C as catalyst under ambient conditions in water

Accepted Manuscript Ultrasound assisted selective catalytic transfer hydrogenation of soybean oil using 5% Pd/C as catalyst under ambient conditions in water Sonam V. Sancheti, Parag R. Gogate PII: DOI: Reference:

S1350-4177(17)30096-2 http://dx.doi.org/10.1016/j.ultsonch.2017.03.004 ULTSON 3581

To appear in:

Ultrasonics Sonochemistry

Received Date: Revised Date: Accepted Date:

31 December 2016 5 March 2017 5 March 2017

Please cite this article as: S.V. Sancheti, P.R. Gogate, Ultrasound assisted selective catalytic transfer hydrogenation of soybean oil using 5% Pd/C as catalyst under ambient conditions in water, Ultrasonics Sonochemistry (2017), doi: http://dx.doi.org/10.1016/j.ultsonch.2017.03.004

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1 1

Ultrasound assisted selective catalytic transfer hydrogenation of soybean oil using 5%

2

Pd/C as catalyst under ambient conditions in water

3 4 5 6 7

Sonam V. Sancheti, Parag R. Gogate*

8 9 10 11 12

Chemical Engineering Department,

13

Institute of Chemical Technology,

14

Matunga, Mumbai – 400 019, India

15 16 17 18 19 20 21

*

22

E-mail address: [email protected]

23

Tel.: +91 22 3361 2024

24 25

Corresponding author

Fax: +91 22 3361 1020

2 26

Abstract

27

Catalytic transfer hydrogenation (CTH) is an alternative approach that does not require the

28

use of potentially dangerous hydrogen gas. Pd/C is the most favoured catalyst for the

29

selective hydrogenation of soybean oil yielding lower extent of formation of stearic acid and

30

trans-isomer, which have adverse health effects. The present work deals with intensification

31

of catalytic transfer hydrogenation of soybean oil in the presence of 5 wt. % Pd/C using

32

ultrasound under ambient reaction conditions. The effect of important operating parameters

33

such as ultrasound power, temperature, type of hydrogen donor, type of formic acid salts,

34

catalyst loading and donor concentration on the progress of reaction has been investigated. It

35

was established that the maximum extent of hydrogenation as indicated by reduction in

36

iodine value from 135 to 95 was observed under optimized conditions of irradiation power as

37

100 W, 22 kHz frequency, 90% duty cycle, ammonium formate concentration of 0.32 mol /

38

50 ml water and 2% (w/w) Pd/C loading at ambient temperature and pressure in the presence

39

of solvent. The approach also offered excellent selectivity with controlled trans-isomer

40

formation as compared to the conventional approach of high pressure hydrogenation. Overall,

41

the work has successfully demonstrated process intensification benefits based on ultrasound

42

for the Pd/C catalysed transfer hydrogenation of soybean oil.

43 44

Keywords: Ultrasound; Physical effects; Catalytic transfer hydrogenation (CTH); Soybean

45

oil; heterogeneous catalyst

46 47 48 49

3 50

1. Introduction

51

Soybean oil consists of mainly triglycerides of saturated and unsaturated fatty acids,

52

particularly with chain length over the range of C16–C18. Hydrogenation of soybean oil is

53

important process in oleochemical industry because of the wide range of applications of the

54

obtained derivatives for the production of margarine, frying oils, etc. Hydrogenation of oil

55

leads to increased melting point, improved color and oxidation properties of soybean oil. The

56

selective reduction of linolenic acid (C18:3) in the soybean oil has a prime importance as it

57

alters the flavour reversion of oil. The quality and physical properties of the final product

58

obtained after hydrogenation are affected by the number of double bonds present in the oil

59

represented by the iodine value (IV) and also cis–trans-isomer content in the fatty acid. The

60

trans-isomer has been reported to be undesirable for human diet due to the adverse health

61

effects.

62

The catalytic transfer hydrogenation (CTH) is a safe, simple and eco-friendly method

63

compared to the conventional hydrogenation where hydrogen gas is used offering handling

64

problems due to the explosive nature of hydrogen gas. In the CTH approach, hydrogen gas is

65

replaced by hydrogen donors such as cyclohexadiene, hydrazine, formic acid, sodium

66

formate, ammonium formate, phosphinic acid or sodium hypophosphite in the presence of

67

suitable catalyst. Initial studies related to CTH were based on the use of homogeneous

68

catalyst. Fedeli et al. [1] investigated the use of homogeneous catalyst in the form of chelates

69

derived from the Schiff bases of the 2,2-dialkyl propylene-1,3-diamine with salicylaldehyde

70

for transfer hydrogenation of soybean oil. Typically, homogeneous catalyst offer

71

disadvantages due to separation and recycling issues and hence the focus shifted to the use of

72

heterogeneous catalyst offer advantage of comparatively easy recovery and recycle. Banerjee

73

et al. [2] investigated the transfer hydrogenation of 4-Nitrodiphenylamine in the presence of

74

two types of catalyst and reported that palladium is more active catalyst than Raney nickel.

