Characterization of Carboxylated Cellulose Nanocrytals Isolated

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Characterization of Carboxylated Cellulose Nanocrytals Isolated through Catalyst Assisted-H2O2 Oxidation in a One-Step Procedure Roya Koshani, Theo G.M. van de Ven, and Ashkan Madadlou J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b00080 • Publication Date (Web): 05 Jul 2018 Downloaded from http://pubs.acs.org on July 6, 2018

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Journal of Agricultural and Food Chemistry

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Characterization of Carboxylated Cellulose Nanocrytals Isolated

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through Catalyst Assisted-H2O2 Oxidation in a One-Step Procedure

3 †

Roya Koshani, Theo G.M. van de Ven,

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5 6

7 8



‡*

Ashkan Madadlou,

†*

Department of Food Science and Engineering, University College of Agriculture and Natural

Resources, University of Tehran, Karaj, Iran ‡

Department of Chemistry, Quebec Centre for Advanced Materials, Pulp and Paper Research

Centre, McGill University, Montreal, Quebec, Canada

9

10

11

12

13

14

15

16

17 18

*

Corresponding authors: Ashkan madadlou, Email: [email protected] and [email protected]; and Theo G.M. van de Ven, Email: [email protected]

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ABSTRACT

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A green and facile method was designed to isolate a type of cellulose nanocrystals

21

(CNCs) with carboxylated surfaces from native cellulose materials. Since isolation and

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modification processes of cellulosic particles are generally performed separately using

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harmful chemicals and multiple steps, the one-pot approach employed in this work is

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interesting from both an economical and ecological point of view. The reaction is carried

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out by adding hydrogen peroxide as an oxidant and copper (II) sulfate as a catalyst in

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acidic medium under mild thermal conditions. The charge content of the carboxylated

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CNC is about 1.0 mmol g-1 measured by conductometric titration. FTIR spectroscopy

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also proved the presence of carboxyl groups on the CNC particles. Atomic force

29

microscopy along with optical polarized microscopy readily showed a rod shape

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morphology for the cellulosic particles. An average length of 263 nm and width of 23 nm

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were estimated by transmission electron microscopy. Dynamic laser scattering on

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carboxylated CNC suspensions by adding salt confirmed that nanoparticles are

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electrostatically stable. Carboxylated CNCs were furthermore characterized by solid

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carbon-13 NMR and X-ray spectroscopy.

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KEYWORDS: cellulose nanocrystal, hydrogen peroxide, catalyst, oxidation reactions

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INTRODUCTION

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Nanocelluloses derived from the most ubiquitous and abundant biological polymer in

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nature have been receiving lots of academic and industrial attention during the 21st

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century. Their exceptional structural properties such as nanoscale dimension, large

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specific area and ease of surface modification (due to the large number of reactive

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hydroxyl groups) together with low cost and non-toxicity have predestined them for

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applications in various fields.1,2 Examples include fabrication of high-performance

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reinforced biocomposites,3,4 medical materials,5,6 carriers for delivery systems7 and green

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catalysts.8

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Nanocellulosic particles are categorized in three major forms, 1) cellulose nanocrystals

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(CNCs) which are also referred to a nanocrystalline cellulose, cellulose (nano)wiskers, or

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rod-like cellulose microcrystals; 2) cellulose nanofibrils or nano-fibrillated cellulose, and

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microfibrilated cellulose; and 3) hairy cellulose nanocrystalloids (HNCs) bearing a

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crystalline body with polymer chains protruding from both ends.9 Several studies have

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reported a structural dependency of these nanocellolusic materials on the source of

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cellulose and the processing conditions.10,11 CNCs are conventionally isolated by acidic

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hydrolysis of the amorphous regions12 whereas HNCs are generated by periodate

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oxidation reaction through solubilization and cleavage of a sufficient number of chains in

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the amorphous regions.13

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To date, many oxidation-based methods have been used for the extraction and/or surface

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modification of cellulosic particles. The hydroxyl groups on the C6 position of the

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glucose units are commonly converted to the carboxyl form by using a TEMPO (2,2,6,6-

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Tetramethylpiperidine-1-oxyl) mediated oxidation.14 Recently, spherical and rod-like 3 ACS Paragon Plus Environment

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carboxylated CNCs were prepared by ammonium persulfate (APS), an oxidizing agent

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with low long-term toxicity, in a one-step procedure.15,16 It was reported that free

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radicals, formed through the thermal cleavage of the peroxide bond of APS and hydrogen

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peroxide (H2O2) produced under acidic condition, are capable of penetrating the

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amorphous regions of cellulose to break them down to generate carboxylated CNCs.

