1. Introduction
Marine diatoms, which are the most important eukaryotic phytoplankton for carbon sequestration and the main producers within phytoplankton today, contribute more than 40% of the global oceanic organic carbon production per year and are responsible for up to 25% of the global CO
2 fixation [
1]. Diatoms produce oil drops that are as a reserve material during the vegetative period of growth, with percentages that vary from 23% to 45% of dry cell weight. Physiological and genetic manipulations have also shown the possibility of increasing the amount of lipids in the cellular mass and re-invigorated studies regarding the potential of affording oil production using these microorganisms [
2]. In addition, marine strains showed more resistance to environmental changes in cultivation, as they are adapted to survive in high levels of salinity. For this reason, and due to the large seawater availability, which can be used in microalgae culture, it is expected that these microorganisms may supply the growing biofuel demand, shifting it from petroleum, natural gas, and coal derived fuels to biofuels produced from marine microalgae [
3].
In recent years, public awareness has been raised to reduce CO
2 emissions around the world. Of the various physical, chemical, and biological methods that can be used to capture CO
2, the CO
2 biological fixation using microalgae is thought to be one of the most important and effective approaches and is considered as a renewable, energy-saving, and sustainable technology for the reduction of CO
2 emissions [
4]. A diverse potential of various algal species has been analysed in terms of ecological, economical, and bioenergy production [
5]. The biochemical components of algae like protein, carbohydrates, and lipids have been used in different industries of food, cosmetics, and medicines. The dynamics of microalgae growth, as well as inorganic carbon and nutrients uptake, were extensively studied during the pond start-up and semi-continuous feeding conditions [
5].
Several strains of microalgae were recently found to be highly tolerant to CO
2, because they can grow under high CO
2 concentrations (mostly 1–15%) and simultaneously produce a significant amount of lipids for biodiesel production [
4]. Microalgae need simple requirements (light, water, CO
2, and minerals) for growth and photosynthesis. They can produce promptly large amounts of lipids, proteins, and carbohydrates [
6]. These microorganisms accumulate triglycerides as a storage lipid under specific culture conditions. Microalgal lipids are the green oil for sustainable biodiesel production [
7]. The increase of growth rate and the improvement of lipid content of microalgal strain have the one challenge to fully exploit this potential [
8]. Cyanophyceae, Chlorophyceae, Bacillariophyceae, and Chrysophyceae are the most abundant sources of microalgae biodiesel production [
9].
Currently, crops are the common feed stocks in the biodiesel production industry, as well as the food industry; thus, crop-based biofuels production has created increased food prices [
10]. A wide variety of microalgae species reach higher lipid productivities than crops, hence becoming potential substrates to alleviate the referred-to “food-versus fuel competition” [
9]. Despite the efforts that have been taken, industrial biodiesel production from microalgae is not economically viable nowadays due to the high costs of drying and lipid extraction processes [
11]. In the present study, diatom of
Amphora coffeaeformis RR03
(A. coffeaeformis) were mass cultivated in 150 L and 1500 L outdoor open raceway ponds. Two distinct types of open bioreactors were used to determine the production of high oil content. The possible contaminating factors were also examined using a non-sterile medium. These results provided new insights to the mass cultivation of new
A. coffeaeformis RR03 towards efficient biocrude and biodiesel production.
3. Discussion
The present investigation has demonstrated the cultivation of marine diatom on a large scale in artificial seawater medium with minimum expenditure. Improved algal growth was ultimately obtained in the laboratory under optimal conditions. The results of this study show that a novel diatom of A. coffeaeformis RR03 could be a suitable candidate for biocrude production: it could meet the future demand of energy, because it contains high amount of biomass.
The mass culture of marine algae is dependent on natural seawater, both in open tanks and in closed controlled systems [
12]. Many algae species have high lipid content and they grow on non-arable land using alternative seawater [
13]. In the present study, mass cultivation trials of
A. coffeaeformis RR03 in the modified CFTRI-RRAC I medium were made; the diatom that was cultivated in 1.0 m
2 open raceway pond without CO
2 supplementation showed that the alga attained a maximum of 0.81 g L
−1 with 2.51 × 10
6 cells/mL on the 15th day. A modified CFTRI-RRAC I medium optimized in the present attempt is supported by the organism for a maximum accumulation of 149 mg L
−1 of lipid content on 15th day. It was more than the alga grown in F/2 medium (control). The alga
A. coffeaeformis RR03 showed maximum lipid productivity of 9.93 mg L
−1 d
−1 in the modified CFTRI-RRAC I medium. The concentration of chlorophyll-
a maximum of 6.09 mg L
−1 on 15th day when grown in modified CFTRI-RRAC I medium was higher than in the control (F/2 medium). James and Al-Khars [
14] have also found similar high yield of
Nannochloropsis sp. and
Chlorella in a lucent vertical air-lift photobioreactor and obtained maximum productivities of 26 to 20 g m
2 d
−1 on a dry weight basis.