4 75

Similarly, Zhang et al. [3] reported that Pd supported on activated carbon exhibits higher

76

activity for the catalytic transfer hydrogenation of phenol as compared to Pd nanoparticles

77

supported over other supports such as TiO2, Al2O3, TiO2-carbon composites. Tike et al. [4]

78

also studied the effect of using different catalysts such as Pd/Al2O3, Pd/C and Ru/C for

79

transfer hydrogenation of soybean oil and reported that 5 wt. % Pd/C has higher catalytic

80

activity as compared to other types investigated in the work. It was also reported that Pd/C as

81

catalyst resulted in the desired control over the formation of stearic acid as well as trans

82

isomer effectively enabling selective hydrogenation of edible oils as compared to the

83

conventional high pressure hydrogenation approach. It is also important to understand that

84

some of the hydrogen transfer agents require high temperatures for appreciable conversion

85

making the overall costs much higher. For example, Šmidovnik et al. [5] reported that

86

catalytic transfer hydrogenation of soybean oil in water using 10 wt. % Pd/C catalyst and

87

sodium formate as hydrogen donor was more effective at higher temperatures (investigations

88

over the range of 50-80°C). Tike et al. [4] also reported that as temperature increases the

89

extent of hydrogenation increases. Apart from temperature and catalyst, the type of hydrogen

90

donor and solvent also plays a major role in deciding the progress of the reaction. Šmidovnik

91

et al. [6] studied selective transfer hydrogenation of soybean oil over Pd/C catalyst in various

92

solvents using different hydrogen donors and reported that best results were obtained in

93

aqueous solution with sodium formate as hydrogen donor. Šmidovnik et al. [7] investigated

94

the kinetics of selective transfer hydrogenation using sodium formate as hydrogen donor at

95

different concentrations and also studied the effect of addition of emulsifier. The main focus

96

was on understanding the effect of donor concentration and the role of diffusion effects. It has

97

been observed that CTH processing typically requires higher temperature and also much

98

higher reaction times. Thus, the use of process intensification approaches with possible

99

benefits of reduced reaction times and temperatures can make the process efficient and

5 100

economical. Considering these aspects, the present work has focused on the use of ultrasound

101

as a process intensification approach for CTH based on the use of Pd/C as the catalyst, which

102

forms the main novelty of the present work.

103

Use of ultrasound offers immense potential as process intensification approach based

104

on the physical and chemical effects generated due to cavitation induced by the passage of

105

ultrasound. Typically, ultrasound is propagated via a series of compression and rarefaction

106

cycles induced in the molecules of the liquid medium. At sufficiently high power, the

107

negative pressure in the rarefaction cycle exceeds the attractive forces of the molecules of the

108

liquid required to hold them intact and cavities are formed. These cavities grow over a few

109

cycles taking in some vapour from the medium (rectified diffusion) and reach an equilibrium

110

size where the frequency of bubble resonance matches the applied sound frequency. The

111

acoustic field experienced by the bubble is not stable because of the interference of other

112

bubbles, which are continuously forming, growing or resonating. As a result, some bubbles

113

after expansion to an unstable size collapse violently generating intense local heating and

114

high pressures for very short lifetimes [8]. In addition to the generation of extreme conditions

115

within the bubble, there are also dominant physical effects produced as a result of the rapid

116

collapse of the cavitating bubble. The physical effects such as liquid streaming and

117

turbulence can break the agglomerates of solid and also remove the passive layers of

118

materials to give a larger and active surface area for the reaction to progress at faster rate [9-

119

10]. Due to these reasons, application of ultrasound can give intensified processing (lower

120

reaction times) under mild reaction conditions and with no/minimum side reactions leading to

121

higher selectivity and yields for the desired product. Many catalytic, non-catalytic organic

122

reactions have been reported to be intensified successfully using ultrasound [8, 10]. For

123

example, Xun et al. [11] investigated the ultrasound assisted hydrogenation of nitroarenes to

124

corresponding N-arylhydroxylamines using zinc as catalyst and ammonium formate as

6 125

hydrogen donor in acetonitrile under ambient conditions. An analysis of the literature also

126

revealed that there is not much literature available on ultrasound assisted catalytic transfer

127

hydrogenation of vegetable oils based on the use of Pd/C catalyst (which has been reported to

128

be most effective catalyst for conventional processing as discussed earlier). Also there has not

129

been much study dealing with understanding the effect of operating parameters or the

130

processing strategy to control the amount of stearic acid and trans-isomer formation.

131

Considering this analysis, the present work deals with an in depth study into understanding

132

the effect of operating parameters such as ultrasound power, temperature, type of donors,

133

donor concentration and catalyst loading on the progress of reaction including the analysis of

134

the trans-isomer formation.

135 136

2. Materials and methods

137

2.1 Materials

138

The refined soybean oil, obtained from Sahkari Bhandar, Matunga, Mumbai, India was used

139

for hydrogenation. The catalyst Pd/C (5 wt. % loading) with matrix activated carbon support

140

was obtained from Sigma Aldrich, India. The hydrogen donors (ammonium formate,

141

potassium formate, sodium formate and formic acid), Wij’s solution (1N), carbon

142

tetrachloride (AR), potassium iodide, sodium thiosulphate were obtained from S.D. fine

143

chemicals, Mumbai All chemicals and solvents used for product analysis were of high purity,

144

and used as received without any further processing.

