Properties of native and blended oil palm starch with nano-silicon dioxide as binder for particleboard

Journal Pre-proof Properties of native and blended oil palm starch with nano-silicon dioxide as binder for particleboard Norani Abd Karim, Junidah Lamaming, Madihan Yusof, Rokiah Hashim, Othman Sulaiman, Salim Hiziroglu, Wan Noor Aidawati Wan Nadhari, Kushairi Mohd Salleh, Owolabi Folahan Taiwo PII:

S2352-7102(19)30058-0

DOI:

https://doi.org/10.1016/j.jobe.2019.101151

Reference:

JOBE 101151

To appear in:

Journal of Building Engineering

Received Date: 22 January 2019 Revised Date:

21 November 2019

Accepted Date: 23 December 2019

Please cite this article as: N.A. Karim, J. Lamaming, M. Yusof, R. Hashim, O. Sulaiman, S. Hiziroglu, W.N. Aidawati Wan Nadhari, K.M. Salleh, O.F. Taiwo, Properties of native and blended oil palm starch with nano-silicon dioxide as binder for particleboard, Journal of Building Engineering (2020), doi: https:// doi.org/10.1016/j.jobe.2019.101151. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. 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. © 2019 Published by Elsevier Ltd.

Authors Contributions: Norani Abd Karim: Conceptualization, Methodology, Formal analysis, Writing- Original draft preparation. Junidah Lamaming: Visualization, Writing—Review & editing. Madihan Yusof: Investigation,Methodology. Rokiah Hashim: Conceptualization, Supervision, Funding acquisition, Writing—Review & editing. Othman Sulaiman: Funding acquisition. Salim Hiziroglu: Writing—Review & editing. Wan Noor Aidawati Wan Nadhari: Formal analysis. Kushairi Mohd Salleh: Formal analysis. Owolabi Folahan Taiwo: Writing— Review & editing.

1 2

Properties of native and blended oil palm starch with nano-silicon dioxide as binder for particleboard

3

Norani Abd Karima,b, Junidah Lamaminga, Madihan Yusofa, Rokiah Hashima*, Othman

4

Sulaimana, Salim Hizirogluc, Wan Noor Aidawati Wan Nadharid, Kushairi Mohd Salleha,

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Owolabi Folahan Taiwoa,e

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Contact information: aDivision of Bioresource, Paper and Coatings Technology, School of

7

Industrial Technology, Universiti Sains Malaysia, 11800 Penang, Malaysia; bPolytechnic

8

Kota Kinabalu, No 4,Jalan Politeknik, KKIP Barat, Kota Kinabalu Industrial Park, 88460,

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Kota Kinabalu, Sabah, Malaysia; cDepartment of Natural Resource Ecology and

10

Management, Oklahoma State University, Stillwater, OK 74078-6013, USA; dDepartment of

11

Technical Foundation, Universiti Kuala Lumpur, Malaysian Institute of Chemical &

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Bioengineering Technology, Lot 1988, Kawasan Perindustrian Bandar Vendor, Taboh

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Naning, 78000 Alor Gajah, Melaka, Malaysia; e Federal Institute of Industrial Research

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Oshodi Lagos, Nigeria.

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*Corresponding author. Tel.: +60 4 653 5217; fax: +60 4 653 6375.

16 17 18 19 20

E-mail addresses: [email protected], [email protected] (R. Hashim*); [email protected] (N. Abd. Karim); [email protected] (J. Lamaming; [email protected] (M. Yusof); [email protected] (O. Sulaiman); [email protected] (S.Hiziroglu); [email protected] (W.N.A.Wan Nadhari); [email protected] (K.M.Salleh); [email protected] (O.F. Taiwo)

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ABSTRACT

22

The replacement of the synthetic binder like urea formaldehyde and other suitable binder

23

with natural adhesive like starch is very challenging to meet acceptable properties. This study

24

evaluates the physicochemical and properties of both native starch and blended oil palm

25

starch from the mixture of polyvinyl alcohol, boric acid and nano silicon dioxide. The result

26

shows higher crystalline index and enthalpy peak of differentiate scanning calorimetry from

27

blended oil palm starch bonded particleboard in comparison with those bonded with native

28

starch. Morphological changes of native starch after blending process were observed from the

29

scanning electron micrograph. Improvement were seen in both the dimensional stability and 1

30

internal bond strength. The study shows that blended oil palm starch would be a potential

31

candidate as a green binder in particleboard production.

32

Keywords: starch; blended oil palm starch; bio-adhesive; polyvinyl alcohol; silicon dioxide

33

1.

34

Introduction The growth of oil palm plantations as an industrial crop in Malaysia has increased

35

exponentially [1] generating 13.97 million metric tons of oil palm trunk (OPT) every year [2-

36

3]. The oil palm trees of the age of 25 years or above are no longer considered as economical

37

and less suitable for cultivation [4]. Therefore, the uneconomical oil palm trees are cut down

38

and being replaced by the new trees plantation. The felled oil palm trees normally left on

39

harvesting site and not being utilized for any valuable products [1,5]. Several researches have

40

been reported on the proposed utilization of abandoned OPT by converting it into other

41

valuable products [6-7].