The mass cultivation of A. coffeaeformis RR03 in modified CFRTRI-RRAC I medium in 10.0 m2 open raceway pond supplemented with CO2 and the pH was maintained in a range of 8.0–8.5, whereas the culture without CO2 supplementation of the pH was raised up to 9.16. The reduction of pH in CO2-supplemented culture could be due to the dissolution of CO2 into carbonic acid. CO2 supplementation enhanced biomass productivity when compared to that of control (without CO2 supplementation), thus indicating the possible utilization of CO2 as carbon source for increase biomass of 1.5 g L−1 on 21st day. However, CO2 supplementation decreased accumulation of lipid content of the alga.
Carbon dioxide supplementation in modified CFRTRI-RRAC I medium supported the diatom for maximum accumulation of Chlorophyll-
a content of 13.18 mg L
−1 on 21st day. The growth rates, biomass, and lipid content of microalgae are manifestly enhanced by freshening with essential for levels of CO
2 [
15]. Addition of extra CO
2 can increase growth rates, which has been demonstrated by various experiments with large amounts of microalgae cultivation in carbon sequestration. The dissolved CO
2 can spontaneously change to carbonic acid to form bicarbonate, and carbonate makes CO
2 dissolve in the medium. However, it lowers the pH, which reduces growth for most species. The pH of medium under CO
2 supplementation was not allowed to be lower than pH 8.0, but was maintained between 8.0 and 8.5, which supported the organism for achieving maximum biomass productivity.
Low broth of algae generally accumulate heavily, whereas the cells normally carry negative charge and contain excess of algogenic organic matters to their immovability in a circulated condition [
16]. The harvesting technique charges the properties of microalgae such as algal density, size, and value of the desired products [
17]. Bioflocculation and electroclarification were followed by harvest diatoms biomass. Flocculation is one of the chemical technologies in the microalgae harvesting. The chamber using a filter press in the absorption of 245 could be attained for the large microalga
C. proboscideum to produce a cake with 27% solids [
18]. In the present attempt, diatom slurry samples were successfully obtained through pressure filtration system. The algal slurry was then exposed to solar radiation for a day and stored under room temperature. The ventilation promotes dewatering process that was also categorized by solid content and recovery time. In the all-purpose, the solid content after the harvested biomass can easily exceed 90%, while the recovery rate can reach 95%.
Harvested algae contained 97–99% of water. The removals of excessive water are necessary for the long-term storage of algae feedstock and are also required for many downstream processes. To maintain microalgae from long-lasting microbial growth, the moisture level of harvested algae was kept below 7%. Drying is an energy-intensive process and it describes total production costs of up to 30%. Natural drying (solar and wind) is the most economical method; however, it is weather-dependent and requires large space [
19].
4. Materials and Methods
4.1. Sample Collection and Isolation of Microalgae
Seawater samples were collected from different coastal regions of Tamil Nadu, India, during August and September 2009. Different seawater samples were collected along the coast of Kanyakumari; Tuticorin; Rameswaram; and Chennai, Tamil Nadu, India using phytoplankton net of 25 μm. In addition, saltpan samples were collected from Kovelong near Chennai, India. The samples were brought to the laboratory and inoculated in the F/2 medium [
20]. Fast growing microalgae strains were isolated and purified using serial dilution technique with spread plate method on 2% F/2 agar medium. The isolated microalgae were cultured in the basal medium.
4.2. Identification of Microalgal Isolates
The algal isolates were identified based on their morphological characteristics observed under compound microscope using standard monographs. Bacillariophyceae members (Diatoms) were identified based on the description given by Al-Kandari et al. [
21]. All the isolated diatom samples were treated with concentrated Nitric acid (HNO3) overnight to remove organic material from the cell. The samples were centrifuged at 1000 g; the pellet was washed with distilled water several times to remove the nitric acid, and then the samples were used for identification. All the isolated microalgae were made into unialgal cultures and maintained in the basal medium under laboratory conditions at 22 ± 2 °C in a thermostatically controlled room, illuminated with cool white fluorescent lamps at an intensity of 30 μEm
−2 s
−1, with a 12:12 h of light: dark regime.