145 146

2.2 Experimental procedure

147

0.012 mol (10.8-11 gm) of soybean oil and 0.32 mol of donor dissolved in 50 ml water (20 g

148

of ammonium formate in 50 ml water) were taken in a glass round bottom flask. The flask

149

was immersed in a thermostatically controlled bath. 0.22 g of Pd/C catalyst (2% w/w of oil)

7 150

was added after the desired temperature was obtained. Reaction was carried out for 1h in the

151

presence of mechanical stirring using teflon impeller at constant speed of rotation as 400 rpm.

152

The progress of the hydrogenation reaction was monitored by determining the iodine value

153

(IV) and fatty acid composition of samples removed periodically during the process. The

154

iodine value is calculated using equation 1. Besides iodine value, gas chromatography (GC)

155

analysis of some samples at optimum conditions was also performed to determine the fatty

156

acid composition after hydrogenation. Iodine Value =

( B - S ) × N of Na2S2O3 × 0.127g/meq × 100

(1)

Weight of Sample (g)

157 158 159 160 161

Where, B: V ml of Na2S2O3 volume for blank S: V ml of Na2S2O3 volume for sample

162

Ultrasonic bath (Model 6.5l200 H, Dakshin, India, 4.5 L capacity) with the internal

163

dimensions of 300 mm × 150 mm × 150 mm and four transducers placed at the bottom was

164

used as a source of ultrasonic irradiations in the present study for the ultrasound assisted

165

approach. The reaction was performed in 50 mL round bottom flask equipped with teflon

166

impeller connected to glass rod. The whole assembly of the glass reactor was kept in the

167

ultrasonic bath having different operating frequency of 22 kHz and 40 kHz with maximum

168

rated power of 200 W. The position of the reactor in the ultrasonic bath was fixed at the

169

centre of the vessel as per the earlier results demonstrating maximum cavitational activity at

170

this position [12]. The effect of operating parameters was investigated by performing number

171

of experiments at different temperatures ranging between 30 to 70 °C and power dissipation

172

levels over the range of 40 W to 120 W using different hydrogen donors such as formic acid,

173

sodium formate, ammonium formate etc. The effect of different catalyst loading ranging from

8 174

1 % (w/w) to 2.5 % (w/w), donor concentration over the range of 0.16 mol/ 50 ml H2O to

175

0.40 mol/ 50 ml H2O as well as water content in reaction also been investigated.

176

During the catalytic transfer hydrogenation, following transformations are possible

177

though it is always desirable to have less amount of stearic acid as well as linolenic acid and

178

higher concentration of linoleic and oleic acid.

179

C(18:3)

C(18:2) + C(18:1) + C(18:0)

180

C(18:2)

C(18:1) + C(18:0)

181

C(18:1)

C(18:0)

C(18:3) C(18:2) C(18:1) C(18:0)

Linolenic acid Linoleic aid Oleic acid Stearic acid

182 183

2.3 Analysis

184

Samples were withdrawn at different time intervals during hydrogenation. The withdrawn

185

samples, which contain oil, were extracted with n-hexane and separated from the aqueous

186

phase. After filtration of the catalyst Pd/C, n-hexane was evaporated and the reaction

187

products were analyzed by Wijj’s method to find the iodine value (IV), which determines the

188

degree of unsaturation [13]. As hydrogenation occurs, IV typically decreases. For quantitative

189

analysis of the fatty acids, methyl esters were prepared from hydrogenated soybean oil using

190

BF3-Methanol and gas chromatographically analyzed using BPX-70 (70% cyanopropyl

191

polysilphenylene–siloxane)

192

chromatograph (model Chemito 1000, Chemito Technologies Pvt. ltd., Mumbai, India) with a

193

flame ionization detector (FID). The column was operated over the range of 120–230°C at

194

3°C/min rate with hydrogen as carrier gas. Injector ports and detector were held at 250 and

195

260°C, respectively. This analysis allowed establishing the data of all kinds of fatty acid

196

methyl esters and geometrical cis–trans isomers quantitatively. It is important to know the

197

concentration of cis and trans isomers separately as the formation of the trans isomer needs to

198

be avoided as it is hazardous to human health.

199

The changes in the morphology of the commercial catalyst used in the work before and after

capillary

column

(30m×0.32mm.)

mounted

on

gas

9 200

the application in the ultrasound assisted selective catalytic transfer hydrogenation reaction

201

were established using scanning electron microscopy (SEM) analysis. SEM was performed

202

using JSM 6360 model obtained from JEOL, Japan

203 204

3. Results and Discussion

205

3.1 Fatty acid composition and properties of refined soybean oil

206

The composition of the refined oil has been analyzed using GC before the actual

207

hydrogenation so as to compare with the composition after hydrogenation and establish the

208

formation of different products (Table 1). As per the data represented in the table, the oil

209

contains 22.4 % of oleic acid, 54.2 % of linoleic acid and 6% of linolenic acid. The iodine

210

value of refined oil before hydrogenation was established as 134.

211

3.2 Effect of ultrasonic power

212

In order to achieve efficient cavitation for the maximum intensification of catalytic transfer

213

hydrogenation reaction using optimized operating power, experiments were performed in

214

ultrasonic bath at different power dissipation levels over the range of 60 W to 120 W at fixed

215

frequency of 22 kHz, 90% duty cycle and temperature of 30°C. The progress of the

216

hydrogenation reaction was monitored by the reduction in iodine value (IV). Iodine value

217

typically decreases with an increase in the extent of hydrogenation. An increase in the

218

ultrasonic power typically enhances the number of active cavitation bubbles, which would

219

result in higher cavitational intensity and hence there should be an increase in the rate of

220

reactions. The obtained results for the effect of power dissipation have been shown in Fig. 1.

