Utilization of Agro-Industrial Residues and Municipal Waste of Plant Origin for Cellulosic Ethanol Production

doi:10.4236/jep.2011.210150

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Journal of Environmental Protection, 2011, 2, 1303-1309

doi :1 0.4236/ jep.2011. 210150 Published Online December 2011 (http://www.SciRP.org/journal/jep)

1303

Utilization of Agro-Industrial Residues and

Municipal Waste of Plant Origin for Cellulosic

Ethanol Production

Fabiano Avelino Gonçalves1,3, Eliana Janet Sanjinez-Argandoña2, Gustavo Graciano Fonseca1*

1Laboratory of Bioengineering, Faculty of Engineering, Federal University of Grande Dourados, Dourados, Brazil; 2Laboratory of

Food Technology, Faculty of Engineering, Federal University of Grande Dourados, Dourados, Brazil; 3Laboratory of Chemical En-

gineering, Faculty of Engineering, Federal University of Rio Grande do Norte, Natal, Brazil.

E-mail: *ggf@ufgd.edu.br

Received S eptember 3rd, 2011; revised October 5th, 2011; accepted November 6th, 2011.

ABSTRACT

Today’s search for alternative sources of energy to reduce the use of fossil fuels is motivated by environmental, socio-

economic and political reasons. The use of agro-industrial and municipal wastes of plant origin for ethanol production

appears to be the best option to solve the dilemma of using food sources to produce biofuels, since it adds value to these

wastes in eco-efficient processes. This paper highlights the potential of agro-industrial and municipal wastes for cellu-

losic ethanol production.

Keywords: Bioethanol, Agro-Industrial Byproducts, Environmental Preservation, Eco-Efficiency

1. Introduction

The interest in alternative sources of energy from plant

biomass to replace the dwindling reserves of fossil fuel

and petroleum derivatives has been influenced by the

constant increase in world crude oil prices. This was evi-

denced as recently as early 2011, when uncertainties in

the political situation of some countries in the Middle

East and North Africa drove the price of crude oil to over

US$ 120 per barrel on the London Stock Exchange [1].

Moreover, the combustion of petrochemical fuels has

influenced climate change and aggravated global warming,

mainly due the emission of greenhouse gases (GHG). At-

tempts to mitigate environmental impacts have led to the

search for renewable and clean sources of energy. These

sources include sugarcane ethanol and corn starch etha-

nol, which represent alternatives to overcome economic

problems and environmental impacts.

However, in some countries, the sharp increase in the

production of ethanol from starch may lead to controver-

sies regarding the use of this raw material for biofuel or

food production, not to mention the high demand for

tillable land and agricultural inputs [2]. In this context, an

alternative to starch and sucrose-based biofuels has been

the production of ethanol from plant biomass (cellulosic

ethanol) derived from agro-industrial wastes [2-5] and mu-

nicipal waste [2,6-10]. The conversion of cellulose into

fermentable sugars for ethanol production is a prom-

ising alternative to meet the global demand for biofuels.

This paper offers a review of the available sources of

plant biomass used for the production of cellulosic etha-

nol, and the environmental, socioeconomic and political

policies involved in cellulosic ethanol production.

2. Plant Biomass

Plant biomass, the most abundant source of organic mat-

ter on earth, is biodegradable and renewable [5]. This bio-

mass is found in forests, agro-industrial residues and mu-

nici p al wa s te [ 1 1 ] , and is a potential source of material for

the production of ethanol [2], which can replace gasoline

du e to its hig h energy ef ficiency [5 ] .

The structure of plant cell walls consists of polysac-

charides, prote ins, phenolic compound s and minerals. Pol y-

saccharides, which represent about 90% of the dry weight

of the cell wall, consist of cellulose (20% - 40%), hemi-

cellulose (15% - 25%) and pectin (30%), while lignin, a

non-polysaccharide, gives the cell wall its rigidi ty [12].