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In our laboratory, several studies have been performed on the production and

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characterization of cellulose-based particles via periodate and chlorite oxidations.13,17-19 A

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reaction of periodate with cellulose fibers, followed by heating at 80 °C, yields rod-like

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nanocrystals with amorphous regions attached to both ends, which are examples of

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HNCs. The periodate oxidation reaction causes the conversion of C2-C3 hydroxyls to

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aldehyde groups, and at the same time it cleaves cellulose bonds.9 Introducing ionic

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charges facilitate the break-up of the cellulose fibers, resulting in the formation of

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electrosterically stabilized nanofibrils cellulose or CNCs. The unique physicochemical

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properties particularly high colloidal stability and being a useful platform for site-specific

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conjugations suggest that electrosterically stabilized CNCs an example of HNCs have a

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wider range of applications than conventional CNCs.

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Because of the trend to develop facile, safe and eco-efficient processes to diminish

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harmful by-products, this project has focused on a one-pot fabrication and

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characterization of a type of functionalized cellulose-based nanoparticles through Cu-

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catalyzed oxidation of softwood pulp by H2O2. This environmentally friendly oxidizing

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agent is extensively used in the bleaching of pulp fibers20 and in the modification of food

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polymers particularly starch.21,22 H2O2 is safe to use and is approved by the Joint

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FAO/WHO Expert Committee on Food Additives (JECFA) as a multipurpose food

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additive. It creates no harmful by-product and decomposes inevitably to oxygen and

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water.23 In general, H2O2 converts the hydroxyl groups on the polymer chains into

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carbonyl and carboxyl functional groups which is almost always accompanied by

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degradation of macromolecules.24 The decomposition of H2O2, in the presence of

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transition metal catalysts such as copper, iron or tungstate, can lead to the generation of

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intermediate radical species such as HO•·(hydroxyl) and HOO• (hydroperoxyl).25 The

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emerged free radicals can eventually oxidize the alcohol groups and cause the scission of

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glycoside bonds in the polysaccharide chains.24,26 The nanocellulose particles produced

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with the present method can be functionalized with antibacterial agents and used for

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stabilizing food emulsions or incorporated in films for food packaging applications. The

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stabilization of food emulsions by the novel cellulose nanocrystals is being investigated

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and will be the topic of a future publication.

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MATERIALS AND METHODS

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Materials

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For producing cellulose particles, a softwood pulp sheet (Domtar Inc. Canada) chopped

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into small pieces was used as raw cellulose material. Hydrogen peroxide (30 wt %),

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hydrochloric acid, sodium hydroxide and poly-L-Lysine standard solutions were

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purchased from Sigma-Aldrich. Other chemicals supplied were copper (II) sulfate

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pentahydrate (Fisher Scientific), uranyl acetate (SPI chemicals Inc.) and sodium chloride

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(ACP Chemicals Inc.). All solutions were prepared with deionized water.

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Oxidative Preparation of Carboxylated Cellulose Nanocrystals

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Dry softwood pulp pieces (2 g) were soaked in water and vigorously dispersed by a

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magnetic stirrer for 1 day, filtered to remove the fines and extra water from the pulp. 5 ACS Paragon Plus Environment

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Then, 40 mL of 30% H2O2, 0.4 mL of 0.1 M copper (II) sulfate pentahydrate

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(CuSO4.5H2O) solution and 80 mL distilled water were added to the swollen pulp. The

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pH of the reaction mixture was maintained in the range of 1-2 by 1 M HCl addition. The

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reaction vessel was covered with aluminum foil and stirred (160 rpm) for 72 hr at a

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temperature of 60 ºC. Temperature was set by a thermometer inside the reaction beaker,

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and controlled by a magnetic stirrer with hot plate. To stabilize the temperature of the

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sample, an oil bath was placed between the beaker and the hot plate. After completing the

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process, the final volume of the suspension was adjusted to 200 mL with cold deionized

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water to stop the reaction and the suspension was washed 3-4 times by centrifugation

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until the pH reached 3-4. The supernatants were entirely water-soluble and consisted of

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dissolved oligosaccharides, resulting from cellulose degradation through catalyst

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mediated-H2O2 oxidation. Moreover, the supernatant contains most of the copper and

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sulfate ions. These ions are undesirable in food applications, for which their

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concentration must be kept below threshold values. This can be achieved by additional

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centrifugation or washing or by ion-exchange resins.

