The Journal of Engineering Research (TJER), Vol. 18, No. 1, (2021) 1-11 
 

 
 

 

*Corresponding author’s e-mail: amalhamza31@yahoo.com 
  
 

DOI: 10.53540/tjer.vol18iss1pp1-11 

IMPROVING BIOGAS PRODUCTION USING DIFFERENT 
PRETREATMENT OF RICE HUSK INOCULATED WITH OSTRICH 

DUNG  
 

Huda Jassim *, and Amal H. Khalil 
Department of Environmental Engineering, College of Engineering, 

University of Babylon, Iraq 
 

 
ABSTRACT: The increased demand for fossil fuel due to its huge importance in global energy has caused 
many problems to the environment both locally and globally. This study investigated the feasibility of the 
anaerobic co-digestion using rise husks as a biomass waste source and ostrich dung as a source of inoculum for 
biogas production as renewable energy. Samples of grounded RH were pretreated with ultrasound, hydrothermal, 
combined hydrothermal-ultrasonic, NaOH (3% w/v) and combined 3% NaOH-ultrasound pretreatment. The 
cumulative production of biogas for the pretreated samples was 44.19, 39.5, 46.3, 47.16 and 52.38 ml/g VS, 
respectively. The results stated the increase in biogas generation by 50.72, 34.72, 57.91, 60.85 and 78.65%, 
respectively, as compared to untreated sample that produced 29.32 ml/g VS of biogas. The results of methane 
productivity, which were 30.73, 26.78, 32.24, 32.91 and 37.3 ml/g VS, respectively; for the pretreated samples 
with the same arrangement mentioned above, caused an increment by 66.11, 44.76, 74.27, 77.89, 101.62%, 
respectively, as compared to methane yield of the untreated sample that resulted in 18.5 ml/g VS. It was 
observed that there was well compatibility between estimated and predicted values for methane (> 0.95) using 
modified Gompertz model. The improvements in biogas and methane yield pointed out the anaerobic co-
digestion of rice husks after pretreatment inoculated with ostrich dung is a promising technology to produce 
renewable energy. The use of ostrich dung encouraged biogas productivity. In addition, Biogas can reduce 
environmental pollution by managing wastes.  
 

 

Keywords: Biogas; Co-digestion; Hydrothermal; Ultrasound, Rice husks; Ostrich dung. 
 
 

 النعام بفضالت األرز الملقح لقشور مختلفة مسبقةمعالجات   باستخدام الحیوي الغاز إنتاج تحسین
 

 امال حمزة خلیل ، *ھدى جاسم
 

ان الطلب المتزاید للوقود االحفوري نسبة الى اھمیتھ الكبرى في الطاقة العالمیة ادت الى عدة مشاكل للبیئة محلیا  :الملخص
الدراسة الحالیة بحثت امكانیة تطبیق الھضم المشترك الالھوائي باستعمال قشور الرز كمصدر للمخلفات الحیویة  .وعالمیا

وفضالت النعام كمصدر للبكتریا النتاج الغاز الحیوي كنوع من الطاقة المتجددة. تمت معالجة مسحوق قشور الرز بعدة 
الجة بالبخار،المعالجة المركبة بالموجات فوق الصوتیة معالجات وھي المعالجة  بالموجات فوق الصوتیة ،المع

 3) ، واخیرا المعالجة المركبة بھیدروكسید الصودیوم w/v) %3%والبخار،المعالجة بھیدروكسید الصودیوم بتركیز 
 ، 47.16،  46.3، 44.19،39.5والموجات فوق الصوتیة. االنتاج المتراكم للغاز الحیوي لھذه النماذج المعالجة ھو 

مل/غم من المواد العضویة المتطایرة على التوالي مما یعني ان الزیادة الحاصلة في انتاج الغاز الحیوي لھذه النماذج  52.38
% على التوالي مقارنة بالنموذج غیر المعالج. ان انتاجیة المیثان 78.65، 60.85،  57.91، 34.72، 50.72المعالجة ھي 

% على التوالي للنماذج المعالجة بنفس الترتیب اعاله 101.62، 77.89، 74.27  ،44.76، 66.11تحسنت  ایضا بحوالي 
مقارنة بالنموذج غیر المعالج. لقد اظھرت النتائج بان ھناك تطابق بین النتائج المختبریة والنتائج النظریة عند تطبیق 

