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CHAPTER 2
REVIEW OF LITERTURE
2.1- Definition of Algae :
The word ALGAE represent a large group of different organisms from different
phylogenetic groups, representing many taxonomic divisions. In general algae can be
referred to as plant-like organisms that are usually photosynthetic and aquatic, but do
not have true roots, stems, leaves, vascular tissue and have simple reproductive
structures. They are distributed worldwide in the sea, in freshwater and in wastewater.
Most are microscopic, but some are quite large, e.g. some marine seaweeds that can
exceed 50 m in length.
The unicellular forms are known as microalgae where as the multicellular forms
comprise macroalgae.
Microalgae comprise a vast group of photosynthetic, heterotrophic organisms which
have an extraordinary potential for cultivation as energy crops. They can be cultivated
under difficult agro-climatic conditions and are able to produce a wide range of
commercially interesting byproducts such as fats, oils, sugars and functional bioactive
compounds.
Seaweed is a loose colloquial term encompassing macroscopic, multicellular, benthic
marine algae. The term includes some members of the red, brown and green algae.
They are photosynthetic, like plants, and "simple" because they lack the many distinct
organs found in land plants. For that reason they are currently excluded from being
considered plants.
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The algae have chlorophyll and can process their own food through the process of
photosynthesis. Almost all the algae are eukaryotes and conduct photosynthesis within
membrane bound structure called chloroplasts. Cyanobacteria are organisms
traditionally included among the algae, but they have a prokaryotic cell structure.
Algae are an extremely important species. For one, they produce more oxygen than all
the plants in the world, put together! For another, they form an important food source
for many animals such as little shrimps and huge whales. Thus, they are at the bottom
of the food chain with many living things depending upon them.
With the recent research and interest into using algae for producing Biodiesel they have
the potential to become even more important.
Microalgae are small unicellular plants that range in size from 1 to 200 m they are
unique organisms in that they can accumulate storage lipids in large quantities within
their bodies
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The algae can be grown in large outdoor ponds, using the resources of sunlight, saline
water, nitrogen, phosphorus, and carbon dioxide. The algae can convert these raw
materials into proteins, carbohydrates, and lipids. In the process, they can double their
biomass three to five times a day. After a rapid growth phase, the algae are transferred
to induction ponds where nutrient limitation is allowed to occur. Under these
conditions, many algae stop growth and division and use all their energy to make lipidsas storage products to survive. Once the cells have accumulated lipids, they are
harvested and the water is recycled back into the growth ponds. The harvested cells
then are subjected to an extraction process to remove the lipids. Algal lipids are
primarily triglycerides with fractions of isoprenoids, phospholipids, glycolipids, and
hydrocarbons. They contain more oxygen and are more viscous than crude petroleum.
The two most promising fuel conversion options are transesterification to produce fuels
similar to diesel fuels and catalytic conversion to produce gasoline.
2.1.1-Components of algae
There are four components to large scale algal production and conversion into
liquid fuels:
1) Microalgae growth and production.
2) Engineering design.
3) Harvesting.
4) Conversion The design of a microalgae mass culture system is a synergistic
process.
The design must be tailored to the characteristics of the culture organism while species
must be selected that contribute to economic construction and operation of the facility.Microalgae must be selected that are environmentally tolerant, have high growth rates,
and produce large quantities of lipids. In addition, the choice of a suitable species
affects harvesting ease. The types of lipids that the algae produce will determine the
conversion methods. Thus, all four areas of development are highly interactive with
each other. Each of these four areas of research and technology development will be
discussed in detail in the remainder of the paper.
To improve lipid yields in microalgae, we must understand the physiological and
biochemical basis for partitioning photosynthetically fixed CO2 into lipids. The rate of
lipid synthesis and final lipid yield will depend on the availability of carbon for lipid
synthesis and the actual levels and activities of the enzymes used for lipid synthesis.Conditions such as nitrogen deficiency that induce the accumulation of lipid by algae
often drastically reduce the capacity of photosynthetic CO2 fixation. Low lipid yields
could result either from an absence of carbon skeletons or from low levels of enzymes.
Improvements in lipid yield can be achieved only when the limiting factors have been
determined.
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There are several main groups of microalgae, which differ primarily in pigment
composition; biochemical constituents, ultrastructure, and life cycle. There are five
groups: diatoms (Class Bacillariophyceae), green algae (Class Chlorophyceae), golden-
brown algae (Class Chrysophyceae), prymnesiophytes (Class Prymnesiophyceae), and
the eustigmatophytes (Class Eustigmatophyceae). The blue-green algae, or
cyanobacteria (Class Cyanophyceae), were also represented in some of the collections.A brief description of these algal groups follows:
Diatoms: Diatoms are among the most common and widely distributed groups of
algae in existence; about 100,000 species are known. This group tends to dominate the
phytoplankton of the oceans, but is commonly found in fresh- and brackish-water
habitats as well. The cells are golden-brown because of the presence of high levels of
fucoxanthin, a photosynthetic accessory pigment. The main storage compounds of
diatoms are lipids. Another characteristic of diatoms that distinguishes them from most
other algal groups is that they are diploid (having two copies of each chromosome)
during vegetative growth; most algae are haploid (with one copy of each chromosome)except for brief periods when the cells are reproducing sexually.