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Insoluble cellulose particles were suspended in 200 mL deionized water, followed by

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collecting a milk-like supernatant by decantation. Then, the remaining white precipitate

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was added to 50 mL distilled water and sonicated for 15 min with an ultrasonic processor

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(Hielscher UP200H, Germany) at a frequency of 50-60 Hz under continuous magnetic

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stirring. The concentration was determined by drying a certain volume of the sample for

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at least 7 hr at 50 °C. Scheme 1 illustrates the preparation steps of cellulosic particles.

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[Scheme 1]

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Charge Analysis of Carboxylated Cellulose Nanocrystals

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Conductometric titration was carried out using an 836 Titrando titrator (Metrohm,

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Switzerland) to measure the charge content, as an indication of the presence of carboxyl

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functional groups on the surface of the nanoparticles. A certain volume of suspension

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containing 20 mg carboxylated CNC particles was mixed with 2 mL of 20 mM NaCl

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solution and 140 mL milli-Q water under vigorous stirring. Then the pH of the well-

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dispersed suspension was adjusted to around 3.5 by dropwise addition of 0.05 M HCl.

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Subsequently, a 5 mM NaOH solution was gradually added at a rate of 0.1 mL min-1 to

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the dispersion up to a pH around 11. The carboxyl content in mmol per gram

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carboxylated CNC was calculated from that part of the conductivity curve representing

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the volume of the weak acid, as indicated by the two vertical lines in Figure 1.

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A Malvern Zetasizer (ZEN 3600, Made in UK) was also used to investigate the

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magnitude of the charge of the particles. The sample was diluted to 0.1 % of carboxylated

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CNC particles in Milli-Q water.

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Measurement of Particle Size Distribution by Dynamic Light Scattering (DLS)

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The effective diameter and polydispersity of carboxylated CNC particles was determined

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by a Brookhaven light scattering instrument BI9000 AT digital correlator. All

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experiments were performed by monitoring the scattered light intensity at 90° scattering

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angle at 25 °C. Firstly, suspensions (0.1 wt %) were filtered through a 0.45 µm syringe

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filter (Acrodisc, PALL) and then 100 µL of sample was transferred to a low-volume

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microcuvette containing 900 µL deionized water. The different concentrations of NaCl

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ranging from 0 to 2 M were added to a number of cellulosic suspensions to probe the

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elecrostatic interactions among nanoparticles. 7 ACS Paragon Plus Environment

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Morphological Studies of Cellulose Particles

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Polarized Light Optical Microscopy (PLOM)

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Droplets of suspensions containing cellulose particles were sandwiched between a glass

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slide and a glass coverslip and color images were taken by a Nikon Eclipse LV100POL

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microscope.

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Atomic Force Microscopy (AFM)

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A Multimode atomic force microscope with Nanoscope IIIa controller (Digital

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Instruments/Veeco, Santa Barbara, CA, USA) was used to study the effect of hydrogen

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peroxide oxidation on cellulose nanoparticles morphology. Sample preparation was done

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by depositing a drop of poly-L-Lysine onto freshly cleaved mica attached to silicon

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wafers, rinsed off by deionized water after 5 min and air-dried. Next a 5 µL droplet of

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nanoparticles suspension (0.001 wt %) was dropped onto the treated mica surface,

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followed by a final rinse. The samples were allowed to dry at ambient air. AFM images

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were obtained in tapping mode using silicon cantilevers with a force constant of 37 N/m,

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a frequency range of 100 kHz to 500 kHz and a nominal tip radius of 6 nm.

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Transmittance Electron Microscopy (TEM)

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The size of cellulose nanoparticles was measured using recorded images of a Philips

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Tecnai 12 120 kV electron microscope equipped with a Gatan 792 Bioscan 1k × 1k Wide

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Angle Multiscan CCD camera. A 5 µL drop of suspension diluted to 0.05 wt% was

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placed on a copper grid coated by a thin carbon film for 5 min and negatively stained

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using a drop of 2% uranyl acetate solution for 30 s, which enhances the contrast. Excess

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sample was carefully blotted away from the edge of the grid with filter paper (Whatman

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Inc., Canada). 25 images were captured from each sample and the average sizes of 50 to

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70 isolated particles were calculated in each image with Image J software.