في نتائج  الغاز الحیوي والمیثان  . ان الزیادة 0.95>وبمعامل ارتباط  modified Gompertz modelالنموذج الریاضي 
ت النعام ھي تكنولوجیا واعدة في لمطحون قشور الرز المعالج وفضال تشیر الى ان ان عملیة الھضم المشترك الالھوائي

مجال الطاقة المتجددة. ان استعمال فضالت النعام قد ادى الى تعزیز انتاجیة الغاز الحیوي التي لھا دور في تقلیل التلوث 
  البیئي من خالل ادارة المخلفات.

 
 فضالت النعام ؛قشور الرز ؛تیةلصوا الموجات فوق ؛راریة المائیةالح ؛المشتركالھضم  ؛الغاز الحیوي لكلمات المفتاحیة:ا

  



Improving Biogas Production Using Different Pretreatment of Rice Husk Inoculated With Ostrich Dung 

2 

1.  INTRODUCTION  
The global energy markets depend majorly on fossil 
fuel like coal, petroleum, diesel, and natural gas. 
Since fossil fuel formation requires trillions of years, 
its stock is finite and subjects to diminution (Saboor et 
al., 2017). However, ease of access to fossil fuels 
during almost two centuries has decreased the 
available fossil fuel reservoirs, causing rising prices. 
(Sari & Budiyono, 2014). On the other hand, fossil 
fuel is considered as one of the main sources of global 
warming which emits carbon dioxide (CO2), methane 
(CH4), and some other trace gases, which result in 
many environmental problems and bad effects on 
human health and ecosystem. Therefore, the issue that 
has become a worldwide concern is the need for 
renewable, cheap, and clean energy sources, which 
has grown up with industrialization and global 
development of technology, as described by Noori 
(2017). 

Anaerobic digestion (AD) has been defined as the 
biochemical process in which microorganisms 
breakdown the bulky organic molecule into smaller 
molecules under anaerobic conditions (Srivastava, 
2020). Lignocellulosic biomass is the earth’s most 
abundant and renewable resource, and, lignin is its 
strongest component such as hardwood, softwood, 
grasses, as well as household, industrial, and 
agriculture residues that can be used for sustainable 
methane production (Otieno and Ogutu, 2020; 
Zieliński et al., 2017). 

Rice husks are agricultural wastes that remain after 
the processing of the rice crop, like rice straw and rice 
husk. Therefore, rice husks can be improved methane 
yield, as reported by Vivekanandan & Kamaraj 
(2011). Lignocellulosic biomass material majorly 
includes cellulose, hemicellulose, and lignin, the 
arrangements of the contents inside the biomass 
makes it an extremely complex structure, as reported 
by Rehman et al. (2013). In order to improve biogas 
production from lignocellulosic biomass, a 
pretreatment process is necessary to disrupt naturally 
recalcitrant carbohydrateelignin shields that impair 
the accessibility of enzymes and microbes to cellulose 
and hemicellulose (Zheng et al., 2014). Besides, this 
led to the enhancement of lignin and hemicellulose 
removal, which allows hydrolytic reagents, improved 
access to the cellulose molecules in the subsequent 
hydrolysis steps (Rehman et al., 2013). From the 
pretreatments, Ultrasound, hydrothermal, combined 
hydrothermal-ultrasonic, alkaline, and combined 
alkaline-ultrasound pretreatment. A high alternating 
voltage is produced by ultrasound energy during the 
pretreatment of ultrasound. Ultrasound waves produce 
internal negative pressure, which in turn causes 
forming of small bubbles during the process of cell 
disruption. Ultrasound energy causes a stunning 
temperature and pressure, which lead to the 
destruction of the cell membrane (Liqian, 2011). 
Hydrothermal pretreatment of lignocellulosic biomass 
for enhanced bio-ethanol and biogas production is 

gaining the 21st century. Water under high pressure 
and temperature can penetrate into biomass, hydrate 
cellulose, and removes hemicellulose and part of 
lignin, the major advantages are no addition of 
chemicals and no requirements of corrosion-resistant 
materials for hydrolysis reactors in the hydrothermal 
pretreatment process (Chandra et al., 2012). Alkaline 
pretreatment, usually employing NaOH, is known to 
break bond linkages between lignin in the 
lignocelluloses material, causing cellulose swelling 
which results in greater accessibility of the cellulose 
fraction (Talha et al., 2018). Combined pretreatments 
including hydrothermal-ultrasonic and 3% NaOH-
ultrasound pretreatment are applied, some studies 
have found that the synergies of matched and mixed 
pretreatments might optimize the overall outcome, as 
reported by Liqian (2011). 