42

The oil palm biomass contains a substantial amount of starch in the whole plant but

43

more specifically in the trunk part [8-9]. Native starch is the mixture of glucose units of

44

amylose and amylopectin. Amylose is a small polymer and is an α-1,4-linked glucose units

45

with sometimes the long chains attached with α-1,6 branches (<1 % branching) whilst the

46

amylopectin is composed of an α-1,4-linked, α-1,6-branched (4-6 % branching) polymer [10].

47

According to Jarowenko (1977) [11], it is being used in various products including binders,

48

sizing materials, and pastes [12].

49

The oil palm starch (OPS) as a binder has a promising future to be seeen as a green

50

binder for particleboard manufacturing. The use of oil palm starch (OPS) as a binder for

51

wood composite is still new and has been explored by various researchers [1,13,14]. It has

52

been reported that the use of native OPS and modified OPS [1,12] in particleboard

53

manufacturing as binder exhibited a good mechanical property and met the requirement of

54

selected standard. In other work [13], the use of OPS as binder was compared with wheat 2

55

starch and the findings showed that particleboard with OPS have better properties than those

56

with wheat starch. However, it seems that starch based adhesives have some disadvantages

57

such as poor water resistant, mobility and bonding strength [15]. Characterization and

58

analysis of physicochemical properties of starch are important parameters to be studied so

59

that it could be used for various applications [16]. Previous research showed that modified

60

corn starch with polyvinyl alcohol (PVOH) and nano silicon dioxide (SiO2) improved

61

properties of packaging material [17]. However, there is very limited information on

62

physicochemical properties of OPS crosslinked with polyvinyl alcohol (PVA) and nano

63

silicon dioxide (SiO2) as a binder for particleboard manufacturing.

64

Particleboard is usually manufactured from wood particles or biomass materials such

65

as sawdust, wood shavings by bonding with synthetic adhesive under heat and pressure [18].

66

The commercial synthetic adhesive such as melamine formaldehyde, phenol formaldehyde,

67

and urea formaldehyde are commonly used adhesives that having excellent properties

68

including providing strong bonding, cost-effectiveness and fast curing time. It has been

69

reported [19] that such adhesives have one major disadvantage namely formaldehyde

70

emission causing environmental pollution and health hazard [20]. Natural adhesive such as

71

starch from different plants as a binder could provide alternative to commercial synthetic

72

adhesive to produce particleboard [13, 19, 21].

73

Several studies in modification of native starch for the particleboard production with

74

enhanced properties had been carried out [1,19,22]. The combination of starch and polyvinyl

75

alcohol (PVA) showed the best compatibility material [19,23]. The PVA enhance

76

particleboard properties such as excellent chemical resistant and good biocompatibility [23].

77

It also shows a biodegradable behavior when it is mixed with starch [24]. However, starch

78

and PVA have hydrophilic characteristics that can absorb moisture from the environment. A

79

water repellent additive probably is needed to overcome this problem [21]. The nano silicon

3

80

dioxide having a high value of hardness is widely used for many applications [25] and could

81

be suggested as a water repellent in natural adhesive such as starch [17]. Addition of this

82

water repellent to oil palm starch is expected to improve water resistant and mechanical

83

properties of particleboard. The blended oil palm starch can affect the physicochemical

84

properties and properties of starch based adhesives. Therefore, the objectives of this study are

85

to evaluate the performance of oil palm starch mixture based adhesive with the addition of

86

nano silicon dioxide (SiO2) and to evaluate their performance as a binder for particleboard.

87

The starch based adhesive properties, physicochemical and mechanical properties of

88

particleboard samples were evaluated according to Japanese Industrial standard (JIS) [26]

89

with acceptable properties.

90

2.

Materials and methods

91

2.1

Raw materials

92

Oil palm trunks (OPT) samples were obtained from local plantations in Kuala

93

Selangor, Malaysia, and cut into 5 cm discs. The oil palm discs were then cut to a smaller

94

size of approximately 0.5 cm for thickness and 6 cm width to facilitate the extraction process.

95

Raw material of 70 % Acacia mangium and 30 % mixed hardwoods (rubberwood and a few

96

types of tropical wood) was supplied by a local particleboard company in Negeri Sembilan,

97

Malaysia.

98

2.2

99

Oil palm starch extraction process The extraction process of the oil palm starch was conducted according to the previous

100

studies [1,8] with a slight modification in steeping time and mesh type used during the

101

extracting process. The samples were soaked in sodium metabisulphite with 1L of 0.005 g

102

(w/v) in aqueous solution. For each batch, approximately 6 discs were used and a total of 30

103

discs were used for this extraction process. Steeping was carried out for 48 h based on the

104

yield obtained from previous work [27]. After steeping, the starch was then extracted and

4

105

filtered through a mesh of sieve size 200 µm to avoid oil palm fibers being mixed with the

106

original starch. After the screening process, the samples were filtered and then centrifuged for

107

10 min at 3000 rpm using a centrifuge model Beckman Coulter Allegra X-15R. The sediment

108

starch at the bottom of the centrifuged bottle was removed and oven-dried at 60 °C ± 2 °C for

109

3 – 5 days. Then, the dried starch was grounded and stored in a sealed jar prior for further

110

use.

