Post on 28-Apr-2023
REVIEW
A review on composting of oil palm biomass
Mohammadtaghi Vakili • Mohd. Rafatullah • Mahamad Hakimi Ibrahim •
Babak Salamatinia • Zahra Gholami • Haider M. Zwain
Received: 23 January 2014 / Accepted: 8 September 2014� Springer Science+Business Media Dordrecht 2014
Abstract Nowadays, the biomass produced in oil palm industry, such as oil palm fronds,
palm pressed fibers, palm kernel shells, empty fruit bunch, and liquid waste discharged
from the palm oil mill effluent and others, may lead to significant environmental concerns.
The quantity of produced wastes by oil palm industry is increasing with the growth of this
industry day by day. Therefore, the use of these wastes as compost is considered by
researchers to overcome their negative impacts and recycle them to produce a useful
byproduct for agriculture. This review analyzes the recent composting studies on palm oil
biomass and provides useful information about the potential uses of these biomass in
composting as an alternative method for enhanced and sustainable use of biomass pro-
duced from oil palm industry. In addition, environmental impacts of composting are dis-
cussed. This knowledge could build a platform for researchers in this area to understand the
recent developments in palm oil biomass composting by means of addressing the envi-
ronmental pollution concerns as well.
Keywords Compost � Oil palm biomass � Environmental pollution � Agricultural waste �Solid waste
M. Vakili � M. Rafatullah (&) � M. H. IbrahimSchool of Industrial Technology, Universiti Sains Malaysia, 11800 Penang, Malaysiae-mail: mohd_rafatullah@yahoo.co.in; mrafatullah@usm.my
B. SalamatiniaSchool of Engineering, Monash University Sunway Campus, Jalan Lagoon Selatan,46150 Bandar Sunway, Selangor, Malaysia
Z. GholamiSchool of Chemical Engineering, Universiti Sains Malaysia, 14300 Nibong Tebal, Penang, Malaysia
H. M. ZwainSchool of Civil Engineering, Universiti Sains Malaysia, 14300 Nibong Tebal, Penang, Malaysia
123
Environ Dev SustainDOI 10.1007/s10668-014-9581-2
1 Introduction
Humans have increased their activities in the field of agriculture, industry, and hygiene by
an excessive and unsuitable use of resources, materials, and energy to improve the quality
of life. Thus, high amounts of organic wastes are produced that cause some environmental
and ecological problems, which have increased human health concerns and environmental
awareness (Vakili et al. 2012a, b). Khalid et al. (2011) reported that an individual generates
approximately 0.77 kg of waste per day in a developing country and the volume of solid
wastes produced in cities worldwide will continuously increase to about three billion tons
per year in 2025. Hence, waste management is an important issue considered worldwide
and should be implemented to reduce the negative and dangerous effects of wastes on the
environment (Ahmad et al. 2007). Thus, different methods such as incineration, disposal of
waste in landfills, and recycling are used to waste treatment methods of solid wastes
(Khalil et al. 2008).
Composting is a useful and desired method to treat organic solid wastes and generate a
byproduct that can be utilized as a resource of organic fertilizer and soil conditioner
(Wolkowski 2003; Barje et al. 2012). This process is an efficient technique, particularly in
places where the organic matter in the soil is reduced by intensive agricultural activities
and weather conditions (Hassen et al. 1998, 2001). Naturally, composting starts when the
fallen leaves of plants pile up and begin to decompose. The decomposed leaves return in
the soil and roots recover the nutrients from the residual leaves (He et al. 1995). In history,
composting has been used since the ancient times when Greeks, Romans, and Egyptians
discovered agriculture production and improved the methods by using organic wastes that
had decayed for a long time (Diaz and de Bertoldi 2007; Kalamdhad and Kazmi 2008). In
ancient times, humans disposed food wastes in piles near their tents and found that seeds of
many food plants sprouted there. This discovery likely led to the idea that organic piles are
good places for food crops to grow (He et al. 1995).
The composting process is defined as an aerobic, biological process that depends on a
microorganism population, which converts the organic substances of wastes into stabilized
humus and less complex compounds by breaking down the organic residues of plants and
animals, stabilizing nutrients, destroying weed seeds and pathogens, as well as controlling
possible toxins or diseases (Xiao et al. 2011; Zhang et al. 2011; Ogunwande and Osunade
2011). During the composting process, carbon and nitrogen compounds are easily trans-
formed and used as energy and protein sources of the microorganisms, thereby producing
heat, CO2, NH3, H2O, organic acids, and mature compost product at the end of the process
(Bernal et al. 2009; Marche et al. 2003; Hamdy 2005).
Under optimal conditions, composting is divided into the moderate-temperature phase
(mesophilic phase), high-temperature phase (thermophilic phase), and maturation phase
(cooling phase). Different microorganisms increase during the composting phases. During
the decomposition phase, the different microorganisms act as decomposers. Later on,
temperature increases and causes the temperature of the final product of the composting
process to increase. At this time, other microorganisms that can act at higher temperatures
(between 45 and 70 �C) become active (Ahmad et al. 2007; Tang et al. 2007; Purnomo
et al. 2010).