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Solid-State 13C NMR Spectroscopy

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Solid-state carbon-13 NMR spectra were recorded on a Varian/Agilent VNMRS

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instrument at a frequency of 100.5 MHz. Powdered original pulp and carboxylated CNC

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were compressed uniformly in 7.5 mm zirconium rotor and spun at 5,500 Hz. Spinning

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sidebands were suppressed by the TOSS sequence. A total of 6,000 transients at a contact

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time of 2 ms and a recycle delay of 2 s were averaged to obtain each spectrum.

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ATR-FTIR Spectroscopy

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Fourier transform infrared (FTIR) spectra of original pulp and carboxylated CNCs was

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acquired by a FTIR spectrometer (Perkin Elmer, Inc., USA) with single bounce diamond

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attenuated total reflectance (ATR) accessory. All dried samples were put directly on the

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ATR crystal and maximum pressure was applied by lowering the tip of the pressure

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clamp using a rachet-type clutch mechanism. The spectra were averaged from 32 scans at

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transmission mode from 400 to 4000 cm- with a resolution of 4 cm-1.

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X-Ray Diffraction (XRD)

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The crystallinity pattern of dried softwood pulp and carboxylated CNC were obtained

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through X-ray diffraction (XRD) to investigate the effects of catalyst-assisted H2O2

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oxidation on the crystalline properties of the cellulose. Both the cellulosic samples were

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pressed into a cylindrical sample holder that was 25 mm in diameter and 2 mm high. The

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measurements were carried out by a Bruker Discover D8 Discover two dimensional

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diffractometer with VANTEC 2D detector and CuKa radiation (k = 1.54 A°). The X-ray

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diffractograms were acquired with a 2θ range of 10°–40° at a scan rate of 0.005° s-1. 9 ACS Paragon Plus Environment

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RESULTS AND DISCUSSION

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Charge Content of Carboxylated CNCs

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Conductivity and pH changes of carboxylated CNC suspension versus the volume of

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NaOH added have been plotted in Figure 1. Carboxyl groups, rendering the particle

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electrically charged, play an important role in the colloidal stability of the particles and in

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minimizing aggregation.27 The amount of carboxyl groups calculated from this curve is

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1.0 mmol carboxylic acid per gram dried carboxylated CNC particles. A 0.1 mmol g-1

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variation was obtained in three repeat experiments. Hence, the carboxyl content is 1.0 ±

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0.1 mmol g-1. This is lower than the carboxyl content of HNC produced by periodate-

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chlorite oxidation (up to 6.6 mmol g-1).18 Fujisawa et al.27 reported a value of 1.74 mmol

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g−1 for the carboxyl content of TEMPO-oxidized cellulose nanofibrils. Although carboxyl

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and carbonyl groups have been formed on the cleaved C2-C3 of an anhydroglucose ring

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(secondary alcohols) through H2O2 oxidation, carboxyl groups are generally introduced

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on the C-6 position (primary alcohol), similar as in TEMPO-mediated oxidation. It

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should be noted that the number of oxidized hydroxyl groups placed on carbon atoms in a

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glycopyranose ring of cellulose molecules depends strongly on the type of oxidant used.21

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The maximum charge content of conventional CNC particles has been theoretically

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calculated about to be 0.8 mmol carboxylic acid per gram of a 10 nm by 10 nm crystal

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cross-section

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catalytic system is slightly greater than this theoretical maximum. The amorphous

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domains of cellulose are more sensitive to chemicals, because of easier accessibility, and

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can be dissolved during the oxidation reactions. However, the crystalline part is only

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attacked at the surface by diverse reactions. It has been also proposed that most of the

18

whereas the charge content of carboxylated CNC produced by our

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carboxyl groups are placed on amorphous chains protruding from the crystalline

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segments.28 Therefore, the observed difference in charge content could be due to

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protruding amorphous chains, a possibility investigated further by DLS (see section 3.2).