Cellulose, the main constituent of plants [13], is a lin-

ear homopolysaccharide with 8000 - 12000 glucose units

linked by 1,4-beta-glycosidic bonds. Hemicellulose is a

complex heteropolysaccharide composed of glucose, ga-

Utilization of Agro-Industrial Residues and Municipal Waste of Plant Origin for Cellulosic Ethanol Production 1304

lactose, mannose, xylose, arab inose, uronic acids a nd ace-

tyl groups. The branched chain presents a degree of po-

lymerization of less than 200 units [14]. Pectin is a com-

plex heteropolysaccharide constituted of axial connec-

tions of α-1,4-D-galacturonic acid units composed of ra-

mose, arabinose and galactose [15]. Lignin is a phenol-

lic polymer that contributes to the structural rigidity of

plant tissues [12]. It is composed of macromolecules syn-

thesized by radicals from three p-hydroxycinnamic pre-

cursor alcohols: p-coumaryl, coniferyl and sinapyl [14].

Glucose molecules are joined by glycosidic bonds to

form linear chains (cellulose) that interact with each other

through hydrogen bonds, forming a structure of elemen-

tary fibrils that are water-insoluble and highly crystalline.

Four elementary fibrils are gro uped in a hemicell u lose mo-

nolayer, surrounded by a hemicellulose and lignin matrix,

called cellulose microfibrils [14,16, 17].

Lignocellulosic material is a generic term that de-

scribes the main constituents of plants, i.e., cellulose, he-

micellulose and lignin [18], as indicated in Figure 1. Its

composition depends not only on the type of plant (Table

1), but also on the selected part of the plant [19], and on

growth conditions [20,21]. This material differs from pro-

ducts with high sugar and s tarch content [5,22-24].

3. Global Scenario

Global ethanol production is monopolized by two major

producers, the USA, which uses corn starch, and Brazil,

which uses sugarcane sucrose [25]. In both cases, this

production is based on food sources. According to Pi-

mentel et al. [26], the allocation of food sources for the

production of biofuels reaches a critical point when an

impasse is reached between the production of raw mate-

rial for fuel ethanol or for food. This impasse represents a

bottleneck in the maintenance and expansion of the bio-

fuels market. One of the short-term alternatives would be

to use these plants solely for food and use only their lig-

nocellulosic materials for the production of ethanol. This

would help mitigate environmental pollution and mini-

mize the use of food sources for ethanol production [10].

Based on this idea, the Chines e government e ncourages

the production of ethanol only from non-food substrates,

e.g., perennial grasses, and plant husks and chaff [27],

and strictly controls the territorial expansion of food sub-

strates used in ethanol production [28]. Currently, China

Table 1. Cellul ose, he micellulose and lig nin contents of some

agro-industrial and urban res idues o f plant or igin.

Compound (%)

Plan t bi o mass Cellulose Hemicellulose Lignin

Sugarcane bagasse 33 30 29

Wheat straw 30 24 18

Sorghum straw 33 18 15

Rice straw 32 24 13

Oat straw 41 16 11

Maize ear 42 39 14

Maize stalk 35 15 19

Barley straw 40 20 15

Alfalfa stalk 48.5 6.5 16.6

Rice hu s k 36 15 19

Eucalyptus grandis 38 13 37

Eucalyptus saligna 45 12 25

Pinus sp . 44 26 29

Journal 61 16 21

Processed paper 47 25 12

Angiosperm wood 40 - 50 24 - 40 18 - 25

Gymnosperm wood 45 - 50 25 - 35 20 - 30

Nuts husk 25 - 30 25 - 30 30 - 40

White paper 85 - 99 0 0 - 15

Grasses 25 - 40 35 - 50 19 - 25

Leafs 15 - 20 80 - 85 0

Cottonseed lint 80 - 90 0 - 15 0

Sourc e : [ 2 9-34].

Figure 1. Structural chains of lig nocellulosic materials.

Utilization of Agro-Industrial Residues and Municipal Waste of Plant Origin for Cellulosic Ethanol Production1305

is the world’s largest rice and wheat producer. The coun-

try generates huge amounts of agro-industrial residues,

which may be used alternatively for ethanol production

instead of impacting the environment [35,36].

Brazil’s sugarcane production seeks to meet domestic

and export market demands for ethanol and sugar. How-

ever, this economic dependence has serious negative con-

sequences for the population. In early 2011, there was a

shortage of ethanol as a result of the higher demand for

sucrose for sugar production (due to rising sugar export

prices), allied to the sugarcane off-season, which resulted

in an average price increase of 20.5%.