111

2.3

112

Starch blending and adhesive preparation process The PVA/starch blending was carried out based on process described in two previous

113

reports [17,28]. The extracted oil palm starch was placed in an oven at a temperature of 50 °C

114

to dry overnight before the blending process. The PVA with molar mass = 99.00 g/mol

115

(Sigma-Aldrich), boric acid (2 %), glycerol (20 %) and tween 80 (1 %) were used in this

116

study. All the materials were weighed based on adhesive modification formulation and

117

parameters set up for particleboard manufacturing as displayed in Table 1. Then 70 % of

118

starch with 30 % ratio of PVOH was prepared in this study and compared to 100 % native

119

starch and commercially produced UF. Distilled water solution of PVA was heated at a

120

temperature of 90 °C until it was completely dissolved. Then, the oil palm starch, glycerol,

121

boric acid, Tween 80 and 3 % of SiO2 were added to the mixture. All the solutions were

122

poured into a container and oven-dried at 60 °C before being used as a binder for

123

particleboard manufacturing.

124 125 126

Table 1. Starch blending ratio for particleboard manufacturing.

Sample type

Ratio Starch: Polyvinyl alcohol: Nano silicon dioxide (%)

Native starch

100: 0: 0

Blended starch (starch/PVA/SiO2)

70: 30: 3

Urea formaldehyde, UF (Control)

100: 0: 0 5

127 128

2.4

Evaluation of physicochemical properties of oil palm starch

129

Approximately 1 to 2 g of oil palm starch samples were placed in an oven at a

130

temperature of 105 °C for 24 h to determine their moisture content in duplicate. The samples

131

were then cooled down in a desiccator for about 10 min before determining their weight loss.

132

The pH measurement of the samples were done based on the procedure described by previous

133

researcher [16]. About 1.5 g of the starch was weighed in duplicate and placed in a 50 mL

134

extraction bottle before adding 25 mL of distilled water. Then, all the samples were mixed

135

with a portable shaker for 2 min and left for 10 min before measuring the pH value.

136

Particle size analysis was carried out by using the Mastersizer 2000 equipped with a

137

Scirocco dry powder feeder. In the next step, the particles size was measured and expressed

138

in micrometer (µm) units.

139

2.4.1 Determination of oil palm starch content

140

Determination of oil palm starch content was carried out by using method stated in

141

previous work by other researcher [29]. Approximately 0.4 g of the oil palm starch powder

142

was weighed and transferred to 50 mL centrifuge test tube. Then, 4 .7 mL of 7.2 M perchloric

143

acid was added, and the solution was allowed to react for 10 min with occasional stirring in

144

the water bath at 30 °C. After 10 min, the content was transferred to another 50 mL

145

centrifuge test tube and brought to volume. The sample was then centrifuged at 3000 rpm for

146

5 min. Then, 10 mL of solution was transferred into another 50 mL centrifuge test tube

147

together with phenolphthalein and turn to alkaline with 2 N sodium hydroxide. About 2 N

148

acetic acid was added to the solution until the color changed and then a further 2.5 mL was

149

added followed by 0.5 mL 10 % w/v potassium iodide and 5 mL 0.01 N potassium iodate.

150

The color was allowed to develop for 15 min before evaluation process. A UV-VIS

6

151

spectrophotometer was set at a wavelength of 650 nm used as the indicator in this

152

experiment. Three readings were collected for each type of sample.

153

2.4.2 Determination of protein content

154

Protein determination was adopted from previous method [30]. The process was

155

running by fully equipped automatic machine which consists of 3 steps. Firstly, digestion

156

with 2 mL sulfuric acid (98 % v/v) and 5 mg of Kjeldahl digestion tablet (catalyst) was used

157

in this process until transparent or nearly colorless solution was obtained in the flasks test

158

sample. Next, the distillation process used a 50 %, (w/v) of sodium hydroxide (NaOH) to

159

neutralize the sulfuric acid. Finally, titration process using 2 % of boric acid (H3BO3) reacted

160

with ammonia solution was conducted. About 1 - 2 g of duplicates of starch samples were

161

employed in this protein test. Lipid content was evaluated by using Soxtec TM 2050 (Auto Fat

162

Extraction System) equipment. About 90 mL of petroleum ether of 40 % – 60 % (v/v) was

163

used to extract the samples. About 1 – 2 g of samples were extracted within 2 h, oven dried at

164

100 °C for half an hour, placed in a desiccator to cool for 1 h until no further change in

165

weight, before the final weight of the sample was taken.

166

2.4.3 Determination of amylose content

167

Determination of amylose content followed a method by other study [31] using an

168

ethanol with 96 % (v/v) within 20 h for starch defatted by soxhlet extraction. A blank sample

169

was prepared at a concentration of 0 % to 40 % for control specimens. The test was

170

conducted in triplicate for each type of sample. Total amylose of starch sample was

171

calculated based on calibration graph from the blank samples by using a UV-VIS

172

spectrophotometer was set at a wavelength of 600 nm. Amylopectin value of the sample was

173

calculated based on equation stated in previous work [32].