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Another explanation could be related to the self-assembly of CNCs into cylinder-shaped

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aggregates, resulting from longitudinal alignment of individual CNCs. The fact that the

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CNC we produce by catalyst mediated-H2O2 oxidation has a much larger diameter (~ 25

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nm) than individual CNC crystals (~ 5 nm) implies that the particles we produce are

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bundles of aligned nanorods. As it is unlikely that all rods inside the bundle are of the

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same length, it is possible that additional surface area is exposed at both ends of the rod.

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The zeta potential of the carboxylated CNCs prepared by H2O2 oxidation was found to be

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-20.8 mV which was close to that value of carboxylated spherical CNC (-24 mV) isolated

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by the APS procedure.15 It shows that the surface of CNC particles has been decorated

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with negatively charged carboxyl groups, creating the electrostatic repulsive forces that

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prevent the aggregation of the colloidal particles. Therefore, high stability of obtained

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carboxylated CNCs suspension over time as depicted in Scheme 1 (fractions 1 and 1՜ )

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can be ascribed to the electrostatic repulsion of negatively charged nanoparticles.

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[Figure 1]

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It is well known that metal catalysts used in H2O2 oxidation can drive the reaction to form

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hydroxyl and other free radicals and hydroxide ions. Equations 1 - 3 display the possible

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paths of the H2O2 reaction in the presence of copper ions, as proposed by Carvalho do

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Lago et al. 29

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Cu2+ + H2O2 → Cu1++ •O2- + 2H+

(1)

Cu1+ + H2O2 → Cu2++ •OH +OH-

(2)

2•O2- + 2H+ → H2O2 + O2

(3)

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The free radicals produced in the above reactions can react with cellulose and introduce

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aldehyde and carboxyl groups. A possible pathway is: RCH2OH + •OH



R•CHOH + H2O

(4)

R•CHOH + H2O2



RCHO + •OH + H2O2

(5)

RCHO + 2 •OH → RCOOH + H2O

(6)

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In an acidic (pH=1-2) environment, protons (H+) can protonate the oxygen involved in

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glycosidic bond, resulting in a cleavage of these linkages in the cellulose structure. Dias

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et al.24 found that depolymerisation of oxidized starch under acidic conditions was more

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extreme compared with that under alkaline conditions during starch modification.

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Particle Size Distribution

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The size distribution of the carboxylated CNC particles was examined by DLS as

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presented in Figure 2A. The equivalent hydrodynamic diameter of the nanoparticles

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prepared by H2O2 oxidation reaction is around 298 nm. The average diffusion coefficient

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of rod-shape nanocrystals is obtained by averaging over all orientations.18 The

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polydispersity index of suspension containing carboxylated CNCs is about 0.27, 12 ACS Paragon Plus Environment

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calculated by dividing the standard deviation of the particles size distribution by the

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average diameter (Figure 2A). In comparison, spherical CNCs obtained by in the H2O2

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oxidation APS had higher polydispersity (0.43).15 This implies that the initial the

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cellulose substrate was more degraded than the CNCs produced by APS process which

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would result in the production of more homogeneous particles. The uniformity of particle

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size has a significant impact on the performance of CNC as nanofillers or in food

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applications.

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The effect of various NaCl concentrations, ranging from 0 to 1000 mM, on the

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hydrodynamic diameter of carboxylated CNCs was monitored as another proof to support

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the electrostatic stability of the nanoparticles. According to Figure 2B, the equivalent

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hydrodynamic diameter of carboxylated CNC nanoparticles showed an almost constant

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trend as the salt concentration increase to about 300 mM, well beyond which sulfate-

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bearing CNC dispersions become unstable (above 25 mmol g-1).28 This finding implies

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that carboxylated CNCs prepared via catalyst assisted-H2O2 oxidation consist of only

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individual crystalline segments with few attached solubilized amorphous regions.

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Combined with the results of charge content, carboxylated CNCs produced by catalyst

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assisted-H2O2 oxidation cannot be classified into the HNCs category, albeit the presence

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of short amorphous hairs particularly at the poles of CNCs remains a possibility. As can

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be seen in Figure 2B, the equivalent hydrodynamic diameter of carboxylated CNC

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particles remarkably increased at salt concentrations higher than 300 mM. According to

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classic theory, increasing the electrolyte concentration results in reducing/eliminating the

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electrostatic repulsions between particles, leading to the coagulation of the charged

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nanoparticles. 13 ACS Paragon Plus Environment

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[Figure 2]

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277 278

Microscopic Observations of Carboxylated CNCs

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The morphological features of the products resulting from H2O2 oxidation process were

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examined by polarized optical micrographs as illustrated in Figure 3. Images of milky

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suspension containing carboxylated CNCs (Figure 3A) exhibit some particles that are

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hardly visible. The submicron particles, which cannot be seen in an optical microscope,

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were imaged by AFM. Figure 4A,B clearly shows the typical rod-like structure of

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nanoparticles after H2O2 oxidation. Images of precipitated particles (Figure 3B) under

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polarized light show microfibers with a length about 230 µm and a width around 25 µm.