Green Algae: often referred to as chlorophytes, are also abundant; approximately8,000 species are estimated to be in existence. . These algae use starch as their primary
storage component. However, N-deficiency promotes the accumulation of lipids in
certain species. Green algae are the evolutionary progenitors of higher plants, and, as
such, have received more attention than other groups of algae.
Golden-Brown Algae:This group of algae, commonly referred to as chrysophytes, is
similar to diatoms with respect to pigments and biochemical composition.Approximately 1,000 species are known, which are found primarily in freshwater
habitats. Lipids and chrysolaminarin are considered to be the major carbon storage
form in this group.
Prymnesiophytes: This group of algae, also known as the haptophytes, consists of
approximately 500 species. They are primarily marine organisms. As with the diatoms
and chrysophytes, fucoxanthin imparts a brown color to the cells, and lipids and
chrysolaminarin are the major storage products.
Eustigmatophytes: This group represents an important component of thePicoplankton, which are very small, cells (2-4 m in diameter). The genus
Nannochloropsis is one of the few marine species in this class, and is common in the
worlds oceans.
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Cyanobacteria:This group is prokaryotic, and therefore very different from all othergroups of microalgae. They contain no nucleus, no chloroplasts, and have a different
gene structure. There are approximately 2,000 species of cyanobacteria, which occur in
many habitats. Although this group is distinguished by having members that can
assimilate atmospheric N (thus eliminating the need to provide fixed N to the cells), no
member of this class produces significant quantities of storage lipid.
2.2- The Aquatic Species Program
This chapter analyzes each step of the algae to biodiesel process, and begins with a
review of previous algae to biodiesel studies. From 1978 to 1996, the United States
Department of Energy's Office of Fuels Development funded the Aquatic Species
Program (ASP). The focus of the program was to develop renewable transportation
fuels from algae. Extensive research was conducted on the production of biodiesel
from algae grown in large raceway ponds that use waste CO2 as shown in the
following sections.
2.2.1 Algae Classification
The study began by trying to determine which species of algae would be suitable for
the purpose of developing transportation fuels. For the production of biodiesel the
selected strain of algae must have very high growth rates and a very high lipid or oil
content. There are well over 100,000 different species of algae, so the scientists
involved in the study had the daunting task of analyzing these species and determining
which were most suitable for producing biodiesel. By the end of the study the
researchers had identified around 300 strains of algae that are the most suitable forproducing biodiesel. They all have high growth rates, oil content, and are capable of
growing in harsh climates. These strains of algae are currently housed at the University
of Hawaii, and are available to interested researchers (Benemann, 1996).
2.2.2 Biochemistry and Molecular Biology
Next researchers focused their efforts on using biochemistry to manipulate the algae to
have higher oil content. The goal of this research was to take advantage of the "lipid
trigger", which is the phenomenon that occurs when microalgae are under
environmental stress many species go through a metamorphosis and begin producingvery large amounts of oil (Benemann, 1996). Researchers thought that this could be
done by denying the algae certain nutrients, specifically nitrogen. However in the end
the researchers concluded that although the nitrogen deficiency did increase the oil
content of the algae it does not lead to increased oil productivity because it reduces the
growth rates of the algae.
During this time researchers were also attempting to genetically modify the certain
algae species so that they would produce more oil and also enable them to grow in very
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harsh environments. Although the researchers did make significant discoveries they
were unable to demonstrate increased oil production in the cells.
2.2.3 Algae Production Systems
Over the course of the program several test sites were constructed to examine thefeasibility of large scale algae production in open ponds. Many different algae growth
systems have been studied, for example the Japanese government have developed
optical fiber based reactor systems that could dramatically reduce the amount of
surface area required for algae production. However while breakthroughs in these types
of systems have occurred their costs are prohibitive, especially for the production off
uels. The ASP focused on open pond raceway systems because of their relative low
cost (Benemann, 1996). The Algae Pond Model, which is a program developed in
Matlab to predict the energy use and emissions that result from growing algae in
various regions, is based off of the results obtain during the operation of the
Microalgae Outdoor Test Facility (OTF) in Roswell, New Mexico.