Another prospect is ethanol production in Brazil driven

by the incorporation of sugarcane bagasse ethanol pro-

duced at the same industrial plant, resulting in lower pro-

duction costs. This proposal would increase the availabil-

ity of ethanol during the sugarcane off-season, and rep-

resent higher economic and ecological efficiencies in the

process. This concept is strengthened by data from Bra-

zil’s 2010/2011 sugarcane harvest. Although it was a

bumper crop, it did not suffice to meet the demand for

ethanol and sugar production. In the 2011 season, Bra-

zil’s sugarcane production volume will fall short of in-

dustrial demand by 23%. This volume is expected to be

approximately 632 million tons, while the volume needed

to meet current domestic and export demand is 775.6

million tons. The projections for 2020 are that Brazil’s

sugarcane production will fall 34% below demand, with

an estimated supply of 974 million tons to meet a de-

mand exceeding 1.3 billion tons [37].

All around the world, new alternatives are being in-

vestigated for the production of cellulosic ethanol based

on crops as the source of raw materials. These alterna-

tives include eucalyptus (Eucalyptus sp.) and leucaena

(Leucaena sp.) as well as fast-growing grasses of high

productivity, e.g., elephant-grass (Pennisetum purpureum),

used as forage in South America, switchgrass (Panicum

virgatum), a species native to North America, and tall

grass of the genus Miscanthus, which is of greater inter-

est in Europe [38]. Although cultivated plant biomass

represents an advance in cellulosic ethanol production,

agro-industrial residues and municipal waste of plant ori-

gin are priorities for use as substrates for cellulosic ethanol

production [30,39- 43].

4. Socioenvironmental, Economic and

Political Policies

Changes in the global energy matrix have been driven by

fuels derived from animal, plant and microbial organic

matter. The search for cheaper fuels in developing coun-

tries has fostered a growth in the economic activity of

biofuel production, facilitated by the fact that most of

these countries have large tracts of land, available water

supplies and favorable weather conditions, which may

lead to regional development (employment and income

generation, population devolution and an increase in for-

eign exchange reserves). However, it is important to un-

derline the need for strategic agricultural zoning studies

to avoid environmental and socioeconomic disasters pro-

moted by huge green deserts, as well as the use of biofu-

els as an extra energy supply and not merely to replace

non-renewable sources of energy.

Renewable sources of energy are desirable because

they represent a safe and sustainable energy supply, and

lower GHG emissions [3,44]. Ethanol production using

lignocellulosic biomass is one of the most important te-

chnologies for an ecologically feasible [45] and sus-

tainable production of renewable fuels [44,46-48] to mi-

nimize the environmental impact caused by GHG. The

six main GHGs are carbon dioxide, methane, nitrous oxide,

hydrofluorocarbons, perfluorocarbons and sulfur hexafluo-

ride [49]. The carbon dioxide produced by burning biofu-

els is partially recycled in the process of photosynthesis,

which is when plant biomass is formed [50,51]. Ethanol

has a positive carbon balance [52], and also releases low

amounts of nitrous oxide and sulfur dioxide during com-

bustion [53].

The use of municipal waste of plant origin as a sub-

strate for ethanol production can lead to a temporary in-

crease in organic compounds and toxic substances in the

environment [54]. However, this amount is small when

compared to that produced by liquid fossil fuels [55].

According to the Intergovernmental Panel on Climate

Change [49], climate change is caused by the excessive

increase of GHGs in the atmosphere, intensified by hu-

man activities, which is the case of fossil fuels that have

been in use since the pre-industrial a ge. Significant a mou-

nts of carbon dioxide are released into the atmosphere

annually. In 2002, about 24 billion metric tons of carbon

dioxide would be produced by burning fossil fuels. This

number is estimated to reach 33 billion by 2015 [51].

Studies on biofuel by Sukimaran et al. [56] demon-

strated that the potential of ethanol is comparable to that

of petroleum, making it economically feasible for com-

mercial purposes. Moreover, these authors emphasize

that the octane rating of ethanol is higher than that of

gasoline and that it produces lower air pollutant emis-

sions. In the 1990s, the Tennessee Valley Authority (USA)

developed an efficient technology for converting vegetable

waste into ethanol [57]. The material was composed of

45% glucose and 9% hemicellulose [2,58,59] and al-

lowed for the production of cellulosic e thanol. According

to Shi et al. [9], the use of municipal waste of plant ori-

gin for ethanol production is a promising strategy to sup-

ply the world’s energy needs and reduce GHG emissions.

