Selective extraction of neutral lipid from wet algae paste and subsequently hydroconversion into renewable jet fuel

Accepted Manuscript Selective extraction of neutral lipid from wet algae paste and subsequently hydroconversion into renewable jet fuel Chao Ju, Feng Wang, Yong Huang, Yunming Fang PII:

S0960-1481(17)31130-8

DOI:

10.1016/j.renene.2017.11.028

Reference:

RENE 9430

To appear in:

Renewable Energy

Received Date: 7 November 2016 Revised Date:

25 July 2017

Accepted Date: 11 November 2017

Please cite this article as: Ju C, Wang F, Huang Y, Fang Y, Selective extraction of neutral lipid from wet algae paste and subsequently hydroconversion into renewable jet fuel, Renewable Energy (2017), doi: 10.1016/j.renene.2017.11.028. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

SC

Ethanol Neutral lipids

Water

Hexane

Ethanol

AC C

EP

TE D

Polar lipid

Wet algae paste

M AN U

Neutral lipids

Others

Polar lipids

RI PT

ACCEPTED MANUSCRIPT

Pt/meso-ZSM-5

Neutral Jet fuel lipid Hydro-cracking

ACCEPTED MANUSCRIPT

1

Selective extraction of neutral lipid from wet algae paste and

2

subsequently hydroconversion into renewable jet fuel ∗

3 4 5

National Energy Research Center for Biorefinery, Beijing University of Chemical Technology, 100029, Beijing, China

6

Abstract: Wet algae paste, after harvested, was converted into renewable jet fuel through

7

selective extraction and subsequent hydroconversion without further purification. A

8

fractional extraction method based on ethanol and hexane starting from wet algae was

9

firstly designed and investigated. The oil recovery was as high as 90 wt.% of lipid after

10

three extraction cycles. Such a method results in fractional extraction of polar lipid and

11

neutral lipid separately from wet algal biomass. The obtained neutral lipid rich fraction

12

has very low metal content, in which the Ca, Mg, and Cu contents are 2, 0, and 3 mg/kg,

13

respectively. It can be converted into jet fuel range paraffin by one-step hydrocracking

14

over Pt/Meso-ZSM-5 catalyst directly. The freeze point, flash point, and energy density

15

of the obtained jet fuel are -57 °C, 42 °C, and 45 MJ/kg, respectively, which satisfies the

16

ASTM 7566 standard and can be used as high quality jet fuel blend.

17

Keywords: Wet algae paste, fractional extraction, direct hydroconversion, Pt/Meso-

18

ZSM-5 catalyst

AC C

EP

TE D

M AN U

SC

RI PT

Chao Ju, Feng Wang, Yong Huang, Yunming Fang

19 20 21 22 ∗

Corresponding author. Tel. & Fax:+86-10-64429057 E-mail address: [email protected] (Yunming Fang)

1

ACCEPTED MANUSCRIPT

23

1. Introduction The exploration of an alternative jet fuel has been drawing worldwide attention

25

because of the double threats of oil shortage and environmental concerns [1]. The levy of

26

carbon tax further accelerates the development of renewable jet fuel. As the only

27

renewable carbon-containing source in the world, the production of jet fuel from biomass

28

becomes one of the most promising routes [2]. Algae are potentially very promising

29

biomass feedstock due to their fast growth rate and high per-acre productivity [3].

SC

RI PT

24

The biochemical composition of algae is conventionally classified to lipids,

31

carbohydrates, proteins, and nucleic acids [3, 4]. Based on their molecular information,

32

lipids such as triglycerides, free fatty acids, phospholipids, and glycolipids have high

33

potential to be an alternative fuel. For instance, triglycerides could be converted to jet

34

fuel by combination of hydrocracking and isomerization, and the products generated had

35

suitable properties and were compatible with current infrastructure [5]. Therefore,

36

extensive research works on the extraction of lipids, as one of the most important and

37

challenging steps in the production of algal biofuel, have been carried out [6-16]. These

38

works can be divided into the following catalogs: 1) application of commercial extraction

39

methods such as hexane extraction and mechanical express process used for terrestrial

40

oilseed plants; 2) co-solvent system (chloroform/methanol, hexane/ethanol, and so on)

41

extraction methods originally used for laboratory scale analyses [6-8]; 3) cell rupture

42

(ultrasonic or electromagnetic release) based extraction methods [9]; 4) employing high

43

pressure such as accelerated solvent extraction, subcritical water extraction, supercritical

44

methanol or carbon dioxide extraction, and so on [10-13]; 5) simultaneous lipid

45

extraction and transesterification [14-16]. Unfortunately, those above-mentioned methods

AC C

EP

TE D

M AN U

30

2

ACCEPTED MANUSCRIPT

are either poor in extraction yield or difficult for large scale industrial application.