Palm oil production is an important industry, which generates huge amount of organic
wastes. In the world’s vegetable oil market, palm oil is one of the most important sources
and produces different biomasses such as the mesocarp fiber, shell, empty fruit bunch
(EFB), oil palm frond (OPF), which may lead to significant environmental concerns
(Ahmad et al. 2011a, b; Mohammad et al. 2012; Rafatullah et al. 2013; Vakili et al. 2014).
M. Vakili et al.
123
This review analyzes recent composting studies of palm oil biomasses and provides useful
information about the potential uses of these biomasses in composting as an alternative
method for treating of biomasses produced from the oil palm industry and as a means of
addressing the environmental pollution concerns. In addition, environmental impacts of
composting are discussed.
2 Composting of agricultural wastes
According to Ahmad et al. (2007), all materials that can be naturally changed by micro-
organisms into environmentally friendly substances are compostable. Among these suit-
able materials, agricultural wastes, which have an adequate level of organic materials, have
an important function in composting (Ahmad et al. 2007; Khalil et al. 2008). In addition,
various biomasses, such as olive tree pruning, rice straw, coffee husk, vegetables, bran,
olive husks, and wheat straw, have been used in composting as shown in Table 1.
Considering the increasing world population and agricultural activities, agricultural waste
management is a serious concern faced by many communities because of the high biode-
gradability, and the disposal of untreated agricultural wastes threatens the environment and
human health (Ahmad et al. 2007; Giuntini et al. 2006; Bouallagui et al. 2005). In particular,
humans experience problems in agricultural waste disposal because of poor economic value
and small amounts of pollutants; however, agricultural wastes are renewable, available in
large amounts, and very easy to obtain (Sabiiti 2011). Recycling them has great advantages
to agriculture and waste management (Sharma and Forster 1995; Singh et al. 2010). They
can be changed into a useful by-product and is used as a valuable resource (Lesteur et al.
2010; Yu and Huang 2009). These properties encourage farmers and other compost users to
utilize the by-product of agricultural waste composting. The use of these by-products helps to
reduce the negative impacts of agricultural wastes on the environment and agriculture. These
by-products also have high amounts of useful nutrients for plants and organic matter (Tortosa
et al. 2012; Martınez-Blanco et al. 2011) that can be used to improve food security, soil
fertility, and crop production (Garcıa-de-la-Fuente et al. 2011; Hargreaves et al. 2008; Jilani
et al. 2007) by producing safe, innocuous, and nutrient-rich organic fertilizer and soil, such as
a soil conditioner, soil amendment, and environmentally friendly products (Mohammad et al.
2012; Nawar 2008; Trillas et al. 2006).
These wastes can be changed into heat, charcoal, methanol, ethanol, animal feed, and
compost, but some of these wastes remain underused. Some are left in the fields or burned,
which are not suitable methods because these wastes contain high amounts of organic
matter and water, and also cause environmental and air pollution (Sabiiti 2011; Jilani et al.
2007) by producing smoke, CO2, N2O, NO2, O3, and NHO3 (Ezcurra et al. 2001; Hegg
et al. 1987; Lacaux et al. 1992). The direct use of agricultural wastes is not suitable for land
and agricultural production because the structures of these wastes are unknown and they
contain some contaminants, such as pathogens, weed seeds, heavy metals, and unpleasant
odors (Kara and Asan 2007). Composting of agricultural wastes or converting them into
compost is considered as one of the most favorable, cheap, and simple methods used to
treat and stabilize these kinds of wastes as well as generate organic fertilizers (Sabiiti 2011;
Tortosa et al. 2012; Fidero et al. 2012).
These methods improve the environmental health by reducing the environmental
problems, decreasing the volume of agricultural wastes, producing manure, and increasing
the degree of contaminant removal (destroying pathogens and weed seeds as well as
A review on composting of oil palm biomass
123
Ta
ble
1A
nover
vie
wof
the
agri
cult
ura
lw
aste
mat
eria
lsal
read
yuse
dfo
rco
mpost
ing
S.
no
.M
ater
ial
Tim
e(d
ay)
Max
imu
mte
mp
erat
ure
(�C
)M
ois
ture
(%)
pH
(fin
al)
C/N
(fin
al)
Ref
eren
ce
1.
Coff
eepulp
,husk
,an
def
fluen
t150
–6
07.4
17.2
5P
reet
hu
etal
.(2
00
7)
2.
Ric
est
raw
,fa
rmy
ard
man
ure
90
–5
0–
60
8.1
71
3.1
Hel
lal
(20
07)
Ric
est
raw
,ch
icken
man
ure
90
–5
0–
60
81
0.3
Ric
est
raw
,fa
rmyar
dm
anure
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icken
man
ure
90
–5
0–
60
8.0
31
2.5
3.
Lea
ves
,g
rass
,an
dsm
all
shre
dd
edb
run
ches
15
06
35
0–
40
––
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iet
al.