2.2.4 Microalgae Outdoor Test Facility (OTF)
In 1987 construction began on an algae growth facility consisting of two 1000m2
ponds, one plastic lined and another unlined, and six small, 3m2 ponds. An abandon
water research facility in Roswell New Mexico was the site chosen for this operation.
Roswell receives large amounts of daily solar radiation and has abundant flat desert
land with large supplies of saline groundwater, making it an excellent location for
algae growth. One limitation of the site was the low nightly temperatures, which turned
out to be to low for many of the more productive species identified.Building the large system required installation of two water pipeline of I, 300m in
length. The ponds were 14 x 77 m, with concrete block walls and a central wooden
divider. The paddle wheels were approximately 5m wide, with a sump that allowed
counter flow injection of C02. One pond was plastic lined; the other had a. crushed
rock layer, and the walls were cinder block (Benemann, 1996). Figure 2.1 below shows
an overview of the layout of the facility,
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Figure 2.1: Schematic of microalgae OTF on Roswell, New Mexico
The facility experimented with three different species of algae; first they used C.
cryptica CYCLOl. C. cryptica had high productivities in the summer months but
reaching 30 g/m2/d but fell off drastically during when the weather became colder.
Next M, minutum (MONOR2) Ii more cold-tolerant organism \VIiS used. Even though
productivity in the winter was very low 3.5 g/m"/d in December the algae survived
despite the ponds freezing over multiple times. Next Amphora sp. was used and
although it exhibited growth rates above 40 g/m2/d in the summer it also could not
survive in the winter months. Because of its survivability M. minutum was selected as
the most suitable strain of algae for the Roswell location (Goebel, 1989).
2.2.4.1 The OTF facility operated the large scale ponds for two years, by the
end of the study they had determined some important parameters for future
algae ponds:
1) Power for pond mixing is quiet low around 0.1 kW Il,000 m2 pond.
2) Pond mixing should be in the 15-25 cm/s range, and pond depth 15-25 cm.
3) CO2 utilization efficiencies of near 90% overall should be achievable.
4) Large-scale pond productivities of 70 mt/ha/yr are realistic goals for this
process.
5) The small-scale ponds can be used to screen strains and optimize conditions.
2.3 Algae Growth in Outdoor Raceway Ponds
This section is a step by step walk through of the algae to biodiesel process. The size of
the algae ponds are 1,OOO m2 the same size studied in the OTF. All of the processes
discussed in this section are modeled in the Algae Pond Model. First the algae pond
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operations are analyzed, followed by the oil extraction process, and finally
transesterification or biodiesel production.
2.4 Microalgae
Micro algae are remarkably efficient biological factories capable of taking a waste(zero-energy) form of carbon (C02) and converting it into a high density liquid form of
energy (natural oil). The four most abundant classes of micro algae are diatoms
(Bacillariophyceae), green algae (Chlorophyceae), blue-green algae (Cyanophyceae),
and golden algae (Chrysophyceae). Diatoms were the only class of micro algae
analyzed in this study. They are found in fresh and salt water, and they store carbon in
the form of natural oils or as a polymer of carbohydrates. (Benemann, 1996) For the
algae to biodiesel cycle to be successful a species of algae that has high growth rates
and oil content must be used. The Aquatic Species Program recommends that an effort
be made to naturally select strains at the locations that would likely be commercial
micro algal production sites. In this manner, the algae would be exposed to theprevailing environmental conditions, particularly the indigenous waters.
If a non- native strain of algae is used it is likely that a native species will infiltrate the
pond and over time dominate the pond, killing off the desired strain.
The Algae Pond Model is based off of the results obtained at the OTF using unicellular
green algae called Monoraphidium minutum (M. minutum).
Algae reproduce by cellular division. They divide and divide and divide until they fill
whatever space they are in or exhaust their nutrients (Tiekell, 2003). There are multiple
stages of algae growth that depend on the culture volume and algae density.
Assume there is a small batch of algae is placed into a large volume tank mixing tank,
and that the tank is supplied with enough C02 and sunlight to generate maximumgrowth. Some form of agitation, such as shaking or mixing is necessary to ensure
nutrient and gaseous exchange. The algae will initially enter an exponential growth
phase, where cells grow and divide as an exponential function of time, as long as
mineral substrates and light energy are saturated (Richmond. 2003), L~hen the
concentration of algae is high enough that light does not penetrate through the entire
culture, the algae move into the light limited linear growth phase. which is expressed
by the following equation (Richmond, 2003).