47

Moreover, drying process, one of the most energy-intensive steps, is usually necessary

48

before the extraction. Development of high-efficient extraction for lipids without drying

49

step is thus essential.

RI PT

46

Most of the studies for algal jet fuel mainly focus on the conversion of extracted lipid

51

into jet fuel range acyclic paraffins (C9–C15) [17-19]. The existing process was often

52

divided into multi steps, including long-chain paraffins production and hydro-

53

isomerization/hydrocracking [20]. The production of long-chain alkane can further be

54

divided into hydrodeoxygenation and decarboxylation mechanisms [18]. However, the

55

multi-step process requires high investment for system equipment and consumes much

56

hydrogen (7-10% hydrogen of algal oil). Recently, Verma et al. proposed a single-step

57

process for conversion of algal lipid to jet fuel range paraffins using sulfide Ni-Mo

58

catalyst supported on semi-crystalline ZSM-5 with high surface area, and the yield of jet

59

range compounds from resultant paraffins was as high as 77% [1]. The single-step

60

process not only shortens the reaction pathway but also simplifies the operation. On the

61

other hand, the level of contaminants in the extracted lipids such as metals, phosphorous,

62

nitrogen, chlorine, and sulfur varies widely depends upon both methods of cultivation and

63

lipid extraction. Lipids rich in above contaminants present challenges for catalytic

64

processing without additional pretreatments, e.g., degumming processes, which lead to

65

additional cost for the whole algae to jet fuel process [21, 22].

M AN U

TE D

EP

AC C

66

SC

50

As discussed above, algal biofuel (including algal jet fuel) production chain covers a

67

series of unit operations. Up to date, a lot of researches have been working on separate

68

operations [23,24]. For example, research on drying step generally focused on the

3

ACCEPTED MANUSCRIPT

efficient energy input and drying reactor development but overlooked the influence of

70

drying step on the oil extraction step. Indeed, oil extraction starting form wet algae or

71

dried algae can be very different. Similarly, in the oil extraction, the influence of different

72

extraction steps on the processing ability of lipid product was not systematically studied.

73

Furthermore, the influence of algal feedstocks (such as ash, polar lipid, pigment and so

74

on) on jet fuel production was also not carefully studied. In an ideal case, these unit

75

operations such as drying, oil extraction, and processing should be considered together.

76

The boundary of different unit operations, which was largely overlooked currently,

77

should be studied in detail. With such a consideration, the wet algae paste was converted

78

into jet fuel through a combination of selective neutral lipid extraction and direct

79

hydroconversion processes in the paper.

80

2. Experimental

81

2.1 Materials

TE D

M AN U

SC

RI PT

69

Scendesmus dimorphus (SD) algae samples with aournd 75 wt% of water content

83

harvested from outdoor glass panel system were used in this work. The glass panel

84

system was constructed and equipped with CO2 supply pipelines and temperature control

85

system. Glass panels were placed in East–West orientation. The maximum culture

86

temperature in glass panels outdoors was around 38 °C by an internal thermal exchanger

87

connected to an evaporative cooling unit. Culture mixing and CO2 supply in panel system

88

were provided by air bubbles enriched with 2% CO2. Algae samples, after removed the

89

bulk water by centrifugation, were kept as 3–5 cm algae cake at -80 °C refrigerator until

90

use. The lipid content and subclass composition were determined according to reference

91

[8] and given in Table 1. Chemicals such as ethanol, hexane with HPLC grade, and

AC C

EP

82

4

ACCEPTED MANUSCRIPT

Chloroplatinic acid hydrate (H2PtCl6.xH2O, ≥99.9 % trace metals basis) were purchased

93

from Sigma-Aldrich and used as received without any further treatment. The mesoporous

94

ZSM-5 zeolite and Pt/Meso-ZSM-5 catalyst were synthesized according to pervious

95

publication [25]. Algal oil extracted from SD algae by chloroform/methanol mixture [8]

96

was used as reference.

97

2.2 Algal oil extraction

RI PT

92

The extraction was carried out as follows: pre-calculated amount of wet algae

99

biomass and ethanol solvent (6 mL/g dry algae) were added into an extraction autoclave

100

equipped with condenser, mechanical stirring, and thermocouple. The mixture was

101

extracted for 1 h under reflux conditions. After cooled to the room temperature, the

102

mixture was subjected to vacuum filtration and crude extract and residue were obtained.

