance

calcium oxide-based sorbent prepared from waste cockle shells for cyclic CO2 capture in high-

temperature condition. Environ. Sci. Pollut. Res., 26:33882-33896.

[8] Liu, W., An. H., Qin, C., Yin, J., Wang, G., Feng, B., Xu, M. (2012) Performance Enhancement of

Calcium Oxide Sorbents for Cyclic CO2 Capture: A Review. Energ. Fuels, 26:275-2767.

[9] María E, Vasilije M, Edward JA. (2016) Calcium looping sorbents for CO2 capture. Appl. Energy,

180:722–742.

[10] Sanchez-Jimenez PE, Perez-Maqueda LA, & Valverde JM. (2014) Nanosilica supported CaO: a

regenerable and mechanically hard CO2 sorbent at Ca-looping conditions. Appl. Energy, 118:92-

99.

[11] Li Y, Zhao C, Ren Q, Duan L, Chen H, Chen X. (2009) Effect of rice husk ash addition on CO2
capture behavior of calcium-based sorbent during calcium looping cycle. Full Processing

Technology, 90: 825-834.

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