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When the suspension is sonicated for 15 min with a low frequency (fraction 3), most of

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the microfibrils were completely broken up into particles in the range of nanometer as

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displayed in Figure 3,4C. This suspension also remained stable for up to one month

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(fraction 1՜ ). The yield of cellulosic nanoparticles extracted from softwood pulp by

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H2O2 reaction was 54 % whereas it reached up to 81 % in combination with ultrasound. It

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seems that H2O2-induced oxidation has caused less intense disruptions in some regions of

292

cellulose structure, allowing glycosidic bonds within the glucan chains to be easily

293

cleaved by using sonication, to give uniform particles in the nanometer scale. In

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agreement with this finding, Yang & van de Ven,30 reported a decrease in the mechanical

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energy required for breaking fibers down into nanosize particles by increasing the charge

296

content.

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[Figure 3]

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[Figure 4] 14 ACS Paragon Plus Environment

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[Figure 5]

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The dimensions of rod-like CNCs prepared with H2O2 oxidation were determined by

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TEM images as shown in Figure 5. The average length and diameter of nanoparticles in

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the milky suspension from fraction 1 (Figure 5A) were 263 ± 28 nm and 23 ± 5 nm,

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respectively, which is slightly lower than the value obtained from DLS measurements.

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Note that DLS overestimates the size of particle even for standard silica nanoparticles.28

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The sizes for ultrasonically treated sample from fraction 3 (Figure 5B) were around 305 ±

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90 nm and 30 ± 9 nm, values close to those of fraction 1. These dimensions are in the

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ranges of CNCs produced by other oxidation processes but with a greater diameter.16,18

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Solid-State 13C NMR

309

The NMR spectra of the original softwood pulp and carboxylated CNC prepared by H2O2

310

oxidation are presented in Figure 6. Typical signals characteristic of functional groups

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can be observed in the spectra. The peak between 100 and 110 ppm is assigned to the

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anomeric carbon C1 and that between 80 and 95 ppm is for C4. The next peaks in 70-80

313

ppm region are associated with C2, C3 and C5 carbons. The region between 60 and 70

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ppm is attributed to C6 of the primary alcohol group. In the cellulose spectra, the narrow

315

cluster at 89 ppm (C4) corresponds to anhydroglucose units in the crystalline parts. The

316

broad peak located in 84 ppm (C4’) is characteristic of the anhydroglucoses with less

317

order in cellulose structural arrangements.31

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The NMR spectra of the original softwood fiber and carboxylated CNCs were almost

319

identical, implying that no significant changes happened in the chain conformations of

320

the cellulose. However, the intensity of the peak around 65 ppm decreased up to 32 %

321

compared to the original cellulose fiber. This change can be a sign of –CH2OH oxidation 15 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

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in the C6 position to form –COOH groups on the CNC surface, rather than other

323

hydroxyl groups. The C1 signal intensity of the cellulose backbone decreased, indicating

324

that cleaving glycoside bonds of cellulose chains occurred. The multiple peaks located

325

between 70-80 ppm are attributed to the oxidation of hydroxyl groups and bond cleavage

326

of C2-C3 during H2O2 oxidation. Observed changes in the C4 and C4՜ signals can be

327

taken as proof for the formation of highly crystalline nanoparticles, in good agreement

328

with the NMR spectra of cellulose nanowiskers produced with sulfuric acid by Sèbe et

329

al.32 [Figure. 6]

330

331

ATR-FTIR Spectroscopy

332

The original softwood pulp and carboxylated CNC particles were further characterized by

333

FTIR spectroscopy as seen in Figure 7. Normalization of FTIR spectra of two cellulosic

334

samples was done to make a meaningful qualitative comparison. The broad band at 3330

335

cm-1 is due to the stretching vibration of –OH groups which was affected by the inter-