103

The pore size of microporous membrane for filtration was 0.22 µm. The crude extract

104

was further separated to lipid fraction and non-lipid fraction by liquid-liquid extraction,

105

in which water and hexane were added to achieve a volume ratio of ethanol: hexane:

106

water at 1: 1: 1. The residue was subjected into a next sequential extraction. Two

107

sequential ethanol extraction cycles were used in this study, after which hexane

108

extraction cycle was employed. Two hexane extraction cycles were performed in Lab

109

scale experiment, while only one cycle was carried out for the neutral-lipid-rich algae.

M AN U

TE D

EP

AC C

110

SC

98

The total lipids of algae samples were analyzed in a chloroform–methanol–water

111

system according to Bligh and Dyer’s method and used as reference for the lipid recovery

112

calculation [5]. The pigment content was determined according to Wellburn’s method

113

[26]. Total lipids were further separated into neutral lipids and polar lipids by column

114

chromatography using silica gel (60–200 mesh) (Merck Corp., Germany) as previously

5

ACCEPTED MANUSCRIPT

described [19]: six volumes of chloroform to collect the neutral lipid class and six

116

volumes of methanol to collect the polar lipids. Each lipid fraction was transferred into a

117

pre-weighed vial, evaporated at 30 °C using a rotary evaporator (Büchi, Switzerland), and

118

then dried under high vacuum. The dried residue was placed under nitrogen and then

119

weighed. Fatty acid profile of lipids were quantified by GC/MS after derivatization into

120

fatty acid methyl esters using heptadecanoic acid (C17:0) as the internal standard [19].

121

The metal content of the extracted lipid sample was analyzed by ICP analysis. The

122

samples (solid algae or algal oil) were combusted in air at 800 °C to get the ash. The

123

obtained ash was dissolved in HNO3 solution for metal content test through ICP analysis.

124

The weight in all the steps was recorded carefully for the calculation of metal content.

125

The catalyst used for hydro-conversion was analyzed by high resolution TEM with a

126

JEOL 3010F microscope. The catalyst was dispersed in ethanol, and deposited on a holey

127

film supported on a lacey support films.

128

2.3 Hydroconversion of neutral fraction of algal lipid into jet fuel

TE D

M AN U

SC

RI PT

115

Hydroconversion was carried out in a fixed bed trickle reactor. The Pt-Meso-ZSM-5

130

catalyst (20-40 mesh, 2.5 mL) which the Pt content was 0.6 wt.% (determined by ICP

131

analysis), diluted with SiC (5 mL) to ensure sufficient catalyst-bed length and to improve

132

the reaction-heat transfer, was loaded into a stainless steel tubular reactor (1.5 cm in inner

133

diameter and 30 cm in length) [27]. Hydrogen pressure was controlled by a back pressure

134

regulator, gas flow was controlled by a mass flow controller, and catalyst bed

135

temperatures were monitored by thermocouples. A high pressure liquid metering pump

136

was used to maintain desired liquid flow. The gas-liquid mixture passed through the

137

pressure gas-liquid separator to separate gaseous fraction from liquid product. Gaseous

AC C

EP

129

6

ACCEPTED MANUSCRIPT

product was released to atmosphere by a gas-meter and analyzed using an Agilent GC

139

7890A, while liquid product was drained to the atmospheric separator in order to remove

140

trace amounts of gases. The reaction condition for all the catalytic hydrotreating

141

experiments was as follows: temperature, 375°C; pressure, 30 bar; LHSV, 1 h-1; and H2

142

to feed ratio (V/V), 1500 [28]. The liquid products were sampled after stabilization of

143

reaction conditions (12 h) in two-hour intervals and analyzed by off-line GC/MS analysis

144

after separation of the water phase. The reaction gases were analyzed using an Agilent

145

7890A equipped with a flame ionization detector (FID) and two thermal conductivity

146

detectors (TCD). The quality of obtained bio-jet fuel such as energy density, flash and

147

freeze points was analyzed by ASTM methods included in ASTM 7566.

M AN U

SC

RI PT

138

In order to confirm the reliable of experiment results. The oil extraction and

149

conversion experiments were carried out at least for twice. The results shown in Table

150

and Figures indicate the reliability of our experiment results since the standard errors in

151

most cases are less than 5%. And the catalytic performance of oil obtained in two

152

different batches used the same method were almost the same.

