CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 52, 2016 

A publication of 

 

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

Guest Editors: Petar Sabev Varbanov, Peng-Yen Liew, Jun-Yow Yong, Jiří Jaromír Klemeš, Hon Loong Lam 
Copyright © 2016, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-42-6; ISSN 2283-9216 
 

Potential of Biomass to Resource as An Action to Mitigate 

Transboundary Haze In ASEAN Country 

Sie Ting Tana, Haslenda Hashima*, Ahmad H. Abdul Rashidb, Esther K. Y. Wongc, 

Jeng Shiun Lima, Wai Shin Hoa, Abu Bakar Jaafard 

aProcess System Engineering Centre (PROSPECT), Research Institute for Sustainable Environment (RISE), Universiti 

Teknologi Malaysia, Johor, Malaysia 
bIndustrial Biotechnology Research Centre, SIRIM Berhad, Shah Alam, Malaysia 
cSTI Strategic Studies Division, Academy of Sciences Malaysia 
dOcean Thermal Energy Development Centre, Institute of Future Energy, Universiti Teknologi Malaysia, Johor, Malaysia 

haslenda@cheme.utm.my 

Transboundary haze is one of the major environmental issues in Southeast Asia for the last three decades. 

The haze has not only affected the countries within the region but even beyond because of the impacts on 

environmental concerns with greenhouse gas (GHG) emissions and biodiversity thus challenging international 

attempts to address these issues. Land clearing and burning activity is a significant contributor to smoke in the 

atmosphere during the haze season.This study aims to investigate the economic benefits through conversion 

of forest biomass and palm biomass, the two main sources of peat fire to medium and  higher value products 

i.e power and bioethanol. The outcomes of this study will provide farmers and policy makers to view the 

biomass as a source of ‘wealth’, not ‘waste’.  

1. Introduction 

For decades, the countries of Southeast Asia, especially Singapore and Malaysia suffer from the attack of 

transboundary haze caused by forest fires and open burning in Indonesia. Most of the forest burning 

happened on the Sumatra Island and Kalimantan province in Indonesia, and some remote area in Sabah and 

Sarawak in Malaysia. The small and medium enterprise and local farmers practice open burning of the 

surrounding forests and biomass of pulp, paper, and palm oil plantations to clear space for expansion. The 
condition of uncontrolled forest fires getting worse with the dry weather of El Nino climate phenomenon and 

carbon-rich peatlands. Smoke is carried by monsoonal winds most frequently spread to Malaysia, Singapore, 

the south of Thailand and the Philipines, causing a significant deterioration in air quality of those countries. In 

2002, all 10 South East Asian countries signed an agreement to combat the issue through greater monitoring 

and encouragement of sustainable development, but efforts carried out by the governance have been limited. 

Given the environmental damage and human health risks, these fires need to stop immediately. One solution 

to clearing the biomass without fire may be to harvest it and use it for value-added resources.  

The rationale is that the creation of value for the burnt biomass shall provide the impetus to consider the 

biomass as a source of wealth to be translated into a sustainable practice of economic harvesting. Therefore, 

the paper first provides an introduction to biomass, their availability in ASEAN and the potential of biomass to 

value-added resources. It is followed by an comprehensive review on the scientific studies and research on 

the biomass conversion to various resources, including power and bioethanol This paper then discusses the 

two potential technologies of converting biomass into heat and power as well as bioethanol as one of the 

promising strategies to mitigate the transboundary haze pollution encountered by the ASEAN countries in 

recent years. Case studies with economic analysis are also presented for possible extension into detailed 

studies later.  

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1652195 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Tan S. T., Hashim H., Abdul Rashid A. H., Wong E. K. Y., Lim J. S., Ho W. S., Jaafar A. B., 2016, Potential of 
biomass to resource as an action to mitigate transboundary haze in asean country, Chemical Engineering Transactions, 52, 1165-1170  
DOI:10.3303/CET1652195   

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2. Potential of biomass to resources 

Biomass refers to any organic, decomposable matter derived from plants or animals available on a renewable 

basis. Biomass residues that generated in the forests, fields or plantations are the major contributor to forest 

fire which caused haze in Southeast ASEAN. These residues are abundant and in dry seasons become very 

dry with high potential of catching fires from very small flames or even burning ambers like cigarette butts that 

could lead to raging fires and massive haze. On the other hand, Sumatra and Kalimantan possess large areas 

of peat forest, which is highly combustible during dry season. Therefore, the problem is further compounded in 

peat forests where a lot of biomass exists underground and once fire starts, it becomes very difficult to control. 