This study was aimed to investigate the influence of 
single pretreatment) ultrasonic, hydrothermal, NaOH 
(3% w/v))  and combined pretreatment (hydrothermal-
ultrasonic, 3% NaOH, -ultrasonic) for rice husks on 
biogas production and on the characteristics of rice 
husks. 
 
2.   MATERIALS AND METHODS 
2.1   Preparing of Substrate and Inoculum 
2.1.1   Preparing of Substrate 
RH was collected from a rice field in Al-Musayib city 
(Hilla, Iraq). After collection, the sample was 
manually cleaned to remove sand and undesirable 
particulates. The rice husk was air-dried for three days 
at 37- 40 ºC. Then, they were milled by using an 
electrical household grinder and screened by using a 
mechanical screener to get a size of (0.3-0.6 mm). The 
size of the sample was selected depending on the 
previous work (Ismail and Noori, 2018). The 
Chemical characteristics of RH are shown in Table 1. 

 
Table 1. Chemical characterizes of rice husks (RH) and 

ostrich dung (OD). 
Variables        RH       OD 

TS (%) 94.2 94.4 

VS (%) 82.08 32.52 

VS/TS 0.88 0.34 

Cellulose content (%) 33 - 

Hemicellulose content (%) 25 - 

Lignin content (%) 20 - 

Carbon content (%) 48.58 18.86 

Nitrogen content (%) 0.52 2.33 
C/N 

 
93.42 8.09 

 



Huda Jassim and Amal H. Khalil 

3 

2.1.2   Preparing of Inoculum 
Ostrich dung (OD) was used as bacterium sources in 
this study. Six fresh samples (one and two days old) 
were collected in the year 2019 from the ostrich farm 
in Al-Mahawil city, Babylon, Iraq. Then, it was air-
dried, crushed, and stored in a plastic container. The 
characteristic of OD is clarified in Table 1. The 
inoculum was incubated at 35-37ºC for 1 week to 
degrade easily degradable materials presented in them 
and to reduce non-specific biogas generation (Saboor 
et al., 2017; BundÓ et al., 2017). The slurry of 
inoculum was provided by blending 300 ml of 
distilled water with 35 g of crushed OD. The mixed 
slurry was manually homogenized by glass rod, 
according to the procedure adopted by Ismail and 
Noori (2018). 
 
2.2   Pretreatment conditions 
To improve the capability of lignocellulosic RH to 
digestate through the anaerobic co-digestion, six 
pretreatments were applied which were ultrasound, 
hydrothermal, combined hydrothermal and 
ultrasound, alkaline with NaOH (98%, provided by 
CA, USA), and combined alkaline with ultrasound 
pretreatment. The details of the pretreatments are 
explained in Table 2. Each pretreatment was 
performed using 30 g from ground RH. Ultrasound 
pretreatment was performed by ultrasound cell 
crusher (Model: SJIA-1200W MTI, Germany). The 
temperature (25 °C) was selected depending on study 
Kavitha et al. (2016) who reported that the sonication 
was carried out at room temperature without any 
temperature regulation. While the time (15 min) was 
selected depending on study Sulʾman et al. (2011) 
who reported that the optimum conditions for 
pretreatment of the substrate at which the most 
complete destruction of the plant material is achieved 
are an intensity of 368 W/ cm2 and a duration of no 
more than 15 min., the frequency (20 KHz, was 
selected depending on Kavitha et al., 2016), whereas 
the input power (480) was modified. In electrical 
autoclave (Model: DAIHAN LABTECH, Korea), the 
hydrothermal pretreatment was done. Pretreatment 
time (15 min) was selected according to (Alzate et al., 
2012). The temperature (121°C) and pressure (15 psi) 

were modified. The heating temperature (80 °C) used 
in alkaline pretreatment was carried out according to 
the previous research work (Hassan et al., 2016a) 
while the concentration of NaOH (3%) and 
pretreatment time (3hr.) were modified.  
 