336

molecular or intra-molecular hydrogen bonds of the cellulose molecules. Higher intensity

337

of this broad peak in carboxylated CNCs arises from hydrogen bonds breaking during

338

H2O2 oxidation reactions and consequently more stretching vibration of –OH groups

339

compare to the intact softwood structure. The absorption peaks at around 2905, 1425 and

340

1021 cm-1 are attributed to C–H stretching vibrations, –CH2 scissoring and CH2–O–CH2

341

stretching, respectively.33 The peak located at 1738 cm-1 corresponds to C=O stretching

342

while the absorption at 1630 is related to the asymmetric stretching vibration of the

343

carboxyl groups of the oxidized CNCs.34 These emerged peaks support the formation of

344

carboxyl and carbonyl groups during H2O2 oxidation which is in accordance with the

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conductometric results. The possibility that these bands were due to aldehyde groups was

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disproved by performing a titration with hydroxylamine hydrochloride, a standard

347

method to determine aldehyde groups18. No aldehyde groups were found, proving the

348

bands cannot be due to aldehyde groups, but must be due to carboxyl groups. Of

349

importance to note is that most of carbonyl groups formed through the oxidation of the

350

hydroxyl groups have been converted to carboxyl groups. The carboxyl groups can be

351

employed as active sites in surface modifications, especially for immobilizing proteins

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and enzymes. [Figure 7]

353 354

Investigation of the Crystalline Structure by XRD

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Figure 8 presents X-ray diffraction patterns of softwood pulp and carboxylated CNCs

356

produced by H2O2 oxidation, confirming the NMR results. The diffraction patterns of two

357

cellulosic samples show a sharp peak at 2θ angle of 22.6° for the (200) peak and two

358

weak peaks at 2θ=15.1° for the (11ത0) peak and 2θ=16.5° for the (110) peak. These peaks

359

correspond to the main crystalline region of the cellulose structure35 which are almost

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identical in original pulp and carboxylated CNCs. It indicates that the original crystalline

361

structure of cellulose fibrils was well maintained during H2O2 oxidation reactions. This

362

finding is consistent with the reports about the crystallinity changes of cellulose caused

363

by APS16 or sulfuric acid.32

364

The crystallinity indices (C.I.) was calculated according to Segal et al.: 36

365

C. I. ሺ%ሻ =

ூమబబ ିூೌ೘ ூమబబ

×100

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where Iଶ଴଴ is the intensity obtained from the (200) plane reflection, Iୟ୫ is the minimum

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intensity between the (100) and (200) peaks. The C.I. of the original pulp and

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carboxylated CNC particles were 77.5 % and 70.5 %, respectively which exhibit a slight

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decrease after the reaction of cellulose pulp with H2O2 and catalyst for 3 days. It is known

370

that the amorphous regions and the surface of crystalline regions in cellulose are

371

kinetically more accessible to chemical reactions.9 Therefore, the decrease in crystallinity

372

could be explained by the fact that H2O2 oxidation-induced hydrolysis does not only

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happen at the amorphous regions but also at the surface of the crystalline parts of

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cellulose. In addition, some extensive surface modifications have possibly caused

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destructive changes in the crystalline structure of cellulose. Interestingly, these results are

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in good agreement with those of Wang et al.37 who studied CNCs produced from

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microcrystalline cellulose using a mixture of sulfuric acid and hydrochloric acid.

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Similarly, Yang and van de Ven,30 reported that crystalline index of softwood cellulose

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pulp (75 %) decreased to 49 % in dialdehyde modified cellulose (DAMC) obtained by

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periodate oxidation. This is related to opening of the glucopyranose rings of cellulose

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from C2-C3 bond during oxidation, resulting in detrimental lowering of the C.I, which

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possibly occurs also in carboxylated CNCs produced by H2O2 oxidation. In contrast, the

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carboxylated CNCs extracted by using APS under thermal conditions showed a higher

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crystallinity than that of the initial cellulose.15

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It is worth noting that the degree of crystallinity of carboxylated CNCs prepared by H2O2

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oxidation is high and close to that of CNCs generated with acid hydrolysis from bleached

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soft wood kraft37 and kenaf core woods38. Thus, the absence of significant changes in the

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total crystallinity of cellulose and high-crystalline CNCs show that the catalyst assisted-