221

As the irradiation power increased from 60 W to 100 W, it was observed that the iodine value

222

decreased from 112.82 to 95.2. Further increase in power to 120 W resulted in a higher final

223

iodine value as 98.86. Considering this analysis, 100 W is considered as optimum power and

224

used for the further experiments. The existence of optimum can be attributed to the fact that

10 225

at significantly higher power dissipation levels, there is formation of large number of

226

cavitation bubbles in the liquid, which creates cushioning effect leading to less intensity of

227

collapse and also presents barrier to the acoustic energy transmission into the reaction

228

mixture leading to lower energy availability for the cavitational effects. Similar results of

229

reduced cavitational activity beyond the optimum power can also be observed in the literature

230

[10,14-15]. Ammar et al. [14] studied ultrasound assisted Knoevenagel condensation of

231

benzaldehyde with ethyl cyanoacetate and reported that an increase in power intensity till an

232

optimum level of 30% led to relatively higher yield and also helped in reducing reaction time.

233

The product yield was also reported to decrease slightly with a further increase in ultrasound

234

power intensity beyond 30%. Dange et al. [15] also investigated the effect of power

235

dissipation for the ultrasound assisted synthesis of methyl butyrate using amberlyst-15 as a

236

catalyst over the power range of 50 to 145 W at constant frequency of 22 kHz. It was

237

reported that the conversion increased drastically over the range of 50 to 100 W and beyond

238

100 W, lower conversion was observed attributed to poor propagation of ultrasound waves

239

through the reaction mixture.

240

3.3 Effect of hydrogen donor type

241

Effect of type of donor on CTH of soybean oil was studied using different hydrogen donors.

242

Experiments were conducted in ultrasonic bath with constant irradiation power of 100 W,

243

frequency of 22 kHz, temperature of 30°C and constant donor loading of 0.32 mol (20 g in 50

244

ml water). Typically formic acid and its salts or secondary alcohols have been reported to be

245

efficient hydrogen donors in the presence of palladium catalyst [16-17], mostly attributed to

246

the ease of availability and handling. Also, these salts are true hydrogen transfer agents (no

247

hydrogen gas is released in the course of the reactions, and thus stoichiometric amounts of

248

donor and acceptor can be used and no special safety precautions are necessary even in large-

249

scale applications). Fig. 2 depicts the observed results for the iodine value reduction using

11 250

different donors. It can be established from the figure that ammonium formate gives

251

minimum possible iodine value at the end of reaction amongst all the donors and hence can

252

be established as the best donor type. In the case of sodium and potassium formate, reaction

253

proceeds slowly as compared to ammonium formate which might be attributed to formation

254

of alkali salts in the reaction mixture (Na2CO3, K2CO3, NaHCO3, KHCO3), which might

255

affect adsorption of reactant and palladium hydride formation on the active catalyst [18].

256

Ammonium formate is also preferred over other salts of formic acid as it decomposes into H2,

257

CO2 and ammonia after reaction which can be easily washed out with water. Gaseous

258

ammonia evolved can be absorbed again in formic acid and recycled back for the reaction

259

[18]. An additional advantage of using ammonium formate would be that due to the higher

260

solubility in water, water can be used as solvent and can give a “greener” approach for

261

hydrogenation. Considering the best performance obtained with ammonium formate, it was

262

used as hydrogen donor for further experiments related to effect of donor loading on the

263

progress of reaction.

264

3.4 Effect of hydrogen donor loading

265

The donor loading is an important factor in deciding the progress of reaction, especially

266

considering the solubility in water which decides the availability of water taking part in the

267

reaction. Effect of donor loading was studied over the range of 0.16 mol/ 50 ml H2O to 0.40

268

mol/50 ml H2O at constant ultrasonic power of 100W, frequency of 22kHz, 90 % duty cycle,

269

temperature of 30°C with Pd/C loading as 2% (w/w) of soybean oil. Fig. 4 depicts the

270

reduction in iodine value with different initial concentrations of ammonium formate. It was

271

observed that as the quantum of donor increases the final iodine value decreases. Use of 0.16

272

mol/50 ml H2O and 0.24mol/ 50 ml H2O of ammonium formate resulted in much slower rate

273

of reaction. An increase in the donor concentration to 0.32 mol/ 50 ml water resulted in best

274

results but a further increase to 0.40 mol/ 50 ml water showed only marginal difference in the

12 275

final iodine values obtained at the end of reaction. At 0.40 mol/50 ml H2O concentration of

276

ammonium formate, the final iodine value was the minimum as 93.15. But from Table 2 it

277

can be also observed that an increase in the donor concentration from 0.32 mol/ 50 ml water

278

to 0.40 mol/ 50 ml resulted in slight increase in the stearic acid concentration. Considering

279

this analysis, 0.32 mol/ 50 ml water is considered as optimum donor loading for further sets

280

of experiments (higher stearic acid formation needs to be avoided).