IA=u"'X"'V/Y
J '" Photon flux density (h J ml\2)1\-1 A Illuminated surface area (mI\2)
u "'" Specific growth rate (1 hl\-l)
X"'" Biomass concentration (grams/liter) V = Culture volume (mI\3)
Y;;;;; Growth yield (g/J)
Finally if the size of the tank is not increased the algae will eventually reach a
terminal density and stop growing, Algae growing in a flowing pond or raceway will
operate in the light limited linear growth stage, The exponential growth stage is not
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achievable, since the algae are not all subject to the necessary amount of solar
radiation. As algae cycle around the race way pond a certain percentage of algae will
be harvest leaving the remaining algae room to grow in the linear growth range,
maintaining the algae in the linear growth range has allowed the model of algae growth
to be controlled by linear relationships.
2.4.1-Algae Pond Operations
Paddle wheel
A scaled version of the 1OOO m2
algae pond is shown in figure 2.2
This is the pond that the APM is modeled after, The pond depth is 20 cm
corresponding to a volume of 200 m3 or 200,000 liters, it is unlined and powered
entirely by electricity, Many ponds of this size would be fit into a small area along with
larger settling ponds and a pumping centrifuge station in order to produce algae on a
large scale. Figure 2.3 below is a scaled layout of what one of these facilities might
look like,
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Centrifuge and pumping station
Settling Ponds (2 total)
Figure 2.3: Scaled model of large algae farm for production of biodiesel
Algae pond operations are very simple. The algae are introduced into the pond
and allowed to grow until they occupy 1 % of the volume of the pond. Very highgrowth rates are achieved because the pond is constantly mixed by the paddle wheel
and it is infused with an ample amount of CO2 and fertilizer. The paddle wheel rotates
providing a current of 20 cm/s around the pond. The mixing is required to ensure that
all of the algae receive the necessary amounts of solar radiation. C02. and fertilizer
required for optimal growth. The C02 is injected into the algae pond in the form of
flume gas from a nearby coal fired electric plant. The bubblers are spaced around the
pond so that the C02 is evenly dispersed throughout the pond. A 1,000 m2 algae pond
operating in Roswell New Mexico consumes around 10,589 kg of CO2 each year. This
is a miniscule amount considering that the average ?85 MW power plant produces
19,488 tons of C02 daily, or enough to support about 330,000 algae ponds (Clear the
Air, 2000).
Algae require a certain amount of phosphorus and nitrogen to grow at optimal rates.
The phosphorus and nitrogen are pumped into the ponds along with ground water from
the central pumping station shown in figure 2.3. The nitrogen is in the form of
ammonia or nitrate and must compose 0.8% of the volume of the pond solution to
ensure maximum algae production. Likewise phosphorus is in the form of phosphate
and must compose 0.6% of the pond (Benemann, 2006). In the future both of these
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nutrients could be supplied in the form of municipal solid waste. Water must also be
continuously supplied to the ponds because a certain amount is lost daily due to
evaporation and farm operations. The OTF tests recorded an average water loss of 6.2
mm or 6.2 rrr' of water per day. This must be replaced with saline or fresh ground
water depending on the species of algae used.
2.4.2 Algae Harvesting
Algae harvesting is one of the major factors that must be overcome in order for algae to
be used as a fuel source. The problem is that microalgae mass cultures are dilute,
typically less than 500 mgll on a dry weight organic basis, and the cells are very small.
Many unicellular species like M. minitum are around 5 micrometers in diameter. In
order to be processed into biodiesel the algae must be in the form of a paste that is 15%
solids. In the raceway ponds the mixture is about 1 % solids, this mixture must go
through a process which will result in a concentration of at least 15%.
2.4.3 Biodiesel Production
In order to be converted into a liquid fuel the oil contained in the algae must be
extracted. According to Nick Nagle a senior engineer at the NREL who was a vital part
of the ASP, algae oil extraction is similar to soybean oil extraction, and can be modeled
the same. The oil is extracted by mixing Hexane, a chemical made from petroleum,
with the algae paste. The hexane removes the oil from the algae, this mixture of hexane
and oil is distilled leaving pure algae oil. The remaining hexane is recycled through
another batch of algae. The algae fiber remaining after this process can be used as
fertilizer for the algae farms.
2.4.4 Transesterification
Transesterification is the process that the algae oil must go through to become
biodiesel. It is a simple chemical reaction requiring only four steps and two chemicals.
1. Mix methanol and sodium hydroxide creates sodium methoxide
2. Mix sodium methoxide into algae oil
3. Allow to settle for about 8 hours
4. Drain glycerin and filter biodiesel to 5 microns
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Figure 2.5: Inputs and outputs of transesteritication reaction
The alcohol used in this reaction can be either methanol or ethanol, the catalyst is
sodium hydroxide, and the oil is any fat or vegetable oil. The outputs are 86% Methyl
Esters or biodiesel, 9% Glycerin which can be used to make soap and other products, 1
% fertilizer, and 4% alcohol which can be recycled back through the process
(Tickell,2003)
2.5 Collection and Screening Activities
We will describes the research performed at SERI(The Solar Energy Research
Institute) they make a program and called it ASP(Aquatic Species Program).Its a
research program in the United States launched in 1978 ,which over the course of
nearly two decades looked into the production of energy using algae . In addition to
performing actual research in this area, SERI personnel were responsible for
coordinating the efforts of the many subcontractors performing similar activities, and
for standardizing certain procedures and analyses. These efforts ultimately resulted inthe development of the SERI Microalgal Culture Collection,
2.5.1 Collection and Screening Activities - 1983
The first collecting trips made by SERI researchers took place in the fall of 1983. Five
saline hot springs in western Colorado were selected for sampling because of their
abundant diatom populations, and because a variety of water types was represented.