174

Ash content method was adopted from previous work [16]. The duplicate sets of a

175

ceramic container containing a starch approximately 1 - 2 g were prepared and placed in a

7

176

muffle furnace at 550 °C for 3 h, then cooled in a desiccator for 1 h before weighing. The

177

percentage ash quantity of the oil palm starch sample was determined by weight differential

178

bases.

179

2.5

Determination of adhesive properties

180

The solid content of oil palm starch was measured by using a powder form sample in

181

a duplicate set [1]. Approximately 1 - 2 g of starch was weighed to obtain the initial weight,

182

before it was oven dried at 105 °C ± 2 °C temperature for 3 h. After 3 h, the samples were

183

placed in desiccators for approximately 10 min to reach a constant weight.

184

With the aid of viscometer model Brookfield DV-II + Pro, equipped with a spindle

185

size No. 0.7 the viscosity of adhesive of the extracted oil palm starch was measured at 100

186

rpm. Approximately 10 % (w/v) of the starch sample dissolved in 25 mL of distilled water

187

was placed in a 50 mL test tube. The sample was then heated in a water bath at a temperature

188

of 90 °C ± 2 °C for 10 min to allow each sample to dissolve completely. Later, the samples

189

were allowed to cool at ambient temperature for 10 min. Rheological properties of the

190

samples were analyzed with a three readings for each type of sample [27].

191

Evaluation of the Pot life of the prepared adhesive was embarked by preparing starch

192

water slurry at 80 °C temperature until it changed into a paste and left inside the container

193

until it became too thick to be spread. The time was monitored and recorded until the

194

adhesive become stable [33].

195

2.5.1 Swelling power and solubility determination

196

The swelling power and the solubility of the samples were carried out according to the

197

previous researcher [34]. Approximately 1 g of starch were weighed and poured into 50 mL

198

centrifuge tube with coated screw cap. About 10 mL of distilled water was added to the

199

sample dissolved. Each type of samples was prepared in triplicate for the experiment. Then,

200

all the tubes were shaken for 2 min with portable shaker before being heated at 50 °C, 60 °C,

8

201

70 °C, 80 °C and 90 °C for 40 min in a water bath for each different temperature respectively.

202

After heating, each sample was cooled to room temperature for 30 min and centrifuged at

203

3000 rpm for 20 min.

204

2.6

205

X-ray diffractometer (XRD) The percentage of a crystalline structure of the native starch and OPS was measured

206

using a Kristal- loflexD-5000 X-ray diffraction system (Siemens, Germany). This method

207

was adopted from the previous study [14]. The starch samples were placed in the sample

208

holder and packed before eliminating possible dust or any contamination by air blown. The

209

X-rays diffraction pattern were recorded using Cu Kα radiation for the scan measurement

210

were generated with an opening voltage of 40 kV and a current of 30 mA. The scanning

211

process was carried out at a 2θ diffraction angle ranging from 10–40º with 0.02 º and 2 º/min

212

scanning speed. The crystallinity index was calculated using Eq. (1) from the previous

213

method [35] (Segal et al., 1959):

214

C

215

where I200 is the peak intensity of the crystalline fraction and Iam is the peak intensity of the

216

amorphous fraction.

217

2.7 Thermal analysis of the sample

218

%





Eq. (1)

%

The thermal stability of both the blended and native sample were determined using

219

differential scanning calorimetry to compare the thermal stability of the blended starch

220

compared to that of the native starch. The melting temperature (Tm) of each type of starch

221

samples was determined using a Perkin Elmer Thermal analysis (Model DSC 8000). For this

222

study, about 5 mg each of the starch powder was weighed and put into an aluminum pan

223

which was subsequently placed in the instrument furnace along with an empty pan used as a

224

reference. At the preset temperature range between -15 °C and 280 °C under the nitrogen

225

atmosphere the samples were heated at the rate of 10 °C/min. 9

226

2.8

227

Morphological analysis The changes in the morphological structures of the native oil palm starch, and blended

228

starch samples were monitored using scanning electron microscopy (SEM). In this analysis,

229

the starch powder was dispersed and placed on a stub. The thin layer of gold was then coated

230

on the sample using a Polaron SC515 SEM coating system (Fisons Instrument).

231

Microstructure of the samples was evaluated by using a scanning electron microscope (Model

232

Supra 50 VP) with an accelerating voltage of 15 kV.

233

2.9

234

Manufacture of particleboard and evaluation of their properties Particleboard samples were produced based on a target density of 0.80 g/cm3 with the

235

dimensions of 20.1 cm x 20.1 cm x 0.5 cm. The particles used in this work recorded an 8 %

236

of moisture content (MC). Approximately 15 % of starch adhesive as prepared in the earlier

237

formulation was weighed based on dry weight (w/w). The starch adhesive was firstly mixed

238

with 150 mL of hot distilled water having temperature of 80 °C until it dissolved completely.

239

Then, it was poured into particles and mixed carefully until it covered all the particles

240

uniformly for about 5 to 7 min. The mixture was then placed into the mold to form a mat with

241

specified dimensional size, followed by cold pressing for about 2 min. A pressure of 5 MPa

242

was then applied on the mat, pressed with hot pressing at a temperature of 165 °C for 15 min.