281

3.5 Effect of temperature

282

Increase in temperature generally increases the kinetic rate constant in the conventional

283

reaction systems. On the other hand, the cavitational intensity is negatively affected by an

284

increase in the temperature and hence it is possible that an optimum temperature exists [10,

285

19]. The effect of temperature on ultrasound assisted CTH of soybean oil was studied by

286

conducting reactions at different temperatures as 30°C, 45°C, 60°C and 75°C (Fig. 4). Other

287

reaction conditions used for the study were ultrasonic power of 100W, frequency of 22 kHz,

288

duty cycle of 90%, ammonium formate loading of 0.32 mol/50 ml H2O and Pd/C loading of

289

2% (w/w) of soybean oil. It was observed that as temperature increased from 30°C to 60°C,

290

iodine value obtained after 1h decreased from 95.20 to 88.82. It was also observed from

291

results given in table 2 that minimum iodine value was obtained at high temperature but this

292

was also accompanied with higher amount of trans-isomer being formed, which is

293

undesirable. Also beyond 60°C, further increase in temperature to 75°C increased the final

294

iodine value to 90.00. The decrease in reaction rate above the temperature of 60°C can be

295

attributed to the fact that an increase in the temperature increases the vapour pressure of the

296

liquid medium leading to a less violent collapse [20]. Existence of optimum temperature has

297

also been reported for the conventional approach (without using ultrasound). Šmidovnik et al.

298

[6] investigated CTH at different temperatures and reported that under ambient conditions,

299

time required for achieving IV 90 was about 9 h, which decreased significantly with an

13 300

increase in the temperature till an optimum level. It was also reported that the minimum

301

formation of the trans-isomer dominated the selection of the optimum temperature.

302

3.6 Effect of catalyst loading

303

Pd/C is the most beneficial catalyst for the catalytic transfer hydrogenation [4]. The amount

304

of catalyst plays a very important role in deciding the progress of reaction and hence the

305

profitability of the process. In order to establish optimum amount of catalyst for maximum

306

benefits, experiments were performed at different catalyst loading ranging from 1 % (w/w) to

307

2.5 % (w/w) keeping all the other parameters constant. The obtained results are represented in

308

Fig. 5. It can be seen that as the catalyst loading increases, the final iodine value decreases

309

and the extent of decrease was significant till 2 % (w/w) catalyst loading. Iodine value after 1

310

h using 1% (w/w) catalyst loading was 109.96 and that obtained for 2 % (w/w) catalyst

311

loading was 95.20. Further increase in catalyst amount to 2.5 % (w/w) did not affect the

312

reaction rate significantly. At high solid loading there is a reduced transfer of ultrasound

313

energy due to attenuation and possible scattering of the incident waves which reduces the

314

cavitational intensity giving lower intensification effects and hence reduced conversion [15,

315

21]. Also there is a possibility of aggregation of catalyst particles decreasing the available

316

surface area [21]. Considering the results obtained in the study, catalyst loading of 2 % (w/w)

317

was established as the optimum.

318

3.7 Effect of water quantity

319

When transfer hydrogenation at an acceptor (A) is performed in an aqueous solution, water is

320

involved in the reaction mechanism to abstract CO2 as HCO3 as represented in the equations:

321 322

Effect of quantity of water was studied over the range of 20 to 80 ml and the obtained results

323

have been given in Fig. 6. It can be seen from the figure that increasing dilution of formate

14 324

solution using higher water resulted in higher reduction in the iodine value (IV) confirming

325

higher extent of hydrogenation. With 20 ml water, the IV after 1 h was 100.61 whereas for

326

the case of 80 ml water, the iodine value was 91.92. The reason of enhanced reaction is that

327

water serves as a medium for contact of the hydrogen donor with the metal and the substrate

328

by forming a thin film of formate solution on the surface of the catalyst [22]. It is also

329

important to understand that optimum water is required (though not observed in the present

330

study) as beyond the optimum loading, any excess water will compete with the donor for the

331

active sites on the catalyst surface leading to lower availability of donors and hence lower

332

rates [23].

333

3.8 Fatty acid composition analysis after the reaction

334

The quantitative analysis for the fatty acids after the reaction has been shown in Table 2.

335

Comparison of catalytical transfer hydrogenation experiments at different conditions was

336

performed in terms of the desired specification of the hydrogenated product. It was observed

337

that ultrasound assisted CTH process with 100 W, 30°C, 0.32 mol/ 50 ml water and 2%

338

(w/w) catalyst loading as the operating conditions resulted in the minimum quantum of trans-

339

isomer. It is well known that formation of trans-isomer increases with an increase in

340

temperature [4]. Consequently, the ultrasound assisted CTH process was found to be quite

341

good as it offered selective hydrogenation with lower trans-isomer compared to high pressure

342

catalytic hydrogenation, which is the conventional approach (Table 3).

343

3.9 Comparison of the ultrasound assisted CTH with the conventional approach

344

The obtained best conditions in the present work for the approach of ultrasound assisted CTH

345

were operating temperature of 30 °C, ammonium formate as the donor at loading of 0.32 mol/

346

50 ml water and catalyst loading of 2% (w/w). Under these operating conditions, the

347

maximum decrease in the iodine yield was observed to be from 135 to 95 in 60 min as the

348

reaction time. Under the conventional approach, as per the reports of Tike and Mahajani [4],

15 349

for obtaining similar reduction in the iodine value, the required time was 90 min and the

350

temperature was 90 °C. Considering this comparison, the clear process intensification

351

benefits from the use of ultrasound can be established as the reduction in the reaction time by

352

33% and significant reduction in the temperature (90 °C to 30 °C) which can direct toward an

353

economical process synthesis route. The use of ultrasound results in cavitating conditions and

354

mainly the physical effects as intense turbulence and liquid circulation are beneficial for

355

enhancing the rate of heterogeneously catalyzed CTH. The turbulence promotes the rate of

356

mass transfer of the reactants toward the catalytic surface and also helps in maintaining the

357

surface of the catalyst clean thereby giving enhanced reaction rates.