Water samples were used to inoculate natural collection site water that had been
enriched with N (ammonium and nitrate) and phosphate (P) and then filter sterilized.
Water samples were also taken for subsequent chemical analyses. The temperature andconductivity of the site water were determined at the time of collection. Conductivity
ranged from 1.9 mmhoscm-2 at South Canyon Spring to 85.0 mmhoscm-2 (nearly
three times the conductivity of seawater) at Piceance Spring. Water temperature at the
time of collection ranged from 11 to 46C. In the laboratory, researchers tried to
isolate the dominant diatoms from the enriched water samples. Cyanobacteria and
other contaminants were removed primarily with agar plating. Approximately 125
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unialgal diatom strains were isolated. The predominant genera found were Achnanthes,
Amphora, Caloneis, Camphylodiscus, Cymbella, Entomoneis, Gyrosigma, Melosira,
Navicula, Nitzschia, Pleurosigma and Surirella. A standardized lipid analysis protocol
was not yet in place to screen these strains. However, many algal strains were known to
accumulate lipids under conditions of nutrient stress. Microscopic analysis of cells
grown under N-deficient conditions revealed lipid droplets in several of the strains,particularly in Amphora and Cymbella.
.
2.5.2 Collection and Screening Activities - 1984
The screening and characterization protocols used by SERI researchers were refined
for the 1984 collecting season. Included in these refinements was the development of a
modified rotary screening apparatus, a standard type of motorized culture mixing
wheel for 16x150-mm culture tubes. The rotating wheel was constructed of Plexiglas to
allow better light exposure (see Figure II.A.1). The wheel was typically illuminated
with a high-intensity tungsten stage lamp, and could be placed inside a box behind aCuSO4-water heat filter for temperature control. The Plexiglas wheel allowed all the
cultures to receive equal illumination. Another technological advance used a
temperature-salinity gradient table to characterize the thermal and salinity preferences
and tolerances of the isolates.
Figure II.A.1.Rotary screening apparatus used for microalgal screening
Collecting trips made by SERI researchers in 1984 focused on shallow saline
habitats, including ephemeral ponds, playas, and springs in the arid regions of
Colorado and Utah. After collection, the water and sediment samples were kept under
cool, dark conditions for 1 to 3 days until they could be further treated in the
laboratory. The pH, temperature, conductivity, redox potential, and alkalinity of thecollection site waters were determined, and water samples were taken for subsequent
ion analysis. In the laboratory, the samples were enriched with 300M urea, 30M
PO4, 36M Na2SiO3, 3M NaFeEDTA, trace metals (5 mL/L PII stock, see Figure
II.A.2), and vitamins. The enrichment tubes were then placed in the rotary screening
apparatus (maintained at 25C or 30C) and illuminated at ~400Em-2s-1. Over a 5-
day period, the illumination provided by the stage lamp was gradually increased to
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1,000Em-2s-1. The predominant strains present in the tubes were isolated as
unialgal cultures by agar plating or by serial dilution in liquid media. The isolated
strains were then tested for their ability to grow in incubators at 25C at 150-200
Em-2s-1 in the standard media types described above. and in artificial seawater
(termed Rila Salts ASW, using Rila Marine Mix, an artificial sea salt mixture
produced by Rila Products, Teaneck, NJ. The strains that grew well in at least one ofthese media were further characterized with respect to growth on a temperature-salinity
gradient table at a light intensity of 200 Em-2s-1. Thirty combinations of
temperature (10 to 35C) and salinity (10 to 70 mmhocm-1) were included in this
analysis, representing the ranges that might be expected in actual outdoor production
systems. Once again, the cultures were enriched with nutrients to maximize growth
rates. The cultures used to inoculate the test cultures were preconditioned by growth in
the media at 17 and 27C. The optical density at 750 nm (OD750) of the cultures was
measured twice daily for 5 days, and the growth rates were calculated from the increase
in culture density during the exponential phase of growth. A refinement of this method
was to measure the growth rates in semicontinuous cultures, wherein the cultures were periodically diluted by half with fresh medium; this method provided more
reproducible results than the batch mode experiments. Approximately 300 strains were
collected from the 1984 trips to Utah and Colorado. Of these, only 15 grew well at
temperatures30C and conductivities greater than 5 mmhocm-1. Nine were diatoms,
including the genera Amphora, Cymbella, Amphipleura, Chaetoceros, Nitzschia,
Hantzschia,an d Diploneis. Several chlorophytes (Chlorella, Scenedesmus,
Ankistrodesmus and Chlorococcum) were also identified as promising strains, along
with one chrysophyte (Boekelovia). Two strains isolated as a result of the 1984
collecting effort (Ankistrodesmus sp. And Boekelo via sp.) were characterized in
greater detail using the temperature-salinity matrix described earlier. Boekeloviaexhibited a wide range of temperature and salinity tolerance, and grew faster than one
doublingday-1 from 10 to 70 mmhocm-1 conductivity and from 10 to 32C,
exhibiting maximal growth of 3.5 doublingsday-1 in Type II/25 medium. Reasonable
growth rates were also achieved in SERI Type I and ASW-Rila salts media (as many as
1.73 and 2.6 doublingsday-1, respectively).Ankist rodesmus was also able to grow
well in a wide range of salinities and temperatures, with maximal growth rates
occurring in Type II/25 medium (3.0 doubling day.