2.3 Biochemical Methane Potential (BMP) Set 

up 
BMP tests were used to compare the anaerobic 
biodegradability of pretreated and non-pretreated 
microalgal biomass (Fabiana and Ivet, 2015), six 
digesters were performed in a batch system. The 
digesters included rice husk in case of untreated (RH-
1) and in case of pretreatments: RH-2, RH-3, RH-4, 
RH-5, and RH-6. Figure (1) states, the arrangement of 
the lab-scale system used in this study for the 
anaerobic co-digestion process, which was depending 
on the previous study (Ismail & Noori., 2018) with 
some modifications to dimensions. Each digester is 
represented by 500-mL Pyrex borosilicate. Inside 
each digester, the ratio of 1:10 was used according to 
previous research (Ismail & Noori., 2018). This ratio 
indicated 30 g of solid waste: 300 ml of inoculum 
slurry. A rubber stopper was used to plug each 
digester. Two ports in each one with 5 mm diameter. 
Glass tubes were submerged inside the digester 
through the two ports. A rubber tube was connected to 
each glass tube from the other end, which in turn 
connected to valves to curb the release of generated 
gas, according to previous research (Ismail & Noori., 
2018). 

Before the start of each batch, the pH of all the 
reactors was determined after mixing the inoculum 
and substrate and was adjusted to pH =7 if necessary 
by adding concentrated HCl solution after adding the 
inoculums and substrates, according to the procedure 
adopted by previous studies (Sambusiti et al., 2013; 
Saboor et al., 2017). In order to avoid aerobic 
respiration, oxygen in the headspace was replaced by 
the purging of nitrogen gas for 3-5mins. The 
introduced nitrogen will maintain an anaerobic 
environment and it will be helpful for a survey of 
methanogenic bacteria for effective biogas 
production. Then the digesters were closed tightly, as 
explained by Kannah et al. (2017). 
 

Table 2. Pretreatment conditions in this study. 
Pretreatment 

type 
Symbol % 

NaOH 
Temperature 

(°C) 
Time Frequency 

kHz 
Input power 

W 
Pressure 

psi 

Untreated RH-1 - - - - - - 
Ultrasound RH-2 - 25* 15** min 20  - 

Hydrothermal RH-3 - 121 15*** min - - 15 
Hydrotherm
al-ultrasonic 

  RH-4 The same conditions of hydrothermal and ultrasonic were applied in this pretreatment 

Alkaline  RH-5 3 80**** 3 h - 480 - 
Alkaline-
ultrasound 

 RH-6 all above conditions were applied in this combined pretreatment  

* depending on study Kavitha et al. (2016), **depending on study Sulʾman et al. (2011), *** according to Alzate et al. 
(2012), **** according to the previous research work (Hassan et al., 2016a). 



Improving Biogas Production Using Different Pretreatment of Rice Husk Inoculated With Ostrich Dung 
  

4  

 
Figure 1. Experimental setup for a Biogas production 

system that composed of the main parts: (1): 
Water bath, (2) Activated digester, (3) 
Thermostat, (4) Digital thermometer, (5) Rubber 
tube for flushing nitrogen, and (6) Manometer. 

 
Digesters were put in a thermostatic water bath (this 

arrangement was depending on the previous study 
(Noori, 2017) with some modifications) so that they 
remain in the required range of temperature which 
was 50 ºC which was selected according to previous 
research, as described by Deepanraj et al. (2014).   

  
2.4 Analytical Methods 
Parameters like volatile solids (VS), total solids (TS), 
total nitrogen (TN), total carbon (TC) and 
lignocellulosic characteristics were analyzed for 
untreated and pretreated samples of RH. Also, TS, 
VS, TC and TN (TN was carried out using a Kjeldahl 
digestion system (England)) were estimated 
depending on the methods described by Ismail & 
Noori (2018). The characterizes of lignocellulosic RH 
which include lignin, hemicellulose, and cellulose 
were determined depending on Van Soest̕s method 
prescribed by Van Soest et al. (1991) using Raw 
fibres extractor (England). Finally, the produced 
biogas was measured daily by a manometer method, 
as described by Ismail & Noori (2018). 