153

3 Results and discussion

154

3.1 Fractional extraction from wet algae biomass

EP

A method of algal oil fractional extraction from wet algae paste with aqueous

AC C

155

TE D

148

156

ethanol and hexane as solvents in different extraction steps was firstly designed and

157

inverstigated. The extraction performance of proposed ethanol/hexane extraction process

158

of algae is shown in Figure 1. It was found that the oil recovery was as high as 90 wt% of

159

lipid after three extraction cycles, which suggested the excellent extraction performance

160

of the proposed system [29]. As also shown in Figure 1, the lipid composition is changed

7

ACCEPTED MANUSCRIPT

with the extraction cycles. The results of column chromatography revealed that the

162

neutral lipid percentages in the crude extract were 12%, 57%, 93%, and 94% from the

163

first to fourth steps, respectively. The appearance of extract from each cycle was also

164

quite different. The extract from the first cycle was a dark black semi-solid after the

165

solvent was removed, while it was yellow liquid with good flow quality from the third

166

cycle (Figure S1 in supporting information). The difference in color of each extract was

167

further examined by a pigment content analysis. The ratios of carotenoid to chlorophyll

168

were 0.05, 0.27, 0.31, and 0.34 from the first to fourth cycles. The change in flow

169

property of each extract was explained by the different lipid composition. The very high

170

polar lipid content was the main reason for its semi-solid appearance since polar lipid is

171

generally considered as “gum” in the oil industry [30]. The fatty acid profile of each

172

crude extract was detected by GC/MS after it converted to fatty acid methyl ester. Similar

173

fatty acid composition was found to all extracts with 16:0, 16:1, 16:2, 18:0, 18:1, 18:2,

174

18:3, and 20:5 as the main components. The detail fatty acid profile of algal oil extracted

175

through this fractional extraction and reference method was shown in Table 2.

TE D

M AN U

SC

RI PT

161

Based on the results described above, it was concluded that polar and neutral lipid

177

fractions were separated during the extraction process, which were explained by the

178

change in the polarity of the solvent used in each extraction cycle. The solubility of polar

179

and neutral lipid in aqueous ethanol altered with different ethanol concentration [22]. It

180

needed to be noted that the sorption capacity of algae to solvent was quite high. In this

181

experiment, it was found that the algae cake retained solvent as much as 2 mL/g. In the

182

first extraction cycle, the strong polar solvent (~70% of aqueous ethanol solution)

183

selectively extracted polar lipid from algae. From the third extraction cycle, the neutral

AC C

EP

176

8

ACCEPTED MANUSCRIPT

lipid was miscible in the solvents mixture (ethanol and hexane) while the solubility of

185

polar lipid was limited. Thus neutral lipid was selectively extracted in the third and fourth

186

extraction cycles. Unlike the first and third extraction cycle, the second cycle obtained a

187

comparable polar lipid and neutral lipid content since the ethanol concentration is 92% in

188

this step which neither selectively extracted polar lipid nor neutral lipid. The second cycle

189

was thus considered to be a transition step with moderate neutral lipid (55%) in the crude

190

extract. That was also the reason why at least three extraction cycles were necessary in

191

the current extraction system. Since the solvent properties have large influence on the

192

extraction performance, it can be expected that the water content in algae paste have large

193

influence on the extraction performance. When compared with the objective outlined in

194

the DOE algal biofuel roadmap, our process met most of those criteria, such as efficient

195

extraction of algal oil from a water rich algae biomass, recovery of more than 85% lipid

196

as so on. With respect to the energy consumption criteria (15% of the final product

197

according to DOE), larger scale extraction experiments as well as process simulation

198

should be implemented before a scientific conclusion can be drawn [29].

199

3.2 Catalytic hydroconversion of neutral fraction of algal lipid into jet fuel range

200

paraffin

SC

M AN U

TE D

EP

Algal oil usually contains strong polar lipid and pigment, and the metal content is

AC C

201

RI PT

184

202

also high [31]. It was reported in bio-oil hydrogenation, the high metal content is the

203

main hindrance to the catalytic performance. The deposition of metal over catalyst

204

surface can poison the catalytic active sites, so that it has negative influence on the

205

catalytic performance. Removing the metal through ion-exchange and filtration can

206

dramatically improve the catalyst lifetime. Hence the metal contents in common algal

9

ACCEPTED MANUSCRIPT

lipid extracted by chloroform/methanol and in neutral lipid (lipid extracted with hexane)

208

extracted by our process were firstly studied. From Figure 2, it can be found the metal

209

content in common algal lipids extracted by mixture solvent are relatively high. The Ca,

210

Mg, and Cu contents are 1400, 820, and 200 mg/kg, while the Ca, Mg, and Cu contents in

211

neutral lipid are 2, 0, and 3 mg/kg, respectively.The reduced metal content can be

212

attributed to the formation mechanism of polar lipid and pigment since the metals are

213

always existed in polar lipid or pigments. The fractional extraction of neutral lipid

214

renders its lower metal content. The reduced metal content could have a positive point in

215

lipid hydroconversion.