2.5.3 Collection and Screening Activities - 1985
In 1985, the strain enrichment procedure utilizing the rotary screening apparatus
described previously was modified to include incubation of samples in SERI Type I
and Type II media (25 and 55 mmhocm-1 conductivity) and in artificial seawater, in
addition to the original site water. The cultures that exhibited substantial algal growth
were further treated to isolate the predominant strains as unialgal (clonal) isolates.
These strains were then tested for growth using the temperature-salinity matrix
described earlier.
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2.5.4 Collection activities:
Collection efforts by SERI researchers in 1985 again focused on shallow inland saline
habitats. This time collecting trips were also made to New Mexico and Nebraska, in
addition to Colorado and Utah. Eighty-six sites were sampled during the year, 53 ofwhich were sampled in the spring. From these 53 sites, 17 promising strains were
isolated. An analysis was conducted comparing the results of the new protocol with
those that would have resulted from the protocol used in prior years. This analysis
indicated that the revised protocol was in fact superior to the older protocol. For
example, only six of the 17 strains selected via the new protocol would also have been
selected using the old protocol. Only three of the 17 strains grew best in the artificial
medium type that most closely resembled the collection site water; in fact, only six
strains were even considered to grow well in the collection site water relative to growth
in at least one of the artificial medium. This analysis clearly indicated the value of
performing the initial screening and enrichment in a variety of relevant media. Theresults suggest that the shallow saline environments sampled probably contain a large
number of species whose metabolism is arrested at any given time. In other words, the
water quality of such sites varies greatly, depending on precipitation and evaporation,
so probably only a few of the many species present are actively growing at any given
time. This also may explain the wide range of salinities and temperatures tolerated by
many of these strains.
2.5.5 Growth rates:
Six promising strains were analyzed in SERI Type I, Type II, and ASW (Rila) usingthe temperature-salinity gradient described previously. These included the diatoms
Chaetocers muelleri(C H A E T 1 4 ), Navicula(N AV IC 1 ), Cyclotella(C Y C LO 2 ),
Amphora (AMPHO1 and AMPHO2), and the chlorophyte Monoraphidium minutum
(MONOR2). (NAVIC1 and CYCLO2 were actually collected from the Florida Keys;
the remaining strains were collected in Colorado and Utah.) All strains exhibited rapid
growth over a wide range of conductivities in at least two media types. Furthermore, all
strains exhibited temperature optima of 30C or higher. Maximal growth rates of these
strains, along with the optimal temperature, conductivity, and media type determined in
these experiments are shown in Table II.A.1. (Higher growth rates were determined for
some of these strains in subsequent experiments; see results presented in Barclay et al.[1987]). Temperature-salinity growth contours are provided for these strains in the