 
2.5 Kinetic Study 
For an anaerobic digester operating in a batch mode, 
the rate of biogas generation corresponds to a specific 
growth rate of methanogenic bacteria in this digester. 
Accordingly, the predicted rate of biogas production 
can be calculated using the Modified Gompertz 
Model (Ismail and Noori, 2018), the modified 
Gompertz model was carried out using (IBM SPSS 
24.0.1FP2) analytical software. This non-linear 
regression model has been identified as a good 
empirical regression model commonly applied in the 
simulation of methane accumulation, because of its 
good enough precise prediction for different 
substrates (Talha et al., 2018): 

 
 

G(t) = G0.exp{- exp [ 
Rmax.e

G0
 (λ-t) +1 ]}               (1)                                   

 
 
Where, Rmax is a maximum production rate of 
methane, ml/ gVS; G0 is the potential methane 
production, ml/ gVS; G(t)  is the accumulated bio-
methane at the time t, ml/g. VS; t is measured time, 
day; λ is the lag-phase, day; and e is exp (1) = 2.7183 
(Talha et al., 2018; Ismail and Noori, 2018). 
 
3. RESULTS AND DISCUSSION  
3.1 The Impact of Types Pretreatments on the 

Properties of Rice Husk 
The goal of the pretreatment process is to break down 
the lignin structure and disrupt the crystalline 
structure of cellulose so that acids or enzymes can 
easily access and hydrolyze cellulose, as reported by 
Kumar et al. (2009). In order to determine the 
influence of pretreatment with ultrasound (RH-2), 
hydrothermal (RH-3), combined hydrothermal-
ultrasonic (RH-4), NaOH (3% w/v) (RH-5), and 
combined 3% NaOH-ultrasound (RH-6) on the 
amount of cellulose, Hemicellulose and lignin content 
for RH were explained in Table 3. 

Table 3 provides that all pretreatments the chemical 
composition of RH. The amount of cellulose content 
was increased from 33% for RH-1 to become 35% for 
RH-6. The highest cellulose content is again by RH-6 
pretreatment. In RH-2 pretreatment, 15 and 20% 
hemicellulose and lignin reduction were noticed, 
respectively, compared to an untreated sample (RH-
1), our results were in good acceptance with Sulʾman 
et al. (2011) who suggested that ultrasound 
pretreatment caused lignin removal by 11.4% when 
it's used to treat lignocellulosic biomass. C/N (RH-2) 
was increased by 3.26% and reduction in TS and VS 
was obtained by 1.3 and 4%, respectively, compared 
to an untreated sample (RH-1). For RH-3 
pretreatment, all parameters including hemicellulose, 
lignin, TS, VS, and C/N were decreased by 13.04, 17, 
1.55, 3.29 and 3.2%, respectively, as compared with 
the untreated RH-1. The amount of TS, VS, C/N, 
hemicellulose and lignin was 90%, 79.67%, 63.19, 
20.5% and 15.2% in the RH-4 pretreatment, 
corresponding to a reduction of 4.46, 2.94, 32.36, 18, 
and 24%, respectively, as compared to RH-1. In RH-5 
pretreatment, the hemicellulose removal was 24% 
compared to RH-1, while 31% was the removal of 
lignin, the C/N ratio, TS was decreased by 25.13 and 
2.23%, respectively, while VS was increased by 
3.34%, as compared with RH-1. Our results agree 
with the study Monlau et al., (2015) in which 
hemicellulose (26%) with subsequent solubilization 
and removal of lignin (22%), compared to untreated 
samples because of pretreatment of sunflower stalks 
with 4 g NaOH/ 100 g Total Solids (TS) at 55 °C for 
24 h. 