M AN U

SC

RI PT

207

Verma et al. reported a mesoporous ZSM-5 supported Ni-Mo catalyst for one-step

217

conversion of lipid into jet fuel range paraffin and iso-paraffin [1]. Here in this paper, a

218

similar mesoporous ZSM-5 was synthesized and used as catalyst support. The

219

characterization results were shown in Figure 3. The X-ray diffraction (XRD) pattern of

220

the mesoporous ZSM-5 shows a typical XRD pattern that belongs to MFI structure.

221

Nitrogen sorption studies show a type IV isotherm, which is typical for mesoporous

222

materials with both characteristics belonging to microporous materials and mesoporous

223

materials. HRTEM analysis proved the high crystalline of MFI zeolite nature since the

224

crystal lattice is clear visible. No diffractions belonging to Pt metal was found in the 1%

225

Pt/Meso-ZSM-5 bifunctional catalyst. The nitrogen adsorption isotherms are very similar

226

to that of parent mesoporous ZSM-5. The results shown in Table 3 indicate the textural

227

properties are little affacted after Pt deposition. The HRTEM images also proved the high

228

dispersion of Pt nanoparticles over the mesoporous ZSM-5 support. The size of Pt

229

particles is around 2~3 nm according to the TEM analysis.

AC C

EP

TE D

216

10

ACCEPTED MANUSCRIPT

The catalytic conditions for neutral lipid conversion were firstly optimized with

231

soybean oil as model compound. The optimized conditions (375 °C, 3 MPa, H2/oil=700)

232

were then used in the experiment with algal oil (hexane fraction) extracted in two

233

different batches. Figure 4 shows the comparison of the algal oil samples conversion over

234

the Pt/meso-ZSM-5. In the initial period, the catalyst was able to convert the lipid oil into

235

hydrocarbon with very high conversion at 375 °C. However, with the common lipid oil as

236

feedstock, the catalyst was deactivated within 10 h. Elemental analysis of the deactivated

237

catalyst indicated the deposition of Ca and Mg on the catalyst surface. The catalyst with

238

the extracted neutral lipid rich algal oil as feedstock can be operated stably for more than

239

100 h.

M AN U

SC

RI PT

230

The jet fuel yield from neutral lipid is 38 wt.%, which is a typical value due to the

241

loss of oxygen and hydrocracking nature. The overall algae to jet fuel yield is about 7%.

242

It should be noted our report here focuses on the process ability of extracted algal oil rich

243

in neutral lipid. The overall performance of this process could be further improved if

244

more desired algae feedstocks and catalytic materials was developed and used. Figure 5

245

gives the hydrocarbon distribution of the jet fuel product from algal oil. It can be found

246

the carbon chain of isomers distributes uniformly between C9 and C15, and the jet fuel

247

sample is rich in iso-paraffin. The iso-paraffin is ideal as jet fuel due to its low freezing

248

point. The jet fuel product from neutral lipid meets most of the standard of ASTM 7566

249

as alternative aviation fuel including the desired freezing point (-57 °C), density (0.74

250

g/mL), flash point (42 °C), heat of combustion (45 MJ/kg), and aromatics content (<1%).

251

The density (0.735 g/mL) is slightly lower than the required value in ASTM 7566

252

specification [32]. However, the low density is a general limitation of iso-paraffin as jet

AC C

EP

TE D

240

11

ACCEPTED MANUSCRIPT

253

fuel, and this can be improved to meet the specification requirement by addition of

254

aromatics and cycloalkane.

255

4. Conclusion

RI PT

The following conclusions can be derived from the present study:

256

1)

258

fractional separation of polar and neutral lipids. This fractional extraction system meets

259

most of the criteria recommended in DOE roadmap.

260

2)

261

metal content than the oil extracted from typical mixture solvent system, and results in

262

stable conversion (100 h) over Pt/Meso-ZSM-5.

263

3)

264

57 °C, 42 °C, and 45 MJ/kg, respectively, which satisfies the ASTM 7566 standard and

265

can be used as high quality jet fuel blend.