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H2O2 oxidation method has great potential in the production of CNC nanoparticles. [Figure 8]

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391

In conclusion, a one-step procedure for producing carboxylated cellulose nanocrystals

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from softwood cellulose pulp was designed by applying H2O2 as an oxidant and

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CuSO4.5H2O catalyst. The use of H2O2 has significant benefits over other chemicals

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because of its easily removing and/or rapidly decomposing to water and oxygen after the

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hydrolysis processes. The mechanism of the reaction is based on penetration of free

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radical ions formed by catalyst-assisted H2O2 oxidation to the outer layer of the

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crystalline regions and all amorphous regions. Since the proposed method uses only non-

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expensive and environmentally friendly chemicals, it is capable of large-scale production

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of CNCs decorated with negatively charged carboxyl groups. Carboxylated CNCs

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displayed a rod-shaped morphology with high size uniformity and almost the same

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dimensions to other cellulose nanoparticles produced by oxidative methods, albeit with a

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larger width. The presence of carboxyl groups on the surface of CNCs was proved by

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conductometric titration and FTIR spectroscopy. DLS measurements with NaCl addition

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showed colloidal stability of carboxylated CNC suspension at salt concentrations less

405

than 400 mM, arising from the dominating electrostatic repulsions between the particles.

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The NMR and XRD results showed that original structure of cellulose fibrils is, to a large

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extent, maintained during H2O2 oxidation. More detailed studies are required to optimize

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parameters such as amount of H2O2, different catalysts, reaction time, temperature and

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pH and characterize carboxylated CNCs produced by H2O2 oxidation to tailor their

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applicability to different fields. 19 ACS Paragon Plus Environment

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ACKNOWLEDGEMENT

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The authors thank the financial support of the Iranian Ministry of Science, Research and

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Technology and the Natural Science and Engineering Research Council of Canada

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(NSERC Discovery grant 42686-13). They also acknowledge the access to facilities and

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instrumentation supported by the Pulp and Paper Research Centre and Department of

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Chemistry, McGill University.

417

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Figure and Scheme captions

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Scheme 1. Synthesis process diagram of carboxylated cellulose nanocrystals by catalyst

549

assisted-H2O2 oxidation.

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Figure 1. Conductometric titration result of 20 mg carboxylated cellulose nanocrystals

551

obtained by catalyst assisted-H2O2 oxidation.

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Figure 2. Particle size distribution of carboxylated cellulose nanocrystals obtained by

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catalyst assisted-H2O2 oxidation (A) and changes of the equivalent spherical diameter

554

versus salt (NaCl) concentration (B).

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Figure 3. Optical and polarized micrographs of (A) carboxylated cellulose nanocrystals

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from fraction 1 prepared by catalyst assisted-H2O2 oxidation; (B) precipitate from

557

fraction 2; and (C) ultrasonically treated precipitate from fraction 3. Scale bars of images

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(A), (B) and (C) are 10 µm.

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Figure 4. AFM height (A) and 3 D (B) images of carboxylated cellulose nanocrystals

560

from fraction 1 prepared by catalyst assisted-H2O2 oxidation; (C) cellulose nanocrystals

561

from fraction 3 after sonication.

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Figure 5. TEM image of carboxylated cellulose nanocrystals prepared from softwood

563

fibers (A) by catalyst assisted-H2O2 oxidation from fraction 1 and (B) after sonication

564

from fraction 3.

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Figure 6. Solid state carbon-13 NMR spectra of softwood pulp and carboxylated

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cellulose nanocrystals obtained by catalyst assisted-H2O2 oxidation.

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Figure 7. FTIR spectra of original softwood pulp and carboxylated cellulose nanocrystals

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obtained by catalyst assisted-H2O2 oxidation.

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Figure 8. XRD profiles of original softwood pulp and carboxylated cellulose nanocrystals

570

obtained by catalyst assisted-H2O2 oxidation.

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Figure graphics

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Soaked softwood pulp

574 Copper (II) sulfate pentahydrate-mediated H2O2 oxidation 575 Cellulosic products 576 Washing by centrifugation 577 White precipitate

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Supernatant (Dissolved oligosaccharides)

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Suspended in deionized water

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Decantation after 5 min

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Precipitate Milk-like suspension

Addition of water

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584

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Fraction 3 Stabilized by sonication

Fraction 2 Precipitate Fraction 1 Freshly prepared

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