358

3.10 Effect of ultrasound on catalyst morphology

359

The changes in morphology of the commercial catalyst before and after the use in ultrasound

360

assisted selective catalytic transfer hydrogenation reaction were established using the SEM

361

analysis and obtained images have been represented in Fig. 7 (a & b). The comparison of the

362

two catalysts revealed that the particle size of spent catalyst was lower attributed to the

363

cavitation effects. A reduction in the particle size means that higher surface area of catalyst is

364

available leading to higher reaction rates. It can be also seen that the roughness of the catalyst

365

is increased which can lead to better adsorption characteristics and higher catalytic activity.

366

Besides these effects, no other significant differences in surface morphology of both the

367

catalysts were observed.

368

4. Conclusions

369

Ultrasound assisted CTH of soybean oil was successfully performed using Pd/C (5 wt.

370

% loading) with matrix activated carbon support as a catalyst and water as solvent.

371

Ammonium formate was found to be an effective hydrogen donor for the ultrasound assisted

372

CTH of soybean oil. Excellent progress of hydrogenation was observed even at 30°C which

373

is much lower compared to the conventional approach which requires 90° C for the reaction

16 374

to progress at sustainable rate. The best conditions for maximum benefits were irradiation

375

power of 100W, duty cycle of 90% with ammonium formate loading as 0.32 mol / 50 ml

376

water and 2% (w/w) Pd/C loading. It was also established that the optimum conditions should

377

not only give higher reduction in the iodine value but also minimum formation of the stearic

378

acid as well as trans – isomer. Effect of temperature clearly established that the desired

379

optimum to maintain minimum trans-isomer formation might lead to lower iodine value

380

reduction. It has been also demonstrated that ultrasound assisted approach offered good

381

selectivity giving complete reduction of linolenic acid with a slight formation of stearic acid

382

(within the acceptable limits). Also the formation of trans-isomers was lower during

383

ultrasound assisted CTH of soybean oil at ambient temperature as compared to the

384

hydrogenation using hydrogen which is typically performed under conditions of high

385

pressure and temperature. Overall, the work demonstrated effective approach of

386

intensification of CTH based on the use of ultrasound with excellent benefits in terms of

387

lower reaction time and temperature as well as more importantly the desired product

388

characteristics.

389 390

5. References

391

1.

392

Fette, Seifen, Anstrichm., 78 (1976) 30-34

393

2.

394

Reactions of 4-Nitrodiphenylamine, Appl. Catal. 59 (1990) l-12.

395

3.

396

phenol on supported Pd catalysts using formic acid as an alternative hydrogen source, Catal.

397

Today 234 (2014) 133–138.

E. Fedeli, G. Jacini, Homogeneous Selective Catalytic Hydrogenation of Soybean Oil,

A. A. Banerjee, D. Mukesh, Heterogeneous Catalytic Transfer Hydrogenation

D. Zhang, F. Ye, T. Xue, Y.Guan, Y. Meng, Y. Shanghai, Transfer hydrogenation of

17 398

4.

M. A. Tike, V. V. Mahajani Studies in catalytic transfer hydrogenation of soybean oil

399

using ammonium formate as donor over 5% Pd/C catalyst, Chem. Eng. J. 123 (2006) 31–41.

400

5.

401

soybean oil, Chem. Eng. J. 51(1993) B51–B56.

402

6.

403

Am. Oil Chem. Soc. 69 (1992) 405–409.

404

7.

405

hydrogenation of soybean oil, J. Am. Oil Chem. Soc. 71 (1994) 507–511.

406

8.

407

443-451.

408

9.

409

water or biphasic aqueous systems under sonochemical conditions : A review on catalytic

410

effects, Catal. Commun. 63 (2015) 2-9.

411

10.

412

chemical synthesis using ultrasound, Ultrason. sonochem. 36 (2017) 527-543.

413

11.

414

highly efficient reduction of nitroarenes to corresponding N-Arylhydroxylamines, Chem.

415

Res. Chinese Universities 25(2009), 183—188.

416

12.

417

extraction of mangiferin from Mangifera indica leaves, Ultrason. Sonochem. 21 (2014) 606–

418

611.

419

13.

420

Press, Oxford, (1979) pp. 42–48

A. Šmidovnik, I. Plazl, T. Koloini, Kinetics of catalytic transfer hydrogenation of

A. Šmidovnik, A. Stimac, J. Kobe, Catalytic transfer hydrogenation of soybean oil, J.

A. Šmidovnik, J. Kobe, S. Leskovsek, T. Koloini, Kinetics of catalytic transfer

T. J. Mason, Ultrasound in synthetic organic chemistry, Chem. Soc. Rev. 26 (1997)

G. Cravotto, E. Borretto, M. Oliverio, A. Procopio, A. Penoni, Organic reactions in

S. V. Sancheti and P. R. Gogate, A review of engineering aspects of intensification of

S. Q. Xun, L. Rong-wen, H. Xin-yu, L. Lian-hai and Z. Shu-fen, Ultrasound-assisted

V.M. Kulkarni, V.K. Rathod, Mapping of an ultrasonic bath for ultrasound assisted

C. Paquat, Standard Methods for the Analysis of Oils, Fats and Derivatives, Pergamon

18 421

14.