M AN U

The neutral lipid rich algal oil extracted by fractional extraction system has lower

EP

TE D

The freeze point, flash point, and energy density of the obtained jet fuel are -

AC C

266

Sequential extraction of wet algae paste with ethanol and hexane result in the

SC

257

12

ACCEPTED MANUSCRIPT

Reference

268

[1] D. Verma, R. Kumar, B.S. Rana, A.K. Sinha, Aviation fuel production from lipids by

269

a single-step route using hierarchical mesoporous zeolites, Energ. Environ. Sci. 4 (2011)

270

1667-1671.

271

[2] J.Q. Bond, A.A. Upadhye, H. Olcay, G.A. Tompsett, J. Jae, R. Xing, et al. Production

272

of renewable jet fuel range alkanes and commodity chemicals from integrated catalytic

273

processing of biomass, Energ. Environ. Sci. 7 (2014) 1500-1523.

274

[3] P.J.L. Williams, L.M.L. Laurens, Microalgae as biodiesel & biomass feedstocks:

275

Review & analysis of the biochemistry, energetics & economics, Energ. Environ. Sci. 3

276

(2010) 554-590.

277

[4] A.L. Ahmad, N.H.M. Yasin, C.J.C. Derek, J.K. Lim, Microalgae as a sustainable

278

energy source for biodiesel production: A review, Renew. Sust. Energ. Rev. 15 (2011)

279

584-593.

280

[5] Z. Eller, Z. Varga, J. Hancsok, Advanced prduction process of jet fuel components

281

from technical grade coconut oil with special hydrocracking, Fuel 182 (2016) 713-720.

282

[6] E.G. Bligh, W.J. Dyer, A rapid method of total lipid extraction and purification,

283

Canadian Journal of Biochemistry and Physiology 37 (1959) 911-917.

284

[7] A.R. Fajardo, L.E. Cerdan, A.R. Medina, F.G.A. Fernandez, P.A.G. Moreno, E.M.

285

Grima, Lipid extraction from the microalga Phaeodactylum tricornutum, Eur. J. Lipid Sci.

286

Tech. 109 (2007) 120-126.

287

[8] A. Hara, N.S. Radin, Lipid extraction of tissues with a low-toxicity solvent,

288

Analytical Biochemistry 90 (1978) 420-426.

AC C

EP

TE D

M AN U

SC

RI PT

267

13

ACCEPTED MANUSCRIPT

[9] N. Samarasinghe, S. Fernando, R. Lacey, W.B. Faulkner, Algal cell rupture using

290

high pressure homogenization as a prelude to oil extraction, Renew. Energ. 48 (2012)

291

300-308.

292

[10] B.E. Richter, B.A. Jones, J.L. Ezzell, N.L. Porter, N. Avdalovic, C. Pohl,

293

Accelerated Solvent Extraction:  A Technique for Sample Preparation, Analytical

294

Chemistry 68 (1996) 1033-1039.

295

[11] M. Herrero, A. Cifuentes, E. Ibañez, Sub- and supercritical fluid extraction of

296

functional ingredients from different natural sources: Plants, food-by-products, algae and

297

microalgae: A review, Food Chemistry 98 (2006) 136-148.

298

[12] M.H. Eikani, F. Golmohammad, S. Rowshanzamir, Subcritical water extraction of

299

essential oils from coriander seeds (Coriandrum sativum L.), J. Food Eng. 80 (2007) 735-

300

740.

301

[13] O. Guclu-Ustundag, J. Balsevich, G. Mazza, Pressurized low polarity water

302

extraction of saponins from cow cockle seed, J. Food Eng. 80 (2007) 619-630.

303

[14] E.M. Grima, A.R. Medina, A.G. Giménez, J.A. Sánchez Pérez, F.G. Camacho, J.L.

304

García Sánchez, Comparison between extraction of lipids and fatty acids from microalgal

305

biomass, J. Am. Oil Chem. Soc. 71 (1994) 955-959.

306

[15] G. Lepage, C.C. Roy, Improved recovery of fatty acid through direct

307

transesterification without prior extraction or purification, J. Lipid Res. 25 (1984) 1391-

308

1396.

309

[16] J. Rodríguez-Ruiz, E.-H. Belarbi, J. Sánchez, D. Alonso, Rapid simultaneous lipid

310

extraction and transesterification for fatty acid analyses, Biotechnology Techniques 12

311

(1998) 689-691.

AC C

EP

TE D

M AN U

SC

RI PT

289

14

ACCEPTED MANUSCRIPT

[17] Y.C. Sharma, B. Singh, J. Korstad, A critical review on recent methods used for

313

economically viable and eco-friendly development of microalgae as a potential feedstock

314

for synthesis of biodiesel, Green. Chem. 13 (2011) 2993-3006.