In this study, we focus on the utilisation of biomass generation in plantation, specifically the oil palm plantation 

biomass. 

2.1 Oil palm plantation biomass 

Oil palm is one of the world's most rapidly expanding equatorial crops. Approximately 85 % of world’s crude oil 

palm is supplied by Malaysia and Indonesia (Sulaiman et al., 2011). Malaysia has approximately 5 million ha 

of palm oil plantation in year 2011, covered a 15 % of total land area (MPOB, 2014). The oil palm has a 

lifespan about 200 years with the economic life up to 25 years. Peak crop yields are achieved from the age of 

9-18, and gradually decline thereafter. Conventionally, a felled oil palm tree, consisting of a large amount of 

trunk and frond, are often shredded and buried in the field to be turned into organic fertiliser. Nevertheless, 

due to the cost constraints, some small and private estate holders practise open burning to clear the land, as it 

is the cheapest mean for land clearing. There are some utilisations of trunks and fronds as source material for 

plywood production but its uptake is not consistent due to uncertain economic values of the raw materials 

primarily due to logistic cost. At the time of reporting, it is estimated that 65 % of Malaysia’s total oil palm trees 

ranged between the age of 9 - 20 years, while another 26 % is approaching the end of yielding age of 20 - 28 

years old (MPOB, 2014). Approximately 1.3 million ha of Malaysia’s oil palm plantation is at the felling age. A 

felled oil palm tree consists of 70 % of trunk, 20.5 % of frond, 6.53 % of leaflets and 5.03 % of others, as 

shown in Table 1 (Khalid et al., 1999). Based on the statistical data of old oil palm plantation area, it is 

estimated that 109 million t of biomass can be obtained from Malaysia old oil palm plantation, with 53.39 

million t of trunk, 20.80 million t of frond, and others.  

Table 1: Composition of an old oil palm tree (khalid et al., 1999) 

Biomass 

composition 

Average weight 

(kg) 

Weight percentage 

(%) 

Estimated dried 

weight (kg/tree) 

Dried weight (t/ha) 

Trunk 1,507.50 70.00 301.50 41.07 

Leaflets 145.00 6.53 58.00 7.69 

Frond 452.50 20.50 117.70 16.00 

Spears 42.75 1.92 9.40 1.28 

Cabbage 44.50 2.00 4.50 0.60 

Inflorescence 134.50 1.11 6.30 17.56 

Total weigh 2,217.50 100.00 497.30 84.20 

 

The chemical composition of the forest biomass and oil palm plantation biomass are shown in Table 2. Among 

the palm plantation biomass, the oil palm trunk (OPT) and oil palm frond (OPF) are the main focus for the 

comparison of biomass characteristic. The properties of empty fruit branch (EFB) are also presented in Table 

2 as the comparison with the other types of biomass. The properties of biomass are compared in the 

proximate analysis, ultimate analysis, and lignocellulosic content. In the proximate analysis, OPF is found to 

have the highest moisture content (16.00 %) as compared to the OPT and EFB. The ultimate analysis 

measured the elemental contents for carbon, hydrogen, oxygen, nitrogen and sulphur (C, H, O, N, S). It is 

valuable indicators to energy processes and gases emissions during combustion of the resource material. 

Comparisons were made with the elemental composition of the EFB, where the highest amount of H and N 

are found in 6.44 % and 2.18 % respectively. In term of the lignocellulosic content, EFB also has highest 

amount of cellulose (57.80 %), while similar lignin and hemicellulose content of each biomass. The higher 

heating value (HHV) of the biomass also compared, where EFB has the highest value of HHV with 20.54 

MJ/kg, while both trunk and frond has slightly lower HHV then the EFB, with 17.27 MJ/kg and 17.28 MJ/kg 

respectively 

 

 

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Table 2: Properties of oil palm plantation biomass versus empty fruit branch. 