Their estimates of the socioeconomic development of

Utilization of Agro-Industrial Residues and Municipal Waste of Plant Origin for Cellulosic Ethanol Production 1306

173 countries point to a global production of 82.9 billion

liters of ethanol fro m municipal waste, replacing the con-

sumption of 5.36% of gasoline.

In a comparison of the eco-efficiency of liquid fuels,

i.e., gasoline, corn starch ethanol and cellulosic ethanol,

Hill et al. [55] found that cellulosic ethanol is the most

eco-efficient. These authors reported the following costs

to produce 1 billion gallons of fuel: gasoline—US$ 416

million, corn starch ethanol—US$ 614 million, and cel-

lulosic ethanol—US$ 208 million. Figure 2 indicates the

time required to eliminate CO2 emissions produced by

deforestation, harvesting and production of some biofuels.

These findings emphasize the importance of producing

cellulosic ethanol, which not only adds value to plant

biomass for biofuel production but also requires no ex-

pansion of far ml and.

The International Energy Agency’s projections for the

global biofuel demand re veal a drastic growth in t he com-

ing decades, with a strong contribution from the road

transport sector up to 2030 [60]. The growing use of bio-

fuels is influenced mainly by the Montreal (1987), Kyoto

(1997) and Copenhagen (2009) Protocols. However, the

UN Climate Change Conference (COP-16) held in Mex-

ico in 2010 pointed to uncertainties for the second phase

of the Kyoto Protocol, which sets mandatory and volun-

tary targets for the reduction of global emission caps

(GEC) in industrialized countries. Nevertheless, there is a

tendency for a period without mandatory targets for en-

vironmental preservation from 2012. The increase in

bio fuel co nsu mpti on is in fl uenc ed b y volunt ar y and man-

datory targets adopted by some countries (Table 2). Ac-

cording to the World Energy Assessment [61] and Gol-

denberg [62], projections for the world energy scenario

up to 2100 are optimistic, with an increase in renewable

sources and the consequent reduction of non-renewable

sources [61].

Figure 2. Time required to eliminate carbon dioxide emissions caused by deforestation, harvesting and production of some

biofuels [ 63] .

Table 2. Voluntary an d mandatory biofuel targets of so me cou ntries.

Country Target Condition

Germany Addi tion of 6.75% of anhydr ous ethanol to ga soline in 2010; increas e to 8% in 2015 and 10% in 2020. Mandatory

Brazil Mixture of 20% to 25% of anhydr ous ethanol in gasoli ne and 5% of b iodiesel in diesel in 2010; expan-

sion of the use of hydrated ethanol. Mandatory

Canada Addi tion of 5% of an hydrous ethanol in gasoline in 2010; addi tion of 2% of b iodiesel in diesel in 2012. Manda tory

China Utilization of 15% of biofuels in the transport sector. Voluntary

France Addition of 7% of anhydrous ethanol in gasoline in 2010a and increa se to 10% in 2015b. aVoluntary and bmandatory

Italy Ad dition of 5.75 % of anhydrous ethanol in gasoline in 2010 and increas e to 10% in 201 0. Mandatory

European Union Utilization of 10% of biofuels in 2010. Mandatory

United Kingdom Utilization of 5% of biofuels in 2010. Mandatory

ource: [64].

Utilization of Agro-Industrial Residues and Municipal Waste of Plant Origin for Cellulosic Ethanol Production1307

5. Final Remarks

The environmental changes influenced by greenhouse

gas emissions and global warming, the rising prices of

crude oil and its derivatives, and the ever growing global

demand for fuels, have led to the development of nu-

merous biotechnological processes to minimize the use

of fossil fuels in the late 20th and early 21st centuries

The se inno vat ion s inc lud e the de velo pment o f b iof uels ,

such as ethanol, which started in Brazil in 1920 and was

strongly boosted by Brazil’s Pro-Alcohol Program estab-

lished in 1975. Since then, ethanol participates effec-

tively in Brazil’s energy matrix and is one of the cleanest

technologies in the world. Population growth, an ex-

panding agribusiness sector and the search for sustain-

able development have resulted in the eco-efficient pro-

duction of cellulosic ethanol from low-cost agro-indus-

trial residues and municipal waste of plant origin.

6. Acknowledgements

The authors gratefully acknowledge the Brazilian research

funding agencies CNPq and FUNDECT for their financial

support.

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