315

[18] J. Fu, C.Y. Yang, J.H. Wu, J.L. Zhuang, Z.Y. Hou, X.Y. Lu, Direct production of

316

aviation fuels from microalgae lipids in water, Fuel 139 (2015) 678-683.

317

[19] N.H. Tran, J.R. Bartlett, G.S.K. Kannangara, A.S. Milev, H. Volk, M.A. Wilson,

318

Catalytic upgrading of biorefinery oil from micro-algae, Fuel 89 (2010) 265-274.

319

[20] A. Galadima, O. Muraza, Catalytic upgrading of vegetable oils into jet fuels range

320

hydrocarbons using heterogeneous catalysts: A review, J. Ind. Eng. Chem. 29 (2015) 12-

321

23.

322

[21] F. Marrakchi, K. Kriaa, B. Hadrich, N. Kechaou, Experimental investigation of

323

processing parameters and effects of degumming, neutralization and bleaching on

324

lampante virgin olive oil's quality, Food Bioprod Process 94 (2015) 124-135.

325

[22] F.Y. Jiang, J.M. Wang, I. Kaleem, D.Z. Dai, X.H. Zhou, C. Li, Degumming of

326

vegetable oils by a novel phospholipase B from Pseudomonas fluorescens BIT-18,

327

Bioresource Technol. 102 (2011) 8052-8056.

328

[23] J.J. Milledge, S. Heaven, A review of the harvesting of micro-alage for biofuel

329

production, Rev. Environ. Sci. Bio. 12 (2013) 165-178.

330

[24] J. Ruiz, G Olivieri, J. de Vree, R. Bosma, P. Willems, J.H. Reith, M.M. Eppink,

331

D.M.M. Kleinegris, R.H. Wijffels, M.J. Barbosa, Towards industrial products from

332

microalgae 9 (2016) 3036-3043.

AC C

EP

TE D

M AN U

SC

RI PT

312

15

ACCEPTED MANUSCRIPT

[25] M. Li, I.N. Oduro, Y. Zhou, Y. Huang, Y. Fang, Amphiphilic organosilane and seed

334

assisted hierarchical ZSM-5 synthesis: Crystallization process and structure, Micropor.

335

Mesopor. Mat. 221 (2016) 108-116.

336

[26] A.R. Wellburn, The spectral determination of chlorophylls a and b, as well as total

337

carotenoids, using various solvents with spectrophotometers of different resolution, J.

338

Plant Physiol 144 (1994) 307-313.

339

[27] Y. Wang, T. He, K. Liu, J. Wu, Y. Fang, From biomass to advanced bio-fuel by

340

catalytic pyrolysis/hydro-processing: Hydrodeoxygenation of Bio-oil derived from

341

biomass catalytic pyrolysis, Bioresource Technol. 108 (2012) 280-284.

342

[28] C. Ju, Y. Zhou, M. He, Q. Wu, Y. Fang, Improvement of selectivity from lipid to jet

343

fuel by rational integration of feedstock properties and catalytic strategy, Renew. Energy

344

97 (2016) 1-7.

345

[29] J. Ferrell, V. Sarisky-Reed, National Algal Biofuels Technology Roadmap. United

346

States: N. p., 2010. Web. doi:10.2172/121856.

347

[30] A.J. Dijkstra, O.M. Van, The total degumming process. J. Am. Oil Chem. Soc. 66

348

(1989) 1002-1009.

349

[31] C. Wang, J.S. Buchanan, W.R. Kliewer, K. Qian, Water-washing to reduce metals in

350

oils extracted from Nannochloropsis algae for potential FCC feedstock, Fuel 155 (2015)

351

63-67.

352

[32] Standard Specification for Aviation Turbine Fuel Containing Synthesized

353

Hydrocarbons, http://www.astm.org/Standards/D7566.htm.

AC C

EP

TE D

M AN U

SC

RI PT

333

354

16

ACCEPTED MANUSCRIPT

Table 1. The lipid class percentage in different algal oil samples*1 Oil samples

Neutral lipid/%

Polar lipid/%

Free fatty acid/%

Algae2

67±0.2

27±0.2

6±0

65±0.3

28±0.1

8±0.2

97±0.1

2±0.03

Oil extracted by common method Oil extracted by fractional method

RI PT

355

1±0.05

*1 Results were expressed in mean ± standard error from duplicate analyses.