 Oil Palm Plantation Biomass Empty Fruit Branch 

(EFB) b Oil Palm Trunk a, b Oil Palm Frond c,d 

Proximate analysis  (wt% dry basis) 

       Moisture content 8.34   16.00  4.68 

       Volatile matter 79.82  83.50 76.85 

       Fixed carbon 13.31  15.20 5.19 

       Ash 6.87  1.30 18.07 

Ultimate analysis (wt% dry basis) 

       C 40.64  44.58 46.36   

       H 5.09  4.53  6.44  

       O 53.12  48.80 38.91  

       N 2.15  0.71 2.18  

       S n.a 0.07 0.92 

Lignocellulosic content (wt% dry basis) 

      Cellulose 45.90  50.33  57.80 

      Hemicellulose 25.30 23.18 21.20 

      Lignin 18.10 21.7 22.80 

HHV (MJ/kg) 17.27  17.28  20.54 

a. Oil palm biomass (www.bfdic.com); b. Guangul et al., 2012 ; c. Abnisa et. al., 2011; d. Abdullah and Sulaiman, 2013 

 

2.2 Conversion pathway of biomass to products 

Conversion of biomass generated on the forest, fields or plantations could overcome the issue of haze that 

caused by forest fire.  In general, the approaches for transforming biomass resources to products and energy 

or biofuels involve thermochemical, biochemical, and physical conversion processes. The product derived 

from biomass can be categorised into three main types based on the economic value, namely the low value 

product, medium value product, and high value product. Low value products such as compost require very low 

investment cost and simple conversion technologies, but the product value is relatively low. Heat and power 

product from biomass are considered as medium value product while the biofuel and biochemical product 

require high investment cost and the product value is highest among the three categories.  

 

 

Figure 1: Conversion pathway of biomass to resources. 

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3. Case studies: Economic Potential of Biomass to Power and Bioethanol 

Conversion of biomass on the field in forest or plantation into value-added product such as power and 

bioethanol can potentially play a role in an effort to reduce the resulting haze conditions from slash and burn 

practices. There are competing uses for biomass resources because of their economic and environmental 

value for a variety of purposes. Biomass material can be potentially be used to generate power, heat, steam, 

and bioethanol, which potentially offer high economic returns to the farmers. 

To explore the economic potential of biomass-to-resources, two case studies on biomass-to-power and 

biomass-to-ethanol are incorporated in this section with the suggested feedstock capacity of 2,000 t of 

biomass daily. Net present value economic analysis with equity and debt corporate financing method are 

applied in the case studies to analyse the economic profitable levels of biomass-to-resources. 

3.1 Biomass to Power Generation 

Malaysia starts utilised biomass to power generation in year 2003, where a 7.5 MW integrated biomass co-

generation plant was established in Sahbat, Lahad Datu, Sabah by the Felda Global Ventures Holdings Bhd 

(FGV). The power plant used EFB as the feedstock, generate heat and power for demands within the 

company including the CPO refining , kernel crushing plant, hotel, office and residential. The project is the first 

Clean Development Mechanism (CDM) Project in Malaysia which is encouraged by the government to invest 

R&D efforts and to study the feasibility of applying the model throughout the country's industrial sector. With 

the investment cost of 38 million MYR, the biomass power plant is successful reduced 377,902 t of CO2 

emission by end of 2012 (CDM, 2006). 

Most of the current application of biomass to power are focused in utilisation of EFB due to its high HHV 

content and abundant of feedstock from palm oil mill. Up to date, there is no utilisation of forest biomass or oil 

palm plantation biomass for power generation in Malaysia. Nevertheless, the forest and oil palm plantation 

biomass are proved to have similar HHV content as the EFB (20 MJ/kg compared to 17 MJ/kg) and thus   

could be a potential source of feedstock for power generation. 