(20
07)
4.
Ric
est
raw
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eget
able
s,so
il,
bra
n3
65
66
08
.31
6.6
2Z
han
get
al.
(20
11)
5.
Sag
ow
aste
60
40
50
–7
07
.32
7.3
3P
etru
set
al.
(20
09)
6.
Veg
etab
lew
aste
and
tree
leav
es90
60–70
55–62
8–8.3
4.1
–5.8
Kal
amdhad
etal
.(2
00
9)
7.
Wh
eat
stra
w,
po
ult
rym
anu
re1
36
3.8
5–
8.8
–9
.2–
Pet
ric
etal
.(2
00
9)
8.
Oli
ve
mil
lw
aste
(alp
eru
jo)
70
––
9.2
18
Gar
cıa-
de-
la-F
uen
teet
al.
(20
11)
9.
Oli
ve
oil
ind
ust
ryw
aste
s,p
ou
ltry
man
ure
27
06
0–
70
50
–6
08
.9–9
.31
1.9
Hac
hic
ha
etal
.(2
00
9a,
b)
10
.R
ice
stra
w9
05
54
2.0
7.0
3–
7.1
21
0.6
Ro
ca-P
erez
etal
.(2
00
9)
11
.L
euca
enas
trim
min
gre
sid
ues
78
53
–5
84
0–
60
7.0
6–
7.5
71
2.6
–2
0B
uen
oet
al.
(20
08)
12
.O
liv
em
ill
was
tes,
sew
age
slu
dg
e1
75
65
–7
–S
anch
ez-A
rias
etal
.(2
00
8)
13.
Agri
cult
ura
lfa
rmw
aste
s30
70
–7.9
019
Sad
iket
al.
(20
10)
14
.C
off
eeh
usk
and
pu
lp7
0–
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11
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assa
etal
.(2
01
1)
15
.P
ou
ltry
man
ure
,ri
cest
raw
14
52
.5–
64
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Pet
ric
and
Sel
imb
asic
(20
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16
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liv
eh
usk
resi
du
es9
02
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62
34
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ano
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.(2
00
8)
17
.G
reen
was
te(g
rass
cutt
ing
san
dfa
llen
leav
es)
21
50
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.24
0G
abh
ane
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.(2
01
2)
18
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liv
eo
ilh
usk
,p
run
ing
was
tes,
shee
pm
anu
re1
20
60
13
.87
.95
27
.9M
onte
mu
rro
etal
.(2
00
9)
Oli
ve
oil
hu
sk,
pru
nin
gw
aste
s,sh
eep
man
ure
12
06
01
3.8
7.9
52
7.9
Oli
ve
oil
hu
sk,
pru
nin
gw
aste
s,u
rea
59
16
.98
.06
23
.5
M. Vakili et al.
123
Ta
ble
1co
nti
nued
S.
no
.M
ater
ial
Tim
e(d
ay)
Max
imu
mte
mp
erat
ure
(�C
)M
ois
ture
(%)
pH
(fin
al)
C/N
(fin
al)
Ref
eren
ce
Oli
ve
oil
hu
sk,
catt
lem
anu
re,
wh
eat
stra
w,
saw
du
st,
lett
uce
resi
dues
65
18
.28
.61
22
.1
Oli
ve
oil
hu
sk,
catt
lem
anu
re,
amm
oniu
msu
lfat
e,w
hea
tst
raw
,sa
wd
ust
,le
ttu
cere
sid
ues
60
31
.86
.44
14
.3
19.
Agri
cult
ura
lorg
anic
was
tes
(ric
est
raw
,v
eget
able
s,b
ran
and
soil
)4
25
54
5–
55
–1
6Z
eng
etal
.(2
01
0)
20.
Ric
est
raw
,an
imal
dung,
(Jat
ropha
curc
as)
deo
iled
cak
e2
5*
70
50
–60
8.8
0–
9.3
51
1.2
–3
2.5
Das
etal
.(2
01
1)
21
.R
ice
stra
w,
veg
etab
les,
bra
n,
soil
50
55
55
–60
9.0
2–
Zen
get
al.
(20
11)
22.
Str
aw,
saw
dust
,hay
,sp
ecifi
edri
skm
ater
ials
300
70
43–62
6.3
–6.5
20–35
Zen
get
al.
(20
12)
23.
Ses
ame
bar
k,
oli
ve
mil
lw
aste
wat
er210
65
40–60
8.7
118.7
5H
achic
ha
etal
.(2
00
9a,
b)
24
.T
ob
acco
pla
nt
was
te,
cow
man
ure
50
62
60
–63
81
2.2
7S
aith
epet
al.
(20
09
25.