243

The panels were cooled and placed in an air conditioning room at a temperature of 25 °C ± 2

244

°C with a relative humidity of 65 °C ± 2 °C for a week before further tests.

245

The physico-mechanical properties of the panel samples were evaluated in accordance

246

to JIS Standard A 5908 [26]. Moisture content (MC) value from an average of 5 samples was

247

taken based on oven dry weight. Density of the samples was calculated based on the product

248

of the dimensional measurement of the mass of the samples, the length, width, and the

249

thickness of the sample. The changes in value of the samples after the samples were soaked

250

for 2 h and 24 h in distilled water were noted. The differences in the thickness before and

10

251

after the immersion were used to determine the thickness swelling (TS) and water absorption

252

(WA) of the samples. Mechanical properties including the modulus of elasticity (MOE),

253

modulus of rupture (MOR) and internal bond (IB) strength were carried out by using an

254

Instron Tensile Machine Model 5582 with crosshead speed 10 mm/min and 2 mm/min.

255

2.10

Statistical analysis

256

All the test results were performed in five replicates and analyzed using SPSS

257

statistical software version 20.0 for Windows package for the analysis of variance (ANOVA)

258

while the post hoc test was conducted with Duncan`s multiple range test DMRT (p < 0.05) to

259

compare mean values at 5 % significance level. However, the physicochemical and adhesive

260

properties were expressed in standard deviation (SD).

261

3.0

262

3.1 Analysis of native starch and blended starch (starch/PVA/SiO2)

263

3.1.1

264

Results and Discussion

Physical and chemical properties of the starch The physicochemical properties of both native starch and blended oil palm starch

265

(starch/PVA/SiO2) are displayed in Table 2. The moisture content values of both native and

266

blended starch were 10.36 % and 23.98 %, respectively. Blended oil palm starch OPS showed

267

higher value as compared to that of native starch. The high MC of blended starch might be

268

attributed to the hydrophilic characteristics of oil palm starch and PVA which made it is easy

269

to absorb moisture from the environment during the blending process and the method storage

270

used for the starch might also contributed to the high MC [36].

271

Table 2.

272

Physical and chemical analysis for both native and blended oil palm starch. Properties

Native starch

Blended starch (starch/PVA/SiO2)

MC (%)

10.36 (0.76)

23.98 (1.83)

pH

4.66 (0.02)

5.63 (0.08) 11

273 274

Particle size (µm)

21.99 (0.71)

17.15 (0.1)

Starch content (%)

6.00 (0.05)

19.75 (6.79)

Amylose (%)

10.87 (0.01)

9.26 (0.01)

Amylopectin (%)

89.13 (0.01)

90.74 (0.01)

Protein (%)

2.17 (0.01)

0.90 (0.08)

Lipid (%)

1.00 (0.01)

0.00 (0.00)

Ash (%)

3.37 (0.05)

2.93 (0.1)

Note: Data is expressed as means; values in parentheses show standard deviations. The pH values for both starches were acidic, with the pH value of the native starch

275

and blended starch measured at 4.66 and 5.63, respectively. From the result, the blended

276

starch is more favored since acidic property enhances better bonding process between binders

277

and wood fibers [13].

278

The granules sizes for both native and blended oil palm starch were 21.99 µm and

279

17.15 µm, respectively. This was the highest value as compared to that of previous work

280

obtained which are in average between 11.00 µm to 13.00 µm [1,13]. A different source of

281

botanical, sampling used, mesh wire size of 200 µm and combination with other additives

282

such as PVA and SiO2 in blended starch may have influenced the results.

283

Starch content obtained in this study was 6.0 % for native starch and 19.75 % for

284

blended starch. The blending process had increased the starch content in the blended oil palm

285

starch which could be attributed to the possibility of cross-linking that might happened

286

between starch and other compounds in the starch-based adhesive. However, further work is

287

required to confirm on this issue. Lower starch content reflected the amylose and amylopectin

288

ratio and purity of the starch that could affect the particleboard properties.

289

Amylose and amylopectin of both starches were also measured. Amylose content of

290

the sample was 10.87 % for native starch and 9.26 % for blended starch/PVA/SiO2.

291

Amylopectin value of 89.13 % and 90.74 % were found for native and blended starch,

292

respectively. Since amylose is insoluble and amylopectin is soluble in water, adhesive 12

293

produced from the blended starch are more soluble and the capability to absorb water was

294

higher [13] as compared to native starch. Water repellent of the sample was lower when

295

amylopectin value is greater. The amylose content of starch affects starch solution properties

296

such as starch solubility and swelling power, which depend on the leaching of amylose out of

297

the crystalline network of amylopectin into solution [36]. In the starch-based application, the

298

amylose content is one of the crucial factors that need to be take account of since the ratio of

299

amylose to amylopectin elucidates the starch applicability [37].

300

Protein content value of both starches was measured and it shows that native starch is

301

having a higher percentage of 2.17 % compared to blended starch, which has 0.90 % of

302

protein. It is known that higher protein content could affect the starch swelling properties due

303

to the proteinaceous materials surrounded the starch granules that can swell rapidly upon

304

hydration [13]. The protein can also affect the starch gelatinization and pasting properties

305

[36]. Higher protein value found in the native starch is an agreement with those of previous

306

work that explain the inefficient removal of protein from the starch sample could contribute

307

to the high value of protein [8].