4.3. Mass Cultivation of Amphora Coffeaeformis RR03 in an Open Raceway Pond
The diatoms of
A. coffeaeformis RR03 were grown in the modified CFTRI-RRAC I medium in an open raceway pond. The modified CFTRI-RRAC I medium was prepared by mixing urea (200 mg/L), super phosphate (40 mg/L), potash (100 mg/L), sodium silicate (35 mg/L), magnesium sulphate (250 mg/L), sodium bicarbonate (250 mg/L), ferric chloride (10 mg/L), and salinity (30 ppt) in a litre of artificial seawater and adjusted pH 8.0. The culture was grown in 150 L and 1500 L open raceway pond. The 30 mL of optimally grown algal samples was inoculated in 270 mL of the basal medium of 500 Erlenmeyer flask and kept in an outdoor condition for a period of 21 days. Every 3 days, the number of diatom cells was recorded and expressed as 10
−6 cells/mL [
22], chlorophyll-
a, [
23], and dry biomass [
24]; total lipid [
25] were also recorded.
4.4. Details of Raceway Ponds
The raceway ponds of 1.0 m
2 with 150 L capacity and 10.0 m
2 of 1500 L at the premises of the Aban Infrastructure Pvt Ltd., Biotechnology Division, Chennai, India were used to conduct the field trail. The details of the raceway ponds are summarised in the
Table 1. The concrete pond raceway floors are coated with FRP material (fibre-reinforced polymer) and RP (reinforced polymer). The raceway ponds were provided with a paddle wheel system for aeration at 10 rpm. During the experimental period, the evaporation loss of the medium was compensated with bore well water. An outlet was also provided in each pond at the bottom to enable cleaning whenever required. The raceway ponds are protected from dust, etc., on the top with transparent polythene sheet. The raceway ponds are also connected with carbonation column. The raceway floors are coated with FRP material and designed as length inner 2.22, 7.00; width inner 0.50, 1.50; depth (m) 0.26, 0.26; partition wall length 1.79, 5.55; partition wall width 0.20, 0.22, bottom area 0.76, 9.30; and the total working volume of 200 L and 2000 L
4.5. Sterilization of Medium
The 1.0 m2 and 10.0 m2 raceway ponds were added with 135 L and 1350 L medium, respectively, and added about 10 ppm of sodium hypochlorite and aerated overnight using the paddle wheel at 10 rpm. Subsequently, 0.285 ppm of sodium thiosulphate was added to neutralize the medium. The level of free chlorine was checked using Hach spectrophotometer (DR 2700, Hach, Düsseldorf, Germany), and if there was any chlorine, it was neutralized by adding sufficient amount of sodium thiosulphate until nil chlorine in the medium was recorded.
4.6. Determination of Chlorine
The samples were filtered through 0.2 μm membrane, and the filtrates were collected for the analysis. To 10 mL of the sample, one DPD-free chlorine powder pillow was added and vortexed. Development of the colour pink indicated the presence of chlorine and colourlessness indicated absence of chlorine.
4.7. Preparation of Inoculum in 1.0 m2 and 10.0 m2 Raceway Pond
Fifteen litres of optimally grown alga culture were obtained from the laboratory condition and transferred to the 1.0 m2 open raceway pond containing 135 L medium. The inoculum was raised in the following order: optimally grown 15 L of diatom culture was collected under laboratory conditions and transferred into the 1.0-m2 raceway pond containing 135 L medium and maintained for 10 days. Then, the culture (150 L) was transferred to 10.0 m2 raceway pond contained 1350 L of medium. This medium was used for mass cultivation outdoor condition.