Veg
etab
le–fr
uit
was
tes
20
58–70
–8.5
16.5
–17.0
Ars
lan
etal
.(2
01
1)
26
.T
ob
acco
was
te–
34
60
9.5
11
Kay
ikci
oglu
and
Ok
ur
(20
11)
To
bac
cow
aste
,o
liv
ep
om
ace
–3
66
09
.61
7
To
bac
cow
aste
,g
rap
ep
om
ace
–4
16
09
.71
3
27
.C
off
eep
ulp
,b
agas
se1
05
65
–70
50
71
0.4
–2
3.8
Rolz
etal
.(2
01
0)
28.
Ric
e,goat
man
ure
,gre
enw
aste
(veg
etab
lean
dfr
uit
was
te)
90
58
.25
0–
60
7.5
51
0.3
Juso
het
al.
(20
13)
Ric
e,goat
man
ure
,gre
enw
aste
(veg
etab
lean
dfr
uit
was
te)
90
56
.25
0–
60
7.6
21
6.1
29
.E
xh
aust
edg
rap
em
arc,
cow
du
ng
15
45
5–
7.1
–7
.42
0.2
–1
5.5
Bust
aman
teet
al.
(20
08)
30
.C
hic
ken
man
ure
,sa
wd
ust
63
68
–7
.3–7
.45
28
Gao
etal
.(2
01
0)
A review on composting of oil palm biomass
123
decreasing the undesirable odor) (Oviasogie et al. 2010; Gajalakshmi and Abbasi 2008;
Manungufala et al. 2008).
3 Palm oil
Palm oil has been used by humans for more than 5,000 years. It is regarded as a gift from
nature to the world, having benefits such as health and nutritional properties as well as a
value as an energy source being discovered (Narasimhulu and Nanganuru 2010). Oil palm
(Elaeis guineensis) is a tropical plant that grows rapidly in tropical and equatorial areas,
thereby causing some negative impacts on the environment, such as deforestation and loss
of a variety of plant and animal species; some positive impacts, such as economic growth
and production of another fuel source, are also observed (Paterson et al. 2009; Sheil et al.
2009). Oil palm is one of the highly significant industrial crops that is used to produce
vegetable oil for cooking, cosmetics, pharmaceuticals, and biofuels (Fitzherbert et al. 2008;
Koh and Wilcove 2008).
Oil palm has geographically spread from its origin in West Africa to tropical areas in 43
countries in Africa, America, and Asia (Paterson et al. 2009; Narasimhulu and Nanganuru
2010; Yaap et al. 2010). About 5,000 years ago, the oil palm plant was considered a native
plant in Nigeria and its product was used for daily life or commerce (Nigam and Pandey
2009). Until the mid-1960s, the increase in oil palm trees of approximately 74 % of the
whole global oil palm plantation caused Nigeria to become the largest palm oil producer in
the world (Oviasogie et al. 2010). After this period, the number of trees increased sig-
nificantly in other tropical countries, such as Malaysia and Indonesia, which have been
recognized as the largest palm oil producers and exporters in the world (Rupani et al. 2010;
Paterson et al. 2009). These tropical countries have suitable conditions for the growth of
the oil palm tree, including favorable climate, rich natural resources, tropical weather, and
high amount of rainfall (Yaap et al. 2010). Mohammad et al. (2012) revealed that both
Malaysia and Indonesia currently produce approximately 85 % of palm oil that is produced
worldwide (Malaysia 41 % and Indonesia 44 %).
3.1 Palm oil biomass
High productivity, high oil production per unit area, and efficient carbon assimilation of oil
palm are some of its many natural advantages. Palm oil and palm kernel oil are palm oil
industry oil production extracted from same fruit. Palm kernel oil, extracted from the
kernel within the mesocarp, is used in oleo chemical industry to produce beauty products,
soaps, and detergents (Basiron 2007), while palm oil, obtained from the fruit of a palm tree,
is the highest source of edible oil worldwide (25 % of the whole edible oil production in
the world) (Rupani et al. 2010; Shuit et al. 2009). Among the world’s vegetable oil
producers, oil palm is one of the most important sources, followed by soya and rapeseed
(Vakili et al. 2012a, b; Sumathi et al. 2008; Jayed et al. 2011). Compared with other oil-
producing plants, oil palm has advantages such as less production expense, less land usage,
and more production and thus is considered attractive for farmers. After palm oil, rapeseed,
groundnut, sunflower, soybean, coconut, cotton seed, and sesame seed are major edible oil
producer, respectively (Sheil et al. 2009; Hansen 2007).
The oil palm tree is a very productive plant that produces 10–35 tons of fresh fruit
bunch (FFB) in 1 year per hectare (Yusoff 2006). A mature palm is a single-stemmed tree
of approximately 20–30 m in height, with approximately 3 to 5 m-long pinnate leaves and
M. Vakili et al.
123
large clusters (10–40 kg) of approximately 200 individual fruits. Overall, the oil palm tree
has 25–30 years of economic life that starts 3 years after planting by harvesting the FFB.
The peak yield is about 12–14 years after planting (Yusoff 2006; Sumathi et al. 2008). The
produced FFB is approximately 45–56 % of the yield, and the total oil obtained from the
kernel is approximately 40–50 %. The produced oil from the mesocarp and the kernel of
the fruit is approximately 17 tons per hectare annually (Rupani et al. 2010).