308

Highest lipid content was found in native oil palm starch (1.00 %) compared to

309

blended oil palm starch that having a value of 0 %. High amylose content in the starch

310

indicates higher lipid content and vice versa. From the findings, the lipid content of both

311

starches were in agreement with the amylose content aforementioned. The native starch is

312

having higher lipid content in accordance to the higher amylose content as compared to

313

blended starch.

314

The higher value 3.37 % of ash content was found in the native oil palm starch, and

315

blended starch/PVA/SiO2 having a value of 2.93 %. The ash content will reflect the purity of

316

starch. The native oil palm starch has higher ash content due to higher silica content in oil

317

palm trunk [8].

13

318

3.1.2

Adhesive analysis

319

Adhesive properties of oil palm trunk starch such as solid content, viscosity and pot

320

life are displayed in Table 3. Percentage of solid content for both native and blended starch

321

was 31.82 % and 24.42 % respectively. The solid content of native starch recorded slightly

322

higher compared to blended starch. The solid content of native starch in this study was found

323

higher while blended starch was lower as compared to previous studies that used native starch

324

and modified starch from oil palm trunk and [1,37]. Different treatments during extraction

325

process and blending/modification process possibly contribute to the difference in the solid

326

content value. However, a value of 24.42 % from blended starch in this study is an agreement

327

with an earlier study [19], suggesting that the solid content should have 27 % or less for

328

better bonding properties.

329

Table 3.

330

Adhesive properties of native and blended oil palm starch. Adhesive properties Type of samples Native starch Blended starch (starch/PVA/SiO2)

331 332 333

Solid content at 105° ± 2°C (%) 31.82 (2.52)

Viscosity at 80 °C (Centipoises, cP) 105.67 (3.06)

Pot life (days) 2.00 (1.41)

24.42 (4.02)

187.67 (12.90)

2.50 (0.71)

Note: Data is expressed as means; values in parentheses show standard deviations.

Native oil palm starch sample obtained a low viscosity value (105.67 cP) compared to

334

blended starch sample having a value of 187.67 cP. This finding was similar to the previous

335

study reported by other researcher [1]. Higher viscosity value of adhesive is required when it

336

acts as an adhesive. It is worth noting that starch originated from different sources and parts

337

of plant also has an influence on the viscosity value [38].

338 339

The pot life of native and blended starch was slightly different from each other. Blended starch had longer pot life of 2.5 days compared to 2 days of native starch. The pot 14

340

life depends on the viscosity of the starch. The higher the viscosity, the less time it will

341

needed for the adhesive to be spread. However, this finding was contradicted with the

342

previous study where native starch has longer pot life compared to blended starch [1]. Natural

343

adhesive commonly was unstable in the room temperature, thus it will shorten the shelf life of

344

this adhesive [39] compared to blended starch based adhesive. This finding could be due to

345

nano silicon dioxide (SiO2) in the samples protecting starch based from absorbing moisture in

346

the environment. Thus, it enhanced the blended adhesive’s shelf life in contrast to the native

347

starch.

348

Table 4 depicted the swelling power and solubility of both native and blended starch

349

at five different temperature. The blended starch/PVA/SiO2 showed higher swelling power

350

values compared to the native starch. The result showed that gradual increment in swelling

351

was shown in both starch before decreasing at temperature of 80 °C for native starch and 90

352

°C for blended starch. The native oil palm starch had the higher swelling power at a

353

temperature of 70 ºC and 80 ºC for blended oil palm starch. Higher solubility values were

354

ranged from 5.23 to 19.05 % to % of native starch as compared to blended starch ranged from

355

0.50 % to 3.38 %. Higher swelling power and lower solubility found in the starch/PVA/SiO2

356

at a temperature of 80 ºC was enhanced the adhesion properties thus improved the internal

357

bonding and dimensional stability.

358

Table 4.

359

Swelling and solubility for native and blended oil palm starch. Temperature (°C)

50

60

Type of sample

SP (g)

Native starch

2.52 17.17 (1.93) (13.24)

SOL (%)

70

80

90

SP (g)

SOL (%)

SP (g)

SOL (%)

SP (g)

SOL (%)

SP (g)

SOL (%)

2.78 (0.35)

19.05 (6.25)

6.90 (5.05)

7.46 (0.88)

6.53 (6.57)

5.23 (2.10)

5.19 (3.90)

2.89 (0.76)

15

360 361 362 363

2.59 24.01 8.64 0.50 10.49 2.80 19.10 0.88 14.17 3.38 Blended (1.95) (0.58) (1.14) (0.12) (1.44) (2.72) (1.64) (0.53) (1.20) (3.30) starch (starch/PVA/ SiO2) Note: Data is expressed as means: values in parentheses show standard deviations; SPswelling power, SOL- solubility.