4.8. Harvesting of Biomass
The raceway ponds (1.0 m−2) containing 135 L medium were inoculated with 15 L of optimally grown culture of A. coffeaeformis RR03. This experiment was conducted for a period of 21 days during the month of June-2013. At the end of the study period, the diatom biomass were harvested using electroclarification process and filter press technique. The algal culture from the experimental pond was pumped into the collection/storage tank and subjected to electroclarification process. The culture was circulated at a flow rate of ~600 L h−1 via the reaction chamber. The volume of the chamber was of 50 L with one stainless steel electrode placed at the centre (0.5 sq.m). The retention time inside the reaction chamber was 25 min. The reaction was carried out at Voltages 1.8 and 111 Amperes. The culture in the reaction chamber was continuously agitated at 100 rpm and added 1.0 ppm of polyelectrolyte using a dosing pump. The polyelectrolyte-treated culture was then overflow into a 250 L clarifier, in which the algal slurry settled at the bottom of the clarifier was taken for further processing. The supernatant was continuously overflowed through the outlet placed just 15.0 cm from the top of the clarifier. Subsequently, dewatering of biomass was made using filter press. The pressure filtration system comprised a filter press. It contained 15 plates and 15 frames, over which plankton material of 5 μm was placed. The plates and frames were tightened using a manual hydraulic closing system at 250 kg/cm2 pressure. There were two inlets and two outlets (lower and upper) for pumping of algal slurry and collection of supernatant, respectively. There were also individual outlets in each of the frames for cross-checking the filtration efficiency of the filter cloth material inside the frame. A suitable provision was made for recirculation of the excess slurry from the inlet by means of a bypass valve. After filtration of the slurry, air compressor was used to dry the slurry inside the frames, which also aided in the formation of wet algal cakes. Then, the frames were separated; the algal cakes were scraped off manually and made into dry algal flakes by drying under sun light for 3 days.
4.9. Hydro Thermochemical Liquefaction (HTL)
The biomass of diatoms collected in this study was subjected for the reaction of hydro thermochemical liquefaction. Hydro thermochemical liquefaction process was conducted using 1.1 L capacity Inconel high-pressure reactor (reliance, floor stand model). After adding the algal slurry to the reaction vessel, the reactor was tightly closed and conducted the experiment at different temperatures, pressures, and durations. An impeller type of agitation device at 250 rpm stirred the reaction mixture to ensure homogeneous reactions.
At the end of reaction, the samples were cooled to room temperature and collected in a separating funnel, and the biocrude was allowed to settle. The solid phase at the bottom of the separating funnel was collected and extracted three times washed with water in dichloromethane (1:1
v/
v) and recovered hydrocarbons. The dichloromethane fractions were pooled and evaporated using a distillation setup at 39 °C to obtain biocrude. The yield of biocrude fraction was expressed as percentage and estimated for its elemental composition such as C, H, N, O, and S using Elemental Analyzer (Vario EL III, Elementar India Pvt. Ltd., Gurugram-122002, Haryana, India). The Gross Calorific Value/Higher Heating Value (HHV) was calculated according to Dulong’s formula [
26]. HHV (MJ/kg) = 0.338C + 1.428 (H O/8) + 0.095.
4.10. Effect of Different Temperatures, Durations, and Pressure on Biocrude Yield of A. coffeaeformis RR03
The biomass of A. coffeaeformis RR03 obtained from 10.0 m2 openraceway pond (without CO2 supplementation being taken, 80 g of dry biomass was added with 400 mL distilled water (1:5 w/v) and kept at different temperatures such as, 280, 300, 330, and 350 °C; duration of each 15 min: and pressures such as, 70.6, 97.5, 141.1, and 171.1 psi, respectively, and subjected to hydro thermochemical liquefaction process. The values of biocrude were expressed in terms of percentage /ash free biomass).
4.11. Direct Biomass Acid Transesterification
Direct transesterification was carried out as per the method described by Johnson and Wen [
27]. Dry algal biomass of 100 g was added with 3.4 mL g
−1 of methanol and 0.6 mL g
−1 of sulphuric acid. To this sample, 4.0 mL g
−1 of each methanol, chloroform: methanol (2:1
v/
v), followed by hexane and petroleum ether, was added. The reaction mixture was kept at 90 °C in a water bath for 40 min, and it was thoroughly mixed intermittently during heating. Then, the mixture was allowed to cool at room temperature, 2.0 mL g
−1 distilled water was added and mixed for 45 s, and the samples were allowed for separation of different phase. The biodiesel (FAME) was separated in the solvent layer, which was collected and transferred to a pre weighed glass vial. The solvent was evaporated using liquid N
2, and the quantified amount of biodiesel gravimetrically and its fatty acid composition were analysed by GC-MS.