Huda Jassim and Amal H. Khalil 

5 

Table 3.  Influence of the pretreatments on the characteristics of RH. 
Variable Cellulose 

content 
(%) 

Hemicellulose 
content 

(%) 

Lignin 
content 

(%) 

TS (%) VS (%) C/N 

RH-1 33 25 20 94.2 82.08 93.42 

RH-2 33.6 21.25 16 92.9 78.82 96.47 

RH-3 32.8 21.74 16.6 92.7 79.38 90.43 

RH-4 32.5 20.5 15.2 90 79.67 63.19 

RH-5 34.5 19 13.8 92.1 84.82 69.94 

RH-6 35 17.5 12.6 90.83 83.76 38.85 

 
The highest decrease was obtained during RH-6 

pretreatment at 30, 37, 58.41and 3.58% for 
hemicellulose, lignin, C/N ratio and TS, respectively, 
in comparison with RH-1. On the other hand, VS was 
slightly increased by 2.005%. RH-6 pretreatment 
caused the difference in the chemical compositions 
and this difference earns it the preference compared to 
RH-2 and RH-5. Our results were agreed with 
previous research (Soontornchaiboon et al., 2016) 
which showed that the pretreatment by the 
combination of alkaline and ultrasound changed the 
chemical composition of all samples (corn cob, 
pineapple waste, bagasse, rice straw and water 
hyacinth), which was better than sole alkaline 
pretreatment. 
 
3.2  The Effect of Pretreatments for Rice Husk 

on the Generation of Biogas and Methane 
In this study, five pretreatments (RH-2, RH-3, RH-4, 
RH-5 and RH-6) were used to improve the production 
of biogas as compared to the control RH-1. Table 4 
stated the cumulative productions of biogas and 
methane for all pretreated and untreated samples of 
RH. The cumulative productions of biogas for RH-2, 
RH-3, RH-4, RH-5 and RH-6 were 44.19, 39.5, 46.3, 
47.16 and 52.38 ml/g VS, respectively; corresponding 
to biogas increment of 50.72, 34.72, 57.91, 60.85 and 
78.65%, respectively, as compared to its value of the 
control RH-1 which was equal to 29.32 ml/g VS for 
biogas production, as clarified in Figure (2). The 
cumulative productions of methane for RH-2, RH-3, 
RH-4, RH-5, and RH-6 were 30.73, 26.78, 32.24, 
32.91 and 37.3 ml/g VS, respectively; corresponding 
to methane increment of 66.11, 44.76, 74.27, 77.89, 
and 101.62%, respectively, as compared to its value 
the control RH-1 which was equal to 18.5 ml/g VS for 
methane yield, as clarified in Figure (3). 

For RH-2 pretreatment, increasing in biogas and 
methane yield was due to the disruption of the 
structures of lignocellulosic biomass (hemicellulose 
and lignin), where lignin transforms most actively 
during the biodegradation of the pretreated substrate, 
due to the disruption of its bonds with cellulose upon 
ultrasonic treatment as reported by Sulʾman et al. 

 

 
Table 4. Effect of pretreatments on cumulative productions 

of biogas and methane. 
Pretreatment Max. Biogas 

production 
(ml/g.VS) 

Max. Methane 
yield 
(ml/g.VS) 

RH-1 29.32 18.5 

RH-2 44.19 30.73 

RH-3 39.5 26.78 

RH-4 46.3 32.24 

RH-5 47.16 32.91 

RH-6 52.38 37. 3 

 
 (2011), and that was confirmed by the hemicellulose 
and lignin reduction in this study which was achieved 
in RH-2 pretreatment by 15 and 20%, respectively, 
compared to the control RH-1, as explained in Table 
3. Rehman et al. (2013) stated that ultrasound 
generates pressure with rapid cycling. In the 
rarefaction phase of this pretreatment, the pressure 
differentials within a solution cause growth and 
forming of cavitation microbubbles in the sonicated 
liquid. Thus, ultra-sonication produces both physical 
and chemical effects in the slurry being sonicated. All 
the above circumstances contribute to the 
pretreatment of lignocellulosic biomass. Our results 
agree with the previous study Deepanraj et al. (2014) 
reported that the ultrasonic pretreatment at 20 kHz in 
the batch reactor on a palm oil mill and stated that the 
methane yield enhanced by 16%. And, that increase in 
biogas production from 3657 L/m3 of WAS (waste 
activated sludge) to 4413 L/m3 of WAS an increase in 
methane production from 2507 L/m3 of WAS to 3007 
L/m3 of WAS under optimal ultrasonic pretreatment 
conditions in a batch reactor. 