3.1.3

XRD analysis Native oil palm starch had the lowest crystalline index value recorded at 14.03°

364

compared to blended starch/PVA/SiO2 which had a value at 23 º as illustrated in Fig. 1. The

366

crystalline index value for native starch and starch/PVA/SiO2 calculated were 20.24 % and

367

29.52 %, respectively. Lowest crystalline index in native starch was similar to previous

368

research [1]. This result might be due to the highest amylose content in native oil palm starch

369

that tends to give a lower crystalline index [13]. The results indicated that the crystallinity of

370

the blended starch tends to increase after blending process. Higher crystallinity of oil palm

371

starch can affects the percentage of swelling and solubility, gelatinization temperature and

372

also the reaction enthalpy of the samples [8]. All the results of this study were considered as

373

Type A pattern as agreement with the previous study where the peaks are between 14 °C to

374

24 °C [8].

Intensity counts

365

10000 9000 8000 7000 6000 5000 4000 3000 2000 1000 0

Blended starch

Native starch

4

6

8

10

12

14

16

18

2 Theta 375 16

20

22

24

26

29

376

Fig. 1. XRD patterns for native oil palm starch and blended starch (starch/PVA/SiO2).

377

3.1.4

DSC thermal analysis

378

The result in Fig. 2 shows the DSC thermograms of native oil palm starch and

379

blended starch/PVOH/SiO2. The DSC thermograms showed that the native starch has a peak

380

melting temperature (Tm) of 78.30 °C and the blended starch showing a higher value of Tm at

381

124.36 °C. The glass transition temperature (Tg) of native starch is 11.98 °C, which is lower

382

compared to blended starch which is 70.81 °C. The total enthalpy of gelanization of native

383

starch recorded at 210.28 J/g, higher than that of blended starch (172.01 J/g). Increased in

384

melting temperature for blended starch occurred in this work ascribed to the cross linking

385

reaction between oil palm starch, PVA and nano silicon dioxide (SiO2). The higher enthalpy

386

value will contribute to higher temperature that needed to break up the linkages when OPS

387

adhesive is used as a particleboard binder. Previous study also confirmed that oil palm trunk

388

has a higher molecular organization, structural conformation, and crystallinity compared to

389

another type of starch such as sago, sweet potato, cassava, and water chestnut [8]. Previous

390

work done by Sulaiman et al. (2013) also reported that thermal properties of blended starch

391

improved in contrast to native starch, due to changes in the chemical structure during the

392

modification process [13].

17

393 394 395

Fig. 2. DSC thermogram of native oil palm starch and blended oil palm starch (starch/PVA/SiO2).

396

3.1.5

397

SEM analysis The micrograph images of both the native and blended oil palm starch are shown in

398

Figs. 3 (a) and (b). The SEM images were taken at 2000X magnification and the shape for all

399

the samples is round to oval shape. This finding has similar trend as found by a previous

400

researcher [8] which reported the ovoid and elliptical shape and some bell shaped granules.

401

The SEM analysis revealed that blended oil palm starch granules changed to agglomerate

402

form and covered by PVA and nano silica dioxide (SiO2) on the surface of starch granules

403

after the blending process. The granules size for native oil palm sample was bigger than

404

blended samples so that they tend to enhance overall strength of the panels.

18

a

b

405

Fig. 3. Scanning electron micrograph morphology of (a) native oil palm starch and (b)

406

blended oil palm starch (starch /PVA/SiO2).

407

3.2

408

Properties of particleboard samples Table 5 displays the results of physical and mechanical properties of particleboard

409

panels made using the native starch, blended starch (starch starch/PVA/SiO2) and UF

410

(control) as a binder. The density of particleboard bonded with native oil palm starch had a

411

value of 0.81 g/cm3. Samples having blended oil palm starch/PVA/SiO2 and control samples

412

made with UF had density values of 0.78 g/cm3 and 0.70 g/cm3, respectively. The uneven

413

distribution of particles and binders in the furnish influenced the results. Duncan`s groupings

414

also supported this finding, where control board (UF) was significantly different at p < 0.05.

415

Board achieved the target density which indicated that good bonding has occurred between

416

starch based adhesive and particles. Other study was reported that board with high density

417

will perform excellent particleboard properties [40].

418

Moisture content (MC) of board bonded with native oil palm starch was obtained 6.80

419

% and board bonded with blended starch/PVA/SiO2 and UF obtained the values of 6.87 %

420

and 7.31 %, respectively. The highest MC value of 7.31 % was found in the control board

421

(UF). Duncan`s groupings also revealed that control sample (UF) showed a significant

422

different at p < 0.05.

19

423

Table 5.

424

Physical and mechanical properties of native and blended oil palm starch. Sample type

Physical properties Measured Density (g/cm3)

425 426

Moisture content MC (%)

Mechanical properties Thickness swelling (%)

Water absorption (%)

2h

24 h

2h

24 h

MOR N/ mm2

MOE N/ mm2

IB N/ mm2

Native starch

0.81 (0.03)b

6.80 (0.17)a

34.67 (4.87)a

45.44 (2.27)b

49.89 (9.15)a

108.64 (10.48)b

16.19 (1.87)b

2702.02 (248.90)b

1.38 (0.96)a

Blended starch (starch/PVA/SiO2)

0.78 (0.03)b

6.87 (0.23)a

34.00 (4.55)a

34.63 (7.78)a

84.47 (8.57)b

88.82 (10.15)a

12.39 (2.89)a

2150.55 (347.89)a

2.16 (1.03)b

Urea formaldehyde (UF)

0.70 (0.03)a

7.31 (0.15)b

33.39 (3.07)a

36.01 (1.89)a

93.75 (13.63)b

91.37 (9.31)a

12.24 (2.87)a

2039.10 (468.77)a

5.20 (0.84)c

Note: Data is expressed as means; values in parentheses show standard deviations. Values with the same letter are not significantly different (p< 0.05).