In general, the palm oil industry produces several types of biomass, which are produced in
plantation like oil palm fronds (OPF), oil palm trunks (OPT), oil palm bark (OPB), and the
wastes produced in the mill such as palm pressed fibers (PPF), oil palm mesocarp fiber
(OPMF), palm kernel shells (PKS), empty fruit bunch (EFB), palm kernel cake (PKC),
decanter cake (DC), palm oil mill biogas sludge (POMS) and liquid waste discharged from the
palm oil mill effluent (POME) (Rupani et al. 2010; Uemura et al. 2011; Sulaiman et al. 2010).
3.2 Utilization of palm oil biomass
The quantity of produced wastes by palm oil industry is increasing with the growth of this
industry day by day. It is estimated that 184 million tons residues in the world and about 53
million tons of residues are generated from oil palm trees every year in Malaysia and it is
increasing annually by 5 % (Mohammed et al. 2011). Because of the considerable quantity
of generated biomass annually, the several uses of these wastes for value-added purposes
and their conversion into useful products increase financial income and profits, decrease
wastes, and make the palm oil industry an environmentally friendly industry (Shuit et al.
2009; Chavalparit et al. 2006). In the past, empty fruit bunch was utilized as fuel in mills
and the generated ash (approximately 30–40 %) was used as a potassium-rich fertilizer
(Singh et al. 2010) and also ash be able to be mix with concrete (Tangchirapat et al. 2007).
However, empty fruit bunch, decanter cake and the mill effluent are utilized as mulch and
soil improver to preserve the soil surface moisture in palm oil plantation areas; fiber and
shells are applied as fuels in the palm oil industries (Yusoff 2006; Singh et al. 2010) and as
well as fiber is used as an inexpensive adsorbent to filter the heavy metal pollutants in
industrial processes (Isa et al. 2008). The produced methane gas by the fermentation of mill
effluent can be used in the process of energy production in the factory (Yacob et al. 2006).
Other applications include foods, oleochemicals, particle board, pulp, paper, feedstuff,
soap, fertilizer, carbon briquette, activated carbon, furniture, fiber boards and fillers, and
compost production (Ramachandran et al. 2007).
4 Composting of palm oil biomass
Biomass management can decrease energy as well as economical and environmental
problems caused by the unsuitable disposal of huge amounts of agro-industrial wastes;
these wastes have the potential to improve the soil fertility because of their high content of
organic matter and mineral elements (Khan et al. 2009; Ordonez et al. 2006). Composting
is a beneficial way of recycling biomasses to produce a compost that is easy to handle,
stable, and rich in nutrients (Yaser et al. 2007; Castaldi et al. 2005). The conversion of
palm oil biomass to compost as a useful technique in treating these wastes is of high
interest (Yaser et al. 2007). Table 2 shows an overview of the types of palm oil biomasses
already used for composting.
Considering that empty fruit bunch (EFB) is produced in huge amounts in oil palm
mills, it is an appropriate substance for recycling (Singh et al. 2010). The amount of EFB
A review on composting of oil palm biomass
123
Ta
ble
2A
no
ver
vie
wo
fth
ety
pes
of
pal
mo
ilb
iom
ass
use
dfo
rco
mp
ost
ing
S.
no
.M
ater
ial
Tim
e(d
ay)
Max
imu
mT
emp
erat
ure
(�C
)M
ois
ture
(%)
pH
(fin
al)
C/N
(fin
al)
Ref
eren
ce
1.
EF
B,
PO
ME
,dec
ante
rca
ke
slurr
y51
79
50–60
8.5
27
18.6
Yah
ya
etal
.(2
01
0)
EF
B,
PO
ME
51
–5
0–
60
8.6
27
28
.02
2.
EF
B,
fron
d,
po
ult
ryli
tter
80
49
–57
40
–65
7.1
5–
7.3
81
7.6
–2
6.1
Vak
ili
etal
.(2
01
2a,
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19
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EF
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ted
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ME
60
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arud
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00
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8.
EF
B,
pal
moil
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00
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54
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75
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chu
char
dt
etal
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00
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11
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alm
pre
ssfi
ber
56
70
65
7–
82
6T
ham
bir
ajah
and
Ku
thu
buth
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(19
89)
Pal
mp
ress
fib
er,
po
ult
ryla
yer
dee
pli
tter
,u
rea
56
70
65
7–
81
7
Pal
mp
ress
fib
er,
po
ult
ryb
roil
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rli
tter
,u
rea
56
72
65
7–
81
6
12
.O
ilp
alm
was
tes
(EF
B,
fro
nd
,tr
un
k),
sew
age
slu
dg
e8
42
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–4
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60
5.8
–6
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9–
41
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ala
etal
.(2
00
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man
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ceb
ran
21
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r(2
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ton
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ante
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ke
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7
Pal
mo
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gas
slu
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ches
,dec
ante
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49
50
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91
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7
15
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cake,
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anu
re4
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ola
de
etal
.(2
00
5)
M. Vakili et al.
123
Ta
ble
2co
nti
nued
S.