For RH-3 pretreatment, the enhancements, which 
were stated above for biogas and methane yields, 
were because of the fact s it is efficient in penetration 
of the biomass, cellulose hydration, and removal of 
hemicellulose and part of lignin (Hesami et al., 2015).  

 



Improving Biogas Production Using Different Pretreatment of Rice Husk Inoculated With Ostrich Dung 
  
 

6  

The major advantages are that there is no 
requirement for chemicals and corrosion-resistant 
material for the reactor. Typically, it can remove most 
of the hemicellulose and part of lignin in biomass by 
degrading them into soluble fractions and loosen the 
recalcitrant structure as well (Beltrán et al., 2019). 
The results obtained by RH-4 pretreatment, which 
showed enhancement in both biogas and methane 
yields, were because the combined pretreatment was 
better than individual pretreatment. As RH-4 was 
combined of two pretreatments which were RH-2 and 
RH-3, that enhanced its ability to increase biogas and 
methane production yields. Zheng et al. (2014) 
indicated that combined pretreatment could be

 beneficial due to higher methane yield and more 
biomass utilization compared to single pretreatment; 
however, it may also increase pretreatment costs. The 
results were in good agreement with the previous 
study reported by Trzcinski et al. (2015) who stated 
that combination ultrasonication and thermal 
pretreatment of sewage sludge resulted in a 20% 
increase in biogas production during the anaerobic 
digestion of the pre-treated sludge.  

 For RH-5 pretreatment, the results could be due to 
the fact that reported by Zheng et al. (2014) who 
stated that alkaline pretreatment is thought to be the 
cleavage and the saponification of carbohydrate-lignin 
linkages. 
 
 

 
Figure 2. The cumulative production of biogas yield through the digestion process for all untreated and pretreated samples 

of RH. 
 

 
Figure 3.  The cumulative production of methane yield through the digestion process for all untreated and pretreated 

samples of RH. 

0

12

24

36

48

60

0 5 10 15 20 25 30

C
om

ul
at

iv
e 

bi
og

as
, m

l/g
V

S

retention time, days 

RH-1 RH-2 RH-3 RH-5 RH-4 RH-6

0

8

16

24

32

40

0 5 10 15 20 25 30

C
um

ul
at

iv
e 

m
et

ha
ne

, m
l/g

V
S

Solid retention time, days

RH-1 RH-2 RH-3 RH-5 RH-4 RH-6



Huda Jassim and Amal H. Khalil 

7 

 
By the removal of crosslinks, alkaline pretreatment 

leads to an increase of porosity, an internal surface 
area, structural swelling, a decrease in the degree of 
polymerization and crystallinity, disruption of lignin 
structure, and a breakdown of links between lignin 
and other polymers. The effective parameters should 
have increased the porosity of the substrate, which 
makes the carbohydrates more accessible for 
enzymes, as stated by Liqian (2011). Sambusiti et al. 
(2013) suggested that a 43% increase in methane yield 
was noticed using pretreatment conditions 10%  
gNaOH/g TS at 40 ºC for wheat straw in batch mode 
in comparison with the control sample of wheat straw.  

The results associated with RH-6 pretreatment 
stated that it was better than RH-2 and slightly higher 
than RH-5 in the production of biogas and methane 
yield. In addition, RH-6 was better in lignin reduction 
than RH-2 and RH-5, as stated in Table (3). This 
performance of RH-6 pretreatment was due to that the 
combined 

pretreatment was better than single pretreatment. As 
RH-6 was combined with two pretreatments, which 
were RH-2 and RH-5, made the effect of RH-6 was 
stronger than the effect of RH-2 or RH-5 in the 
enhancement of biogas and methane yields. Our 
results had provided an obvious consistency with 
Talha et al. (2018) reported that the combined 
alkaline and ultrasonic treatment, with different 
NaOH loading rates (0.25%-6%) and pre-treatment 
times, were applied to enhance methane yield (up to 
39.49%) compared to the untreated filter mud. 
 