H. B. Ammar, M. Chtourou, M.H. Frikha, M. Trabelsi, Green condensation reaction

422

of aromatic aldehydes with active methylene compounds catalyzed by anion-exchange resin

423

under ultrasound irradiation, Ultrason. Sonochem. 22 (2015) 559–564.

424

15.

425

Butyrate using Heterogeneous Catalyst, Ultrason. Sonochem. 26 (2015) 257–264

426

16.

427

with alcohols, J. Am. Oil Chem. Soc., 43 (1966) 119-121.

428

17.

429

transfer from lithium formate in the presence of ruthenium and rhodium complexes,Croat.

430

Chem. Acta, 63 (1990) 203-206.

431

18.

432

solid sodium formate in the presence of palladium on carbon, J. Mol. Catal. 26 (1984) 321 –

433

326

434

19.

435

Eng. Chem. Res. 38 (1999)1215–1249.

436

20.

437

sonochemical reactors. Ultrason. Sonochem., 10 (2003) 325–330.

438

21.

439

synthesis from non-edible Schleichera triguga oil using heterogeneous catalyst : Kinetics and

440

thermodynamic analysis, Ultrason. Sonochem. 29 (2016) 288–298

441

22.

442

solvents in liquid-phase heterogeneous catalytic transfer reduction, Tetrahedron 48 (1992)

443

7735–7746

P. N. Dange, A. V. Kulkarni, V.K. Rathod, Ultrasound Assisted Synthesis of Methyl

H. N. Basu, M. M. Chakrabarty, Studies on conjugated hydrogenation: Nickel catalyst

R. Marčec, Catalytic hydro-dehalogenation of some organic halides by hydrogen

A. Zoran, Y. Sasson, Catalytic transfer hydrogenation of unsaturated compounds by

L. H. Thompson, L. K. Doraiswamy, Sonochemistry : Science and Engineering, Ind.

P. R.Gogate, A. M. Wilhelm, A.B. Pandit, Some aspects of the design of

A.N. Sarve, M.N. Varma, S.S. Sonawane, Ultrasound assisted two-stage biodiesel

A.F. Brigas, R.A.W. Johnstone, Metal- assisted reactions. Part 24. The importance of

19 444

23.

445

compounds by solid sodium formate in the presence of palladium on carbon. J. Mol. Cat. 26

446

(1984) 321-26

447

A. Zoran, Y. Sasson, J. Blum, Catalytic transfer hydrogenation of unsaturated

20 448

List of figures

449

Figure 1. Effect of ultrasound power on reduction in iodine value during ultrasound assisted

450

CTH of soybean oil. Frequency of 22 kHz, 90% duty cycle, temperature of 30°C, ammonium

451

formate concentration of 0.32 mol (20 g in 50 ml water), catalyst loading of 2% w/w of

452

soybean oil (0.22 g), soybean oil as 0.012 mol (10.8-11 ml).

453

Figure 2. Effect of type of donors on reduction in iodine value during CTH of soybean oil.

454

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

455

ammonium formate concentration of 0.32 mol/50 ml H2O, catalyst loading of 2% w/w of

456

soybean oil (0.22g), soybean oil as 0.012 mol (10.8-11 ml).

457

Figure 3. Effect of donor concentration on reduction in iodine value during CTH of soybean

458

oil. Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

459

ammonium formate as donor, catalyst loading of 2% w/w of soybean oil (0.22g), soybean oil

460

as 0.012 mol (10.8-11 ml).

461

Figure 4. Effect of temperature on reduction in iodine value during CTH of soybean oil.

462

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, ammonium formate

463

concentration of 0.32 mol/ 50 ml water, catalyst loading of 2% w/w of soybean oil (0.22g),

464

soybean oil as 0.012 mol (10.8-11 ml).

465

Figure 5. Effect of catalyst loading on reduction in iodine value during CTH of soybean oil.

466

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

467

ammonium formate concentration of 0.32 mol/ 50 ml water, Pd/C catalyst, oil (0.22g),

468

soybean oil as 0.012 mol (10.8-11 ml).

469

Figure 6. Effect of amount of water on reduction in iodine value during CTH of soybean oil.

470

Ultrasound power of 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

471

ammonium formate concentration of 0.32 mol, Pd/C catalyst, oil (0.22g), soybean oil as

472

0.012 mol (10.8-11 ml).

21 473

Figure 7. SEM images of Pd/C (5 wt% loading) with matrix activated carbon support. (a)

474

fresh catalyst (b) Spent catalyst after first cycle

475 476

List of tables

477

Table 1. Fatty acid composition and properties of refined soybean oil

478

Table 2. Effect of operating parameters and hydrogenation on the fatty acid composition as

479

well as formation of trans-isomers (geometrical) during soybean oil hydrogenation

480

Table 3. Fatty acid composition of soybean oil after hydrogenation using gaseous high

481

pressure hydrogen [4]

482

22

140

60 W 80 W

130

100 W

120 W Iodine value

120 110 100 90 80 0

483

15

30 Time (min)

45

60

484

Figure 1. Effect of ultrasound power on reduction in iodine value during ultrasound assisted

485

CTH of soybean oil. Frequency of 22 kHz, 90% duty cycle, temperature of 30°C, ammonium

486

formate concentration of 0.32 mol (20 g in 50 ml water), catalyst loading of 2% w/w of

487

soybean oil (0.22 g), soybean oil as 0.012 mol (10.8-11 ml).