no
.M
ater
ial
Tim
e(d
ay)
Max
imu
mT
emp
erat
ure
(�C
)M
ois
ture
(%)
pH
(fin
al)
C/N
(fin
al)
Ref
eren
ce
Pal
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ke,
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at/s
hee
pm
anu
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1
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ge
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(20
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oca
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75
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75
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ken
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ure
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75
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18
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Sti
chno
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and
Sch
uch
ard
t(2
01
0)
A review on composting of oil palm biomass
123
produced in an oil palm mill is 20 % of the daily capacity of the mills, or about 100 metric
tons of FFB per day (Singh et al. 2010; Mohammad et al. 2012). In the past, these wastes
were burned to generate the heat in mills or used in fields, thereby causing some envi-
ronmental problems (Igwe and Onyegbado 2007). Composting is a feasible way to convert
them to a valuable, manageable and environmentally friendly product. Numerous
researchers are currently conducting assays to use these wastes in composting.
Microbiological and biochemical variations during the composting of EFB were ana-
lyzed by Thambirajah et al. (1995). EFB was composted by adding goat dung, cow dung,
and chicken manure as a supplement in four different treatments. The initial C/N ratios in
all of the treatments decreased during the composting process, 60 days, and producing the
stable mature compost. The temperature increased to 70 �C at the beginning of the process
and remained constant for 3 days. During the process, mesophilic and thermophilic bac-
teria were active, whereas fungal activity was decreased within the peak heating period.
Yahya et al. (2010) investigated the composting of EFB and decanter cake (DC) slurry
by adding POME under an ordered turning operation. They found that the rate of the EFB
composting process increased by adding a DC slurry. After a composting period of
51 days, the compost (EFB and DC slurry) was matured and contain 46.4 % nitrogen,
17.9 % phosphorus, 17.7 % potassium, and 23.1 % calcium compared with compost
without a DC. Baharuddin et al. (2009a, b) found out that the co-composting of EFB with a
slightly treated POME is a useful method to change these materials to suitable mature
compost and is effective in oil palm farms as a fertilizer. At 3 days of the period, the
temperature reached 58.5 �C and eradicated the pathogens. The moisture and C/N ratio
decreased from 65 to 75 % to approximately 60 % and 45–12 at the end of the process,
respectively. The mature compost contained very low levels of heavy metals and a sig-
nificant rate of nutrients, such as carbon, nitrogen, phosphorus, potassium, calcium,
magnesium, sulfur, and iron.
POME, a non-toxic liquid waste discharged from an oil palm mill comprises approxi-
mately 95–96 % water, 0.6–0.7 % oil, and 4–5 % total solids that are mostly residue of the
fruit. POME contains high levels of pollutants and harmful properties that threaten the
environment, such as soluble chemical materials, high levels of biochemical oxygen
demand, and chemical oxygen demand (Yacob et al. 2006; Alam et al. 2007; Mumtaz et al.
2010; Hassan et al. 2013). Therefore, the discharge of POME on the surrounding envi-
ronment causes environmental pollution to a certain degree. Considering the biological
properties of composting in nature, composting can be an appropriate management method
for this waste (Rupani et al. 2010). Wood et al. (1979) reported that the use of POME as a
fertilizer was senseless because it destroys vegetation, causes compression, and reduces the
permeability and water logging of the soil, thereby resulting in an anaerobic condition.
This issue can be resolved by using the proper amount of POME. Oviasogie and Aghimien
(2003) also revealed that the suitable use of POME is useful for the environment and
improves the soil fertility. The results indicated that the use of POME likely leads to the
enrichment of the soil in terms of some elements, such as phosphorus, nitrogen, calcium,
magnesium, sodium, and potassium. Copper, iron, and lead are present in organic forms,
whereas zinc is present in an exchangeable form.
Nwoko and Ogunyemi (2010) reconfirmed that the POME is a low-cost resource of
nutrients for plants. The use of POME as an organic fertilizer can promote a sustainable
agriculture considering that the maize crop production possibly improves. Yaser et al.
(2007) assessed the efficiency of POME composting as a fertilizer for growing Cymbo-
pogun citratus, a Malaysian herbal plant, by adding sawdust to produce the compost. The
composting process was conducted in a natural aerated reactor. During the process, the
M. Vakili et al.
123
temperature in the reactor was increased to 40 �C. The pH and C/N ratio were reduced
from 7.5 to 5.7 and 25 to 19.25, respectively. The proportion of the organic matter losses
was 50 % at 300 days during the composting period. The produced compost was combined
with 70 % sandy soil to achieve the best result for the growth of C. citratus.