357

*2 25% total lipid content

SC

356

AC C

EP

TE D

M AN U

358

17

ACCEPTED MANUSCRIPT

Table 2. Fatty acid profile of algal oil (total lipid) extracted through this fractional extraction and reference method Extraction method

16:0

16:1

18:0

18:1

18:2

18:3

20:0

20:1

Others

Reference/%

36.2

2.87

3.3

24.5

19.2

11.1

0.71

1.11

1.01

Fractional/%

35.8

3.1

3.2

23.7

18.7

12.3

361

0.57

AC C

EP

TE D

M AN U

SC

362

RI PT

359 360

18

1.31

1.32

ACCEPTED MANUSCRIPT

Table 3. Textural and chemical properties of Meso-ZSM-5 and Pt/Meso-ZSM-5 SBET

V meso

Vmicro

V total

(mL/g)

(mL/g)

(mL/g)

4.73

0.47

0.08

0.55

4.52

0.47

0.07

0.54

2

Dpore (nm)

Meso-ZSM-5

483

Pt/Meso-ZSM-5

479

Zeolite

(m /g)

AC C

EP

TE D

M AN U

SC

364 365

RI PT

363

19

ACCEPTED MANUSCRIPT

Neutral lipid Neutral lipid

Polar lipid Polar lipid

100

80

16

RI PT

14

Lipid recovery (% of Lipid)

18

12

60

10 8

40

6 4

20

2 0

SC

Lipid recovery (% of DW)

20

Total lipid Total lipid

0

1

2

3

M AN U

Extraction cycle

4

Figure 1. Algal oil extraction performance with ethanol/hexane solvent system. The total,

367

polar and neutral lipid recovery to lipid are calculated with the overall total lipid, polar

368

lipid and neutral lipid as 100%, respectively. Results were expressed in mean ± standard

369

error from duplicate extraction. The left y-axis corresponds to the bar graph, and the right

370

y-axis corresponds to the line graph.

AC C

EP

TE D

366

20

ACCEPTED MANUSCRIPT

1600

Oil extracted by common method Oil extracted by fractional method

6 4

800

2 0

Ca

Mg

Cu

SC

400

RI PT

8

0 Ca

M AN U

Metal content (ppm)

1200

Mg

Cu

Metals

Figure 2. Difference of metal content of algal oil in reference sample and oil extracted by

372

the developed fractional approach. Results were expressed in mean ± standard error from

373

duplicate extraction.

EP AC C

374

TE D

371

21

ACCEPTED MANUSCRIPT

Meso-ZSM-5

500

400

Pt/Meso-ZSM-5 300

200

Meso-ZSM-5

100

0 10

20

30

40

50

0.0

0.2

0.4

0.6

0.8

1.0

Relative Pressure (P/P0)

TE D

M AN U

SC

2θ (degree)

RI PT

Pt/Meso-ZSM-5

Volume Adsorbed (cm3/g, STP)

Intensity (a.u.)

600

Figure 3. XRD patterns (a) and nitrogen adsorption isotherms (b) of Meso-ZSM-5 and

376

Pt/Meso-ZSM-5 (The y axis offset of Pt/Meso-ZSM-5 in (b) is 150 cm3/g, respectively);

377

HRTEM images of the synthetic Meso-ZSM-5 (c) and Pt/Meso-ZSM-5 (d)

AC C

378

EP

375

22

ACCEPTED MANUSCRIPT

Oil extracted by fractional method

RI PT

90

80

70

1st run 2nd run 3rd run

Oil extracted by common method

60 0

20

40

60

SC

Conversion (%)

100

80

100

379

M AN U

Time on Stream (h)

Figure 4. Catalytic performance of the algal oil samples over the Pt/Meso-ZSM-5

381

catalyst. Catalytic conversion was repeatedly investigated using neutral lipid rich algal oil

382

extracted from two different batches.

EP AC C

383

TE D

380

23

ACCEPTED MANUSCRIPT

20 18

14

RI PT

Relative content (%)

16

12 10 8 6

SC

4 2

iC 9 nC 9 iC 10 nC 10 iC 11 nC 11 iC 12 nC 12 iC 13 nC 13 iC 14 nC 14 iC 15 nC 15 iC 16 nC 16

M AN U

0

Carbon number

384

Figure 5. Carbon chain length of jet fuel products from neutral lipid rich algal oil

AC C

EP

TE D

385

24

ACCEPTED MANUSCRIPT

Highlights
Algal oil was extracted directly from wet algae with high efficiency (>90%)
Fractional extraction achieved with renewable ethanol and hexane as solvent

RI PT


Neutral lipid rich oil has very low metal content

AC C

EP

TE D

M AN U

SC


Neutral lipid rich oil was directly converted into jet fuel over Pt/Meso-ZSM-5