This study presents the economic potential using 2,000 t/d forest and oil palm plantation biomass (OPF and 

OPT) as the feedstock for power generation with main focus on electricity production. The proposed 

technology is a 27 MW capacity direct combustion system with a 76 % efficiency comprising of a pre-

treatment drying system, fluidised bed boilers for conversion of biomass to heat and steam, and generation of 

electricity through extraction-condensing turbine. The biomass feedstock with an assumed calorific value of 

15.82 MJ/kg with 16 % moisture content (dry basis) (Fiseha et al., 2012). The direct combustion technology 

has a 30 years plant life with investment cost of 900 $/kW and 1,050 $/kW for boiler and turbine respectively. 

The costing information was obtained through personal interview with a local biomass-to-power industry 

stakeholder while the financing data are adopted from NREL report (Humbird et al., 2012). 

Using the net present value (NPV) economic analysis, the correlation between the minimum electricity 

production cost and the equity financing is presented in Figure 2 Minimum electricity product cost ranged from 

0.23 $/kWh to 0.19 $/kWh with variations of equity financing share of 30 % to 70 %. The minimum product 

cost is consider high even with the equity financing adoption as compared to the current feed-it-tariff (FiT) 

incentive of 0.10 $/kWh.  

As can be seen in Figure 2, there are only a marginal reduction in the minimum electricity price (ranged from 

0.24 $/kWh to 0.19 $/kWh) for different capacities (2,000 t/d, 1,000 t/d, and 500 t/d) due to economy-of scale 

capacity increment with high fixed investment cost (approximately 3,000 $/kW). It was found that the low FiT 

scheme renders the biomass-to-power to be less competitive at the current power industry market.  

 

 
Figure 2: Breakeven of electricity selling price for biomass-to-power in Malaysian context. 

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3.2 Biomass to Bioethanol Generation 
Maximum valorization of biomass can be achieved through its conversion to biofuels such as ethanol. The 

conversion of lignocellulosic biomass to biofuels and biochemical follow similar routes consisting of pre-

treatment, hydrolysis, microbial conversion followed by purification. While the process of conversion to 

biofuels in the form of bioethanol has been commercially established, the processes for conversion to other 

biofuels such as butanol and biochemical are not commercially available at the present time. There are a 

number of processes in the pilot or pre-commercialisation stage all over the world (Becker et.al., 2015) and it 

is predicted that commercialisation of a few biochemical processes will happen in the next 5 years. Within this 

scenario, this report will focus on describing the process involved in the production of bioethanol as well as its 

economic evaluation in the Malaysian context to serve as a first estimate for a more rigorous evaluation.  

The case study for biomass to bioethanol presents the economic potential using 2,000 t/d biomass as the 

feedstock. The proposed technology is enzymatic hydrolysis followed by fermentation  with the cellulosics 

content in biomass of 70 % and conversion yield of the cellulosics to C5 and C6 sugar of 95 %. The 

fermentation process is using high substrate tolerant recombinant yeast capable of converting 30 % 

fermentable C5 and C6 sugars to 15 % ethanol. The technology has a 30 years plant life with the total 

capacity cost of $ 1,094,065,600.00. The major variable cost is assumed to be the enzyme cost of about 0.6 

$/gal of ethanol.  

 

 

Figure 3: Breakeven of ethanol selling price for biomass-to-ethanol in Malaysian context. 

Table 3: Ethanol production cost ($/L) reduction by improving the debt: equity ratio or interest rate 

Debt:Equity ratio  Interest Rate 

8 % 5 % 3 % 

95:5  0.77 0.61 0.52 
70:30  0.73 0.60 0.53 
60:40  0.71 (0.57a) 0.60 0.53 
50:50  0.69 0.60 0.54 
40:60  0.67 0.59 (0.52ᵇ) 0.54 
ᵃUS NREL (2011) ᵇAdapted from US NREL analysis 

Using the net present value (NPV) economic analysis, the correlation between the ethanol production cost and 

equity financing is presented in Figure 3. For a production capacity of 2,000 t/d, the production cost ranged 

from 0.64 $/L to 0.62 $/L with the movement of equity financing share from 30 % to 70 % which is higher than 

the current market ethanol price of 0.58 $/L.  