Baharuddin et al. (2010) carried out the composting of pressed-shredded EFB with
POME anaerobic sludge under controlled conditions. The microbial seeding, high levels
of nitrogen and nutrients sources from POME anaerobic sludge, increased the rate of the
composting process and reduced the composting period to 40 days. During the com-
posting process, the temperature increased to 60–67 �C (thermophilic phase). The curing
phase was then observed after the fourth week. The high biodegradation rate of the
microbial activity decreased because of the reduction of the moisture content
(64.5–52.0 %), C/N ratio (45.6–12.4), pH, 8.56–8.12, cellulose (34.0 %), and hemicel-
lulose (27.0 %) during the process. Moreover, the mature compost contained a low level
of heavy metals and a high amount of nutrients. Kabashi et al. (2007) examined the
composting of EFB and POME with wheat flour as a co-substrate in a tray bioreactor.
Some strains derived from the POME, such as Phanerochaete chrysosporium, Tricho-
derma harzianum, Aspergillus niger (A 106, S 101), and Penicillium, were used in this
process. The change in pH during the composting process was not very significant at the
range of 5–6. The organic matter percentage, germination index, and C/N ratio decreased
to 3 %, 95 %, and 17, respectively, whereas the total nitrogen content increased from
0.744 to 2.96 g/g.
There is a growing interest to use of other produced biomasses in oil palm industry such
as palm oil fronds, mesocarp fiber, trunk, and kernel cake are a suitable resource as a raw
material for composting. Ahmad et al. (2011a, b) investigated the physicochemical changes
and microbial population within the co-composting of OPF with a POME anaerobic
sludge. The results indicated that the microbial activities and the number of thermophilic
and mesophilic microorganisms changed by varying the temperature during the com-
posting process of 60 days. The temperature increased within the range of 50–56 �C in the
first 6 weeks of the composting period. However, the moisture content, oxygen level, and
pH increased from 60–70 %, 2–12 %, and 7.9–8.5, respectively. The C/N ratio decreased
from 64 to 18 after the composting period. The final mature compost contained 1.8 %
nitrogen, 0.1 % phosphorous, 0.9 % potassium, and a low level of heavy metal.
Lim et al. (2009) assessed the physicochemical changes of the oil palm mesocarp fiber
(OPMF) and POME anaerobic sludge composting with a pilot scale. The temperature
during the first week increased to 68 �C and maintained within the range of 50–68 �C in
the first 40 days of the composting process because of the addition of the POME anaerobic
sludge as a nutrient source. The moisture content decreased to about 50 % and the C/N
ratio decreased from 78 to 12.6 during the composting process of 50 days. The pH value
remained stable within the range of 6.8–7.8 during the whole process. The results indicated
that the produced compost had low heavy metal content and had the acceptable properties
of mature compost that can be used as a fertilizer or for soil improvement. Erwan et al.
(2012) evaluated the physicochemical and biological changes within the composting
process of OPF. Raw materials (OPF, chicken manure, and rice bran) were mixed in three
piles, A, B, and C, in different ratios of 40:40:20, 40:30:30, and 40:20:40, respectively. The
results indicated that 21 days after starting the process, the compost produced in Pile A was
matured and adequately contained the highest amounts of nitrogen, phosphorus, and
potassium with the lowest C/N ratios of 2.33, 2.02, 1.80, and 15.79, respectively. Nut-
ongkaew et al. (2011) analyzed the compost production from an oil palm mill sludge
(POMS) mixed with oil palm mill wastes and biogas effluent. The EFB’s total organic
A review on composting of oil palm biomass
123
carbon was 52.83 % dry weight, and the total nitrogen of the POMS and DC was 3.6 and
2.37 % dry weights, respectively. Moreover, the oil palm fuel ash had high amounts of
phosphorus and potassium of 2.17 and 1.93 % dry weight, respectively. During the
composting process of 60 days, the pH value was stable in the range of 6.9–7.8, whereas
the moisture content reduced to 30 % at the end of the period. The composting mixture
with a POMS/PEFB/DC ratio of 0.5:0.25:0.25 were found. The addition of the biogas
effluent represented the best properties of the compost, in which 31.75 % higher nitrogen
content obtained compared with the other treatments. The amounts of nitrogen, 3.26 %,
and phosphorous, 0.84 %, were more than the level necessary for a plant fertilizer (0.5 %
nitrogen, 0.5 % phosphorus).
Nahrul Hayawin et al. (2010) studied the physicochemical changes of an oil palm biomass
during vermicomposting. The data indicated that vermicomposting of an oil palm biomass,
such as EFB, OPT, and OPF, is an appropriate method for recycling the oil palm wastes to a
value-added vermicompost. The total organic carbon, C/N ratio, and pH value were reduced
during the process, whereas the nitrogen, phosphorous, and potassium proportions increased.
In addition, the heavy metal level increased, but the increase was not beyond the nutrient
range in the vermicompost. Thambirajah and Kuthubutheen (1989) studied the potentiality of
PPF for composting. The raw materials were mixed in three heaps with different ratios: The
first heap only contained PPT, 250 kg; the second heap contained 250 kg PPF, 50 kg poultry
layer deep litter, 0.5 kg urea, and 250 kg PPF; and the third heap contained 50 kg poultry
broiler floor litter and 0.5 kg urea. The temperature in all the heaps increased to 60–70 �C in
the first 3 weeks and then decreased to 30–40 �C at the end of the composting time of
8 weeks. The thermophilic to mesophilic fungi ratio increased in the composting time,
whereas the mesophilic bacteria ratio was stable in all the heaps. The cellulose and carbon
were reduced after composting because of the increase in the nitrogen, lignin, and ash level.