1986 ASP Annual Report (Barclay et al. 1986).
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Strain Maximu
mGrowth
Rate(doublin
gsday-1
Optimal
Conductivity
(mmhocm-1
Optim
alTemperature
Optimal
Medium Type(dependent on
temperatureand conductivity
used)
AMPHO
1
1.7 10-25 30 Type I,
ASW
AMPHO
2
2.48 40-70 30-35 Type I,
Type II
CHAET1
4
2.87 25-70 35 Type II,
ASW
CYCLO
2
1.63 10-70 30-35 Type I,
ASW
MONOR
2
2.84 25 25-30 Type I, II,
ASW NAVIC1 2.77 10-40 30 Type I,
Type II
Experiments were also conducted in an attempt to identify the chemical components of
SERI Type I and Type II media most important for controlling the growth of the
various algal strains. Bicarbonate and divalent cation concentrations were found to be
important determinants in controlling the growth of Boekelovia sp. (BOEKE1) and
Monora phidium (MONOR2). The growth rate of MONOR2 increased by more than
five-fold as the bicarbonate concentration of Type II/25 medium was increased from 2
to 30 mM and the growth of BOEKE1 by approximately 60% over this range. These
results make sense, since media enriched in bicarbonate would have more dissolved
carbon available for photosynthesis. An unexpected finding was that there was a
decrease of nearly 50% in the growth rate of BOEKE1 as the divalent cation
concentration increased from 5 mM to 95 mM (in Type I/10 medium containing altered
amounts of calcium and magnesium). The effects of magnesium and calcium
concentration on the growth of MONOR2 were less pronounced. These results indicate
that matching the chosen strain for a particular production site to the type of water
available for mass cultivation will be important.
2.5.6 Lipid content:
The lipid contents of several strains were determined for cultures in exponential growth
phase and for cultures that were N-limited for 7 days or Si-limited for 2 days. In
general, nutrient deficiency led to an increase in the lipid content of the cells, but this
was not always the case. The highest lipid content occurred with NAVIC1, which
increased from 22% in exponential phase cells to 49% in Si-deficient cells and to 58%
in N-deficient cells. For the green alga MONOR2, the lipid content increased from
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22% in exponentially growing cells to 52% for cells that had been N-starved for 7
days. CHAET14 also exhibited a large increase in lipid content in response to Si and N
deficiency, increasing from 19% to 39% and 38%, respectively. A more modest
increase occurred for nutrient-deficient AMPHO1 cells, whereas the lipid content of
CYCLO2 was similar in exponential phase and nutrient-deficient cells, and actually
decreased in AMPHO2 as a result of nutrient deficiency.These results suggested that high lipid content was indeed achievable in many strains
by manipulating the nutrient levels in the growth media. However, these experiments
did not provide information on actual lipid productivity in the cultures, which is the
more important factor for developing a commercially viable biodiesel production
process. This lack of lipid productivity data also occurred with most of the ASP
subcontractors involved in strain screening and characterization, but was
understandable because the process for maximizing lipid yields from microalgae grown
in mass culture never was optimized. Therefore, there was no basis for designing
experiments to estimate lipid productivity potential.
2.5.7 Collection and Screening Activities - 1986 and 1987
SERI in-house algal strain collection and screening efforts during 1986-1987 were
focused in three separate areas. First, detailed characterization of previously collected
strains continued. Second, because the desert southwest sites targeted for biodiesel
production facilities can be quite cool during the winter, a new effort to collect strains
from cold-water sites was initiated. Finally, a strategy was developed and implemented
to reduce the number of strains that had accumulated as a result of in-house and
subcontracted research efforts, which allowed researchers to focus on the most
promising strains.
2.5.8 Strain characterization:
Eight additional strains collected previously from warm-water sites that grew well
during the initial screening procedures were characterized with respect to temperature
and salinity tolerances, growth rates, and lipid content under various conditions. These
strains were Chaetoceros muelleri (strains CHAET6, CHAET9, CHAET10,
CHAET15, and CHAET39), Cyclotella cryptica(C Y C LO4), Pleurochrysis carterae
(PLEUR1), and Thalassiosira weissflogii (THALA2). Each strain was grown in a
variety of temperature-salinity combinations by the use of a temperature-salinitygradient table. The maximal growth rate achieved under these conditions occurred with
CHAET9, which exhibited a growth rate of 4.0 doublingsday-1. The remaining strains
all had maximum growth rates that exceeded 1.4 doublingsday-1, and several grew at
rates exceeding 2.5 doublingsday-1 (i.e., CHAET6, CHAET10, and CHAET39). All
had an optimal temperature of 30C or higher, except for PLEUR1 and THALA2,
which had optimal temperatures of 25C and 28C, respectively. Most of the strains
grew well in a wide range of salinities (e.g., five of the eight strains exhibited a growth
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rate greater than one doublingday-1at conductivities between 10 and 70 mmhocm-1).
With respect to the effect of water type on growth, CHAET39, CYCLO4, and PLEUR1
grew best on SERI Type I medium. On the other hand, CHAET6, CHAET9, and
CHAET10 grew best in SERI Type II medium, but also exhibited good growth on
Type I medium and artificial seawater. CHAET15 and THALA2 achieved maximal
growth rates on artificial seawater, and, along with PLEUR1, grew very poorly onType II medium. These results again highlight the need to have a variety of algal
strains available for the specific water resources that would be available for mass
culture in various locations.