Figure 3 also shows the variation of ethanol production cost at different capacities and with variation in 

enzyme costs. The plot demonstrates that economic viability from lower ethanol production cost can be 

achieved at favourable equity financing ratios, higher capacities (due to economy of scale) and lower enzyme 

costs.  

Table 3 presents the potential of ethanol production cost reduction by improving the debt: equity (D:E) ratio or 

interest rate. It is shown that at the interest rate of 3 %, the ethanol production cost could be reduced 

significantly and make it competitive to current market value. 

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4. Conclusion 

The two case studies presented in this study reveal the economic potential of conversion of biomass-to-power 

and ethanol in current market. For biomass-to-power, the current FiTscheme is relatively lower than the 

electricity production cost, rendering the biomass-to-power option less attrative to investors. The rate of FiT 

scheme in Malaysia was established in year 2011, and is considered not up-to-date on current renewable 

resources market as various RE resources have been more economically competitative in recent years. In 

order to promote the utilisation of biomass to power, the current Fit should be reviewed and revised. 

The case study of biomass to ethanol, on the other hand, demonstrates a favourable scenario to the investors. 

As discussed, with a financial interest rate of 3 %, ethanol production is economically competitive in the 

current market. Nevertheless, the current interest rate stands at the rate of 5 % - 8 % and with high cost of 

enzyme in Malaysia, there needs to be some policy and technology intervention to enablea sustainable 

bioethanol industry in Malaysia. The problem is further compounded when the investments is undertaken 

through acquisition of bank loans thus increasing the operational cost from interest payment. It is proposed 

that there is a significant funding involvement from the government converted to equity to minimise the interest 

charges from massive loans. The equity-loan ratio needs to be optimised to maximise margins on sale of 

ethanol from a financial evaluation.  

Acknowledgments  

The study is sponsored and support by the Academy of Science Malaysia under the study of “Transboundary 

Haze Study: Help Action Toward Zero Emissions”. 

Reference 

Abdullah N., Sulaiman F., 2013, The Properties of the Washed Empty Fruit Bunches of Oil Palm, Journal of 

Physical Science, 24(2), 117–137. 

Abnisa F., Daud W.M.W., Husin W.N.W., Sahu J.N., 2011, Utilization Possibilities of Palm Shell as a Source 

of Biomass Energy In Malaysia by Producing Bio-oil in Pyrolysis Process, Biomass and Bioenergy, 35(5), 

1863–1872.  

Becker J., Lange A., Fabarius J., Wittmann C., 2015, Top value platform biochemical: biobased production of 

organic acids, Current opinions in biotechnology, 36, 168-175. 

Clean Developemnt Mechanism (CDM), 2006, Simplied Project Design Document for small-scale project 

activities - Sahabat Empty Fruit Bunch Biomass Project February 2006. 

Fiseha M.G, Shaharin A.S, , Anita R., 2012, Gasifier selection, design and gasification of oil palm fronds with 

preheated and unheated gasifying air, Bioresource Technology, 126, 224-232. 

Guangul F.M., Sulaiman S.A., Ramli, A, 2012, Gasifier Selection, Design and Gasification of Oil Palm Fronds 

with Preheated and Unheated Gasifying Air, Bioresour Technol, 122, 224–232.  

Humbird D., Davis R., Tao K., Kincin C., Hsu D., Aden A., Schoen P., Lukas L., Olthof B., Worley M., Sexton  

D., Dudgeon D., 2011, Process Design and economics for Biochemical Conversion of Lignocellulosic 

Biomass to ethanol, National Renewable Energy Lab (NREL)  technical report. 

Khalid H., Zin Z.Z., Anderson J.M., 1999. Quantification of oil palm biomass and nutrient value in a mature 

plantation; above-ground biomass, Journal of Oil Palm Research, 2, 23 – 32. 

Malaysia Palm Oil Board (MPOB), 2014, Malaysian Oil Palm Statistics. 

Sulaiman F., Abdullah N., Gerhauser H., Shariff A., 2011, An outlook of Malaysia energy, oil palm industry and 

its utilisation of waste as useful resource, Biomass and Bioenergy, 35, 3775-3786. 

 

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