The C/N ratios in all the heaps decreased from their initial amounts of 40:1, 33:1, and 26:1 to
26:1, 17:1, and 16:1, respectively.
Kolade et al. (2005) carried out the composting of PKC with goat manure and poultry
droppings as nitrogen supplements. The composting process was started by mixing the
PKC with the poultry manure and goat/sheep manure in two treatments with a ratio of 3:1.
The temperature increased in both treatments from about 30 to 58 �C at 12 days and to
64 �C at 9 days for the composting time of 42 days. The produced compost was assessed
for crop production, resulting in an acceptable product as a fertilizer. This method indi-
cated the ability of decreasing the environmental health problems caused by the current
method of dealing with palm kernel wastes. Kala et al. (2009) investigated the best ratio of
mixing the raw material, oil palm wastes, and sewage sludge. The investigation was
conducted in a greenhouse made of glass by using a polystyrene box to produce the mature
compost, utilized as a potting media in horticulture. The oil palm wastes, EFB, frond, and
trunk, were shredded and mixed with sewage sludge in three ratios of 1:0, 3:1, and 4:1. In
this experiment, the best ratio was 4:1, producing the most favorable result as a medium for
ornamental plants because of its proper texture as a potting media, pH of 6.2, low C/N ratio
of 19, and high levels of nutrients of 2.05 % nitrogen, 0.640 % phosphorus, 1.39 %
potassium, 0.705 % calcium, 0.229 % magnesium.
5 Environmental impacts of composting
Composting is an appropriate, cost effective, and simple method, using for treating organic
wastes, which is able to reduce the volume of wastes, destroys weed seeds, and pathogens,
M. Vakili et al.
123
and stabilizes the nutrients, mature organic matter, produce usable environmentally
friendly final product (Jiang et al. 2011; Rynk et al. 1992). The use of mature compost,
produced from organic wastes, as a fertilizer, is much cheaper than the chemical fertilizers
produced in the industry. The use of chemical fertilizers cause to reduce the production
time for a mean time while in the long run showed bad impacts on soil, water, and air as
well as ecosystem. Unsuitable and continuous usage of them leads to damage the soil
structure, decreases in the organic materials, and finally reduces the soil aggregation
strength, which restricted the productivity of field crops. Farmers are interested to use
chemical fertilizers and pesticides rather than organic fertilizers due to the easily accessible
and rapid growth response for plants; however, using organic fertilizers is useful to
improve the physical, chemical, and biological qualities of soil (Ghoneim 2008; Hellal
2007). It also improves the soil water holding capacity and provides better tilts. It has been
reported utilization of compost is no longer limited to its use as a soil amendment and can
use as a suppressor agent for different crop diseases (Ruggieri et al. 2009). At present, the
compost is applied in control of erosion on highways, the purging of contaminants in storm
water runoff, and in the reduction of soils contaminants such as heavy metals and toxic
organic compounds. Nowadays, global warming is seen as a major problem around the
world and composting could play an important role to eliminate this problem; since the
decomposition of organic wastes in anaerobic condition such as landfill generates methane
gas as a major product which has numerous unfavorable impact on global warming, while
this process in composting produces CO2 (Mohammad et al. 2012).
6 Conclusions
This article has summarized and discussed the composting studies on palm oil biomass
so far in order to address problems associated with waste management of biomass
generated in palm oil industries. Composting is defined as an aerobic biological process
in which microorganisms convert organic materials into a stable environmentally
friendly product, similar to that which naturally occurs in the soil. The palm oil industry
produces large quantities of biomass in different forms, such as PPF, kernel shells, EFB,
OPF, OPT, OPB, PKC, and liquid waste discharged from palm oil mills. These wastes
could have diverse impact on the environment if not managed appropriately; for
instance, EFB needs long time to decay and POME affects the environment by polluting
the ground water and decreasing the soil fertility. However, they may be a potential
resource and value-added product if they are treated and managed properly. Considering
that these wastes are biological, which contain high levels of organic content they could
be a suitable resource and value-added byproduct. Hence, oil palm biomasses’ com-
posting is a suitable option to reduce the volume of the waste and often to make it more
useable than in its original form which is regarded by several researchers. In addition,
the maturity of compost is essential in achieving the beneficial uses. Even though a large
number of studies have been performed in this area, considering enormous amount of
biomass generated annually, still there is a lot of gaps in this area which could be
covered by other researchers.
Acknowledgments The authors acknowledge the research grant provided by Universiti Sains Malaysiaunder the Short Term Grant Scheme (Project No. 304/PTEKIND/6312118).
A review on composting of oil palm biomass
123
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