488

23 140

Potassium formate Sodium Formate

130

Ammonium Formate 120 Iodine value

Formic Acid

110

100

90

80 0

15

30

45

60

Time (min)

489 490

Figure 2. Effect of type of donors on reduction in iodine value during CTH of soybean oil.

491

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

492

ammonium formate concentration of 0.32 mol/50 ml H2O, catalyst loading of 2% w/w of

493

soybean oil (0.22g), soybean oil as 0.012 mol (10.8-11 ml).

494 495 496 497 498 499 500 501 502 503 504 505

24

140

0.16 moles 0.24 moles

130

0.32 moles 0.40 moles

Iodine Value

120

110

100

90

80 0

15

30

45

60

506 507

Figure 3. Effect of donor concentration on reduction in iodine value during CTH of soybean

508

oil. Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

509

ammonium formate as donor, catalyst loading of 2% w/w of soybean oil (0.22g), soybean oil

510

as 0.012 mol (10.8-11 ml).

511

25 512 140

30°C 45°C

130

60°C 75°C

Iodine Value

120

110

100

90

80 0

513

15

30 Time (min.)

45

60

514

Figure 4. Effect of temperature on reduction in iodine value during CTH of soybean oil.

515

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, ammonium formate

516

concentration of 0.32 mol/ 50 ml water, catalyst loading of 2% w/w of soybean oil (0.22g),

517

soybean oil as 0.012 mol (10.8-11 ml).

518 519

26 140

1 % (w/w) 130

1.5 % (w/w)

2 % (w/w) Iodine Value

120

2.5 % (w/w)

110 100 90 80 0

15

30

45

60

520 521

Figure 5. Effect of catalyst loading on reduction in iodine value during CTH of soybean oil.

522

Ultrasound power 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

523

ammonium formate concentration of 0.32 mol/ 50 ml water, Pd/C catalyst, oil (0.22g),

524

soybean oil as 0.012 mol (10.8-11 ml).

525

27 526 527 140 130

Iodine Value

120

20 ml 110

50 ml 80 ml

100 90 80 0

15

30

45

60

528 529 530

Figure 6. Effect of amount of water on reduction in iodine value during CTH of soybean oil.

531

Ultrasound power of 100W, frequency of 22 kHz, 90% duty cycle, temperature of 30°C,

532

ammonium formate concentration of 0.32 mol, Pd/C catalyst, oil (0.22g), soybean oil as

533

0.012 mol (10.8-11 ml).

534 535 536 537 538 539

28

540 541 542 543 544

545

(a)

(b)

Figure 7. SEM images of Pd/C (5 wt% loading) with matrix activated carbon support. (a) fresh catalyst (b) Spent catalyst after first cycle

29

546

Table 1. Fatty acid composition and properties of refined soybean oil

547 %

C12:0

C14:0

C16:0

C18:0

C18:1

C18:2

C18:3

C20:0

C22:0

C24:0

0.2

0.4

11.6

4.3

22.4

54.2

6

0.4

0.3

0.2

Fatty acid composition

548

Iodine value (Wijj’s) = 134

549

Table 2. Effect of operating parameters and hydrogenation processes on the fatty acid

550

composition as well as formation of trans-isomers (geometrical) during soybean oil

551

hydrogenation Sample

US

Catalyst

Donar

Temp. after

Power

Loading

552

(W)

Std.

NA

1

C18:1

C18:3

(%)

(%)

Cis

Trans

(%)

Conc.

(° C) 1h

C18:2 (%)

C18:0

IV

%(w/w)

(moles)

NA

NA

NA

4.3

22.4

55.5

0

6

135

100

30°

2

0.32

6

32.3

46.5

0.5

1.6

95.50

2

100

30°

2

0.4

6.8

37.3

42.3

0.7

1.2

93.15

3

100

30°

2.5

0.32

7.5

37.5

41.9

0.6

0.8

92.00

4

100

60°

2

0.32

12.0

34.4

40

1.1

0.6

88.82

30

553

Table 3. Fatty acid composition of soybean oil after hydrogenation using gaseous high

554

pressure hydrogen [4] Sr. No. Conditions

C18:0

C18:1

C18:2 (%)

C18:3

(min)

(%)

(%)

Cis

Trans

(%)

IV

1

High-pressure (Ni; 150 ◦C)

20

7.5

37.6

37.3

2

1.9

110.7

2

High-pressure (5% Pd/C; 150

5

7.2

37.4

37.6

3.6

0.52

110.3

◦C)

555 556 557

Time

31 558

HIGHLIGHTS:

559


First report of intensification of heterogeneously catalyzed transfer hydrogenation using

560

ultrasound

561




562


Significant reduction in the temperature and reaction as the key benefits

563


Selecting best set of operating conditions also helps in minimizing the formation of hazardous

564 565 566 567 568

Understanding the engineering aspects in terms of effect of operating parameters

trans-isomer