3.3 Kinetic Study Using Modified Gompertz 

Model  
Figure (4a-f) and Table 5 present the results of the 
application modified Gompertz model, which 
explained that the estimated values and predicted 
values were incompatibilities with ρ> 0.95.  
 

 

 
a: Predicted and measure results for RH-1 pretreatment. 

 

 
b: Predicted and measure results for RH-2 pretreatment. 

 

0

4

8

12

16

20

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

R2= 0.959

0

7

14

21

28

35

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

rrR2=0.968



Improving Biogas Production Using Different Pretreatment of Rice Husk Inoculated With Ostrich Dung 
  
 

8  

 
c: Predicted and measure results for RH-3 pretreatment. 

 

 
d: Predicted and measure results for RH-4 pretreatment. 

 

 
e: Predicted and measure results for RH-5 pretreatment. 

 
 

0

7

14

21

28

35

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

R R2=0.986

0

7

14

21

28

35

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

R2=0.970

0

7

14

21

28

35

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

R2=0.961



Huda Jassim and Amal H. Khalil 

9 

 
f: predicted and measure results for RH-6 pretreatment. 
 
Figure 4. The predicted and measured results for methane yield to all the untreated and pretreated samples of RH for all 

rectors (a, RH-1); (b, RH-2); (c, RH-3);  (d, RH-4); (e, RH-5); and (f, RH-6). 
 
Table 5. Results from Performing Modified Gompertz Model. 

Digester 
No. 

G(t) exp. 

(ml methane/g 
VS) 

Gompertz model parameters R2 
λ 

(day) 
 

Rmax. 

(ml methane/g 
VS) 

G0 

(ml methane/g 
VS) 

G(t) model 

(ml methane/g 
VS) 

1 18.5 1.25 0.93 18.5 16.63 0.96 

2 30.73 3.04 1.47 30.73 26.27 0.97 

3 26.78 0.53 1.42 26.78 24.69 0.99 

4 32.24 1.36 1.59 32.24 28.76 0.97 

5 32.91 2.03 1.44 32.91 27.57 0.96 

6 37.3 0.17 1.8 37.3 33.88 0.97 

 

4. CONCLUSION 
 
The results obtained from anaerobic co-digestion of 
pretreated rice husks inoculated with ostrich dung 
were most effective than those of untreated rice husks. 
In addition, the combined pretreatments for rice husks 
showed better results than solo pretreatment in biogas 
and methane production.  The combined hydrothermal 
and ultrasonic pretreatment showed better 
productivity of biogas and methane than ultrasonic 
and hydrothermal pretreatments separately. Also, the 
combined alkaline and ultrasonic pretreatment 
showed better productivity of biogas and methane 
than alkaline and ultrasonic pretreatments separately.  
Best performance in biogas and methane increase for 
solo pretreatments was for alkaline pretreatment with 
3% NaOH by 60.85 and 77.89%, respectively as 
compared with untreated rice husks. The combined 
alkaline and ultrasonic pretreatment were preferably 

recommended for biogas and methane enhancement, 
it caused an increase by 78.65 and 101.62%, 
respectively, as compared to untreated rice husks. 
 
CONFLICT OF INTEREST 
 
The authors declare no conflict of interest. 
 
FUNDING 
 
No funding was received for this study. 
 
ACKNOWLEDGEMENT 
 
The authors would like to thank the Environmental 
Engineering Department and chemistry& 
Microbiology Laboratory in the Biology  
Department/College of Science at the University of 

0

8

16

24

32

40

0 5 10 15 20 25 30

m
l m

et
ha

ne
/g

 V
S

Solid retention time, days

Measured Predicted

R2=0.969



Improving Biogas Production Using Different Pretreatment of Rice Husk Inoculated With Ostrich Dung 
  
 

10  

Babylon. Agriculture Department/ College of 
Agriculture at the University of Baghdad. 
 
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	تحسين إنتاج الغاز الحيوي باستخدام  معالجات مسبقة مختلفة لقشور الأرز الملقح بفضلات النعام
	1.  INTRODUCTION
	CONFLICT OF INTEREST
	FUNDING
	Srivastava S K (2020), Advancement in biogas production from the solid waste by optimizing the anaerobic digestion. Waste Disposal Sustainability Energy 2:85-103.