20

427

The native oil palm starch achieved a higher value of thickness swelling (TS) at 2 h

428

(34.67 %) and 24 h (45.44%). Board bonded with blended starch/PVA/SiO2 with TS value of

429

34.63 % recorded a lower value when immersed in water for 24 h as compared to board

430

bonded with native starch and urea formaldehyde (UF). The addition of nano silicon dioxide

431

(SiO2) with starch in blended oil palm starch improved TS value of the samples. Excellent

432

bonding properties between particles and interaction of nano SiO2 with other compounds in

433

the starch-based adhesive are evidence for improving thickness swelling value of the samples

434

[41].

435

The WA value of 88.82 % and 108.64 % corresponding to lowest and highest values

436

were found for board bonded with blended oil palm starch/PVOH/SiO2 and native oil palm

437

starch, respectively for 24 h soaking time. Based on Duncan`s grouping analysis, only board

438

with native starch was significantly different at p< 0.05. However, both TS and WA in this

439

study did not satisfy the minimum requirement (12 %) for Type 8 in JIS standard A 5908.

440

The highest value of modulus of elasticity (MOE) was found for board bonded with

441

native oil palm starch (2702.02 N/mm2). The higher amount of starch typically reflects the

442

higher ratio of amylose to amylopectin [1]. Board bonded with blended starch/PVA/SiO2,

443

showed higher value (2150.55 N/mm2) as compared to the control board (UF) obtained a

444

value of 2039.10 N/mm2. All the boards fulfilled the minimum standard for Type 8 in JIS

445

standard A 5908 for MOE results (2000 N/mm2).

446

Modulus of rupture (MOR) in this study also had showed the similar trend as MOE

447

values where both particleboards with native oil palm starch showed the highest value that is

448

16.19 N/mm2. A similar trend as MOE performance was also shown in board bonded with

449

blended oil palm starch/PVA/SiO2 achieved 12.39 N/mm2 slightly higher than control board

450

(UF) has a value 12.24 N/mm2. All the boards also fulfilled the minimum standard for Type 8

451

in JIS standard A 5908 for MOR results (8 N/mm2). For internal bond (IB) strength test, as 21

452

expected boards bonded with UF showed the higher value 5.20 N/mm2 as compared to

453

blended oil palm starch/PVA/SiO2 and native starch has a value of 2.16 N/mm2 and 1.38

454

N/mm2, respectively. All the boards had passed the minimum requirement of JIS Standard

455

for type 8 (0.15 N/mm2). The addition of SiO2 in the samples resulted in significant effect in

456

enhancing the internal bond strength of particleboard specimens bonded with blended oil

457

palm starch. Other factors such as particle size, chemical composition in starch granules [13],

458

and purity of starch [1] also influenced overall properties of the samples.

459

4.

460

Conclusions Based on the findings in this study, blended oil palm starch with polyvinyl alcohol

461

and nano silicon dioxide (SiO2), had a significant effect on physicochemical properties. Both

462

native starch and blended oil palm starch properties positively influenced the final

463

performance of the particleboard as a binder. The starch content ratio also affected the

464

mechanical properties of the particleboard. All the panels of the particleboard bonded using

465

native and blended oil palm starch in this study satisfied the Japanese Industrial Standards

466

(JIS) Type 8 for mechanical properties including MOE, MOR, and IB. However

467

improvement in dimensional stability of the samples is necessary. The study further revealed

468

that incorporation of additives such as SiO2 is capable of enhancing the TS and the WA

469

characteristics of the samples. This study indicated that blended oil palm starch with

470

polyvinyl alcohol and nano silicon dioxide (SiO2) would have the potential candidate as a

471

binder for particleboard production in the future.

472

Acknowledgements

473

We would like to acknowledge Universiti Sains Malaysia for the research grant (100/

474

PTEKIND/815066 and 1001/PTEKIND/ 8014083) to carry out this research project and

475

postdoctoral fellowship awarded to Dr. Junidah Lamaming Dr. Owolabi Folahan Taiwo and

22

476

graduate assistant to Madihan Yusof. Graduate study scholarship awarded to Norani Abd

477

Karim by Ministry Of Higher Education, Malaysia is also acknowledged.

478

Conflict of Interest

479

We declare there is no conflict of interest.

480

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481

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27

Highlights •

New source of starch extracted from oil palm trunk.

•

Modification with PVOH and addition of nano silicon dioxide (SiO2).

•

Physicochemical properties altered the properties of starch based adhesives.

•

Starch ratios influenced the board panel’s properties.

•

SiO2 had significant influenced the dimensional stability.