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Jun 26, 2017 - School of Renewable Natural Resources, Louisiana State University Agricultural Center, Baton Rouge, Louisiana 70803, United. States. â€...
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THERMO-RESPONSIVE COPOLYMER POLY(NVINYLCAPROLACTAM) GRAFTED CELLULOSE NANOCRYSTALS: SYNTHESIS, STRUCTURE, AND PROPERTIES Jinlong Zhang, Qinglin Wu, Mei-Chun Li, Kunlin Song, Xiuxuan Sun, Sun-Young Lee, and Tingzhou Lei ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/ acssuschemeng.7b02033 • Publication Date (Web): 26 Jun 2017 Downloaded from http://pubs.acs.org on June 27, 2017

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THERMO-RESPONSIVE

COPOLYMER

POLY(N-VINYLCAPROLACTAM)

GRAFTED CELLULOSE NANOCRYSTALS: SYNTHESIS, STRUCTURE, AND PROPERTIES Jinlong Zhang1, Qinglin Wu1*, Mei-Chun Li1, Kunlin Song1, Xiuxuan Sun1, Sun-Young Lee2, and Tingzhou Lei3* 1School

of Renewable Natural Resources, Louisiana State University Agricultural Center, Baton

Rouge, LA 70803, USA 2Department

of Forest Products, Korea National Institute of Forest Science, Seoul, 130-

712, Republic of Korea 3 Key

Biomass Energy Laboratory of Henan Province, Zhengzhou, 450008, Henan, China

Corresponding Author: * E-mail: [email protected]

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ABSTRACT

A

novel

thermo-responsive

copolymer

poly(N-vinylcaprolactam)

grafted

cellulose

nanocrystals (PVCL-g-CNCs) was synthesized by using surface-initiated atom transfer radical polymerization, and its temperature responsive behavior was studied in this work. The chemical structure characterization by Fourier transform infrared spectroscopy, solid-state CP/MAS

13C

NMR spectroscopy and X-ray photoelectron spectroscopy confirmed the presence of covalently grafting PVCL chains on the CNC surface. The crystalline structure and nanorod-shaped morphology of CNCs were well preserved after polymerization. Transmission electron microscope results indicated that the surface of CNCs was covered with grafted PVCL brushes. The viscoelastic properties of PVCL-g-CNCs aqueous suspensions (1.0 wt%) by dynamic rheology measurements confirmed the thermally induced phase transition behavior. The work presented herein paves a way to design CNC-based advanced functional materials benefiting both from the intrinsic characteristics of CNCs and the new properties imparted by the temperature sensitive grafted polymer chains.

KEYWORDS: Poly(N-vinylcaprolactam), Thermal induced phase transition, Cellulose nanocrystals, Atom transfer radical polymerization, Temperature responsive polymer.

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INTRODUCTION Cellulose nanocrystals (CNCs), as an inexpensive, renewable and biodegradable nanomaterial, have received an increasing attention in recent years. CNCs possess many attractive properties, such as a large specific surface area, high modulus, unique optical properties and the ability to self-assemble into liquid crystalline phases, which makes them useful in nanocomposites [1-3]. However, as a consequence of poor dispersibility of CNCs in hydrophobic matrices, and weak interfacial adhesion among different phases, their composites generally exhibit poor mechanical properties. A feasible approach is to modify the CNC surface with hydrophobic monomers, leading to improved stability and dispersibility of CNCs in hydrophobic matrices [4]. A diverse set of powerful polymerization tools have been used to tailor the surface of CNCs and other nanocellulose materials for creating uniquely surface-functionalized nanomaterials. These techniques include reversible deactivation radical polymerization (atom transfer radical polymerization (ATRP) [5-8], reversible addition-fragmentation chain transfer polymerization [9] and nitroxide-mediated radical polymerization [10]), ring open polymerization [11-12], olefin metathesis polymerization (ring open metathesis polymerization [13] and acyclic diene metathesis polymerization [14-15]) and postmodification by click chemistry (copper catalyzed azide-alkyne cycloaddition, diels-alder reaction and thiol-ene reaction) [16-17]. Among these methods, the ATRP technique has emerged as a robust synthesis tool, which is compatible with a wide range of initiators, monomers, and solvents [18-19]. ATRP is also a desirable surface functionalization technique as it does not compromise the surface morphology and structure of the substrate [20]. The robustness and versatility of ATRP can lead to a precise control over molecular architecture in term of chain topology, composition and functionality [7, 21]. Covalently functionalized CNCs with polymer brushes to tune the hydrophilic surface of CNCs 3 ACS Paragon Plus Environment

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were widely reported in recent years. The functionalized CNCs with polystyrene (PS) by ATRP strategy were firstly published by Yi et al [22]. Subsequent investigations were reported by Morandi et al concerning the optimizing surface initiated ATRP (SI-ATRP) of polymer brushes from the CNC surface [5, 23]. Different types of polymers have been grafted from CNCs through ATRP method after these developments such as PS [5, 22, 24-25], poly(methyl methacrylate) [26], poly(methyl acrylate) [27], poly(2-aminoethylmethacrylamide) [28-29], (tertbutyl acrylate) [7, 30], poly(butyl acrylate) [31], poly(2-aminoethylmethacrylate) and poly(2aminoethylmethacrylamide) [32], poly(6-(4-(4-methoxyphenylazo)phenoxy)hexyl methacrylate [33], soybean amide methacrylate [8] and poly(methyl methacrylate)-co-butyl acrylate) [34]. The grafting of hydrophobic polymers onto the surface of CNCs promoted the compatibility between CNCs and hydrophobic matrices, which facilitated the dispersibility of CNCs in the hydrophobic matrices, enhanced the interfacial adhesion, and subsequently improved the toughness of CNCs based nanocomposites. Recently, the surface functionalized CNCs with responsive polymers, which respond to external stimuli such as pH [35], light [36-37] and temperature [38], have been of significant interest. Temperature responsive CNCs have been synthesized with polymers such as poly(N, Ndiethylacrylamide)

[9]

and

poly(N-isopropylacrylamide)

(PNIPAM)

[20,

39],

and

poly(oligoethylene glycol) methyl ether acrylate (