The lipid contents of these 10 strains were also determined for exponentially growing
cells, as well as for cells that were grown under nutrient-limited conditions. Nitrogen
deficiency led to an increase in the lipid contents of CHAET6, CHAET9, CHAET10,
CHAET15, CHAET39, and PLEUR1. The mean lipid content of these strains increased
from 11.2% (of the total organic mass) in nutrient-sufficient cells to 22.7% after 4 days
of N deficiency. Silicon deficiency led to an increase in the lipid content of all strains
(although in some cases the increase was small and probably not statisticallysignificant). The mean lipid content of the eight strains increased from 12.2% in
nutrient-sufficient cells to 23.4% in Si-deficient cells. A few strains were poor lipid
producers, such as CHAET6, CYCLO4, and PLEUR1, which did not produce more
than 20% lipid under any growth conditions.
In conclusion, the work carried out by Tornabenes laboratory provided a detailed
characterization of the lipids present in a variety of microalgae. No general conclusions
could be made from the work except that the lipid composition of various microalgal
strains can differ quite substantially. Because the nature of the lipids can have a large
impact on the quality of the fuel product, characterizing the potential production strains
is important to ensure that deleterious lipids (e.g., highly polyunsaturated fatty acids inthe case of biodiesel fuel) are not present at high levels.
2.6 Algae - A source of biofuel
2.6.1 Algae as a source of Biofuel possess certain advantages:
Algae produce oil, and because of their growth rate and yields, they could produce a lot
more than other energy crops. Some estimates suggest that microalgae are capable of
producing up to 15,000 gallons of oil per Hectare a year. This could be converted into
fuels, chemicals and more.
Microalgae, specifically, possess several attractive characteristics in the context of
energy and biofuels:
1. They provide much higher yields of biomass and fuels, 10-100 times higher than
comparable energy crops.
2. They can be grown under conditions which are unsuitable for conventional crop
production.
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3. Microalgae are capable of fixing CO2 in the atmosphere, thus facilitating the
reduction of increasing atmospheric CO2 levels, which are now considered a global
problem.
4. Algae biofuel is non-toxic, contains no sulfur, and is highly biodegrada.
Origin of some types of Microalgae:
Color Genus Alga name Origin
Green Dunaliella Dunaliella bardawil Bardawil Lake
Dunaliella Dunaliella salina Qaron Lake and
Egyptial costal shores
Chlamydomonus Chlamydomonus sp. Swiss government
Scenedesmus Scenedesmus obliquusScenedesmus sp.
Scenedesmus sp.
GermanyEl-Fayoum, El-Rayan
Valley
Saudi Arabia kingdom
Chlorella Chlorella sp. El-Qalubia governorate
Blue
Green
Spirulina Spirulina sp. Most Egyptian lakes
specially ,those at
Natron
valley
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Comparison between open ponds and photo bioreactor:
Percentage of oil contents in Microalgae :
Algae Oil% Algae Oil%
Anabaena cylindrica 4-7 Monallantus salina 72
Ankistrodesmus species 28-40 Nannochloropsis species 28.7
Botryococcus braunii 25-86 Neochloris oleoabundans 35-65
Chaetoceros muelleri 24.4 Nitschia closterium 27.8
Chlamydomonas species 23 Nitschia frustulum 25.9
Chlorella emersonii 63 Phaeodactylumtricorunutum
20-30
Chlorella minutissima 57 Scenedesmus dimorphus 16-40
Chlorella protothecoides 15-55 Scenedesmus obliquus 12-14
Chlorella sorokiana 22 Scenedesmus quadricauda 19.9
Chorella vulgaris 14-56 Selenastrum species 21.7
Cyclotella species 42 Skeletonema costatum 19.7
Dunaliella bioculata 8 Spirulina maxima 6-7
Dunaliella salina 28.1 Spirulina plantensis 16.6
Dunaliella tertiolecta 36-42 Stichococcus species 33
Hantzschia species 66 Tetraselmis maculate 3Isochrysis galbana 21.2 Tetraselmis suecia 15-23
Item Open pond Photo bioreactor
Cost Low High
Space Short Long
Growth volume High Low
Running cost Low High
Maintenance Low High
Purity Low High
Specification Low High
Light harvesting Low High
Harvesting cost High Low
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Scope of present work
As a result from the previous discussion; we choose Dunaliella Salina as a source of oil
as the algae exist in Egypt at Qaron Lake and Alex. and its lipid content is somehow
high 10-30%.
The oil is then extracted from the algae by the help of professional botanist, after we
get the oil it would be treated chemically with adding some additives to get the
biodiesel, then we will make sure that this biodiesel can work as fuel in engines, has no
side effects on the engine, livings and environment, measure some of the main
properties as flash point, toxicity, cetane number and etc. Then we will measure its
performance on the engine.
In the end we will study how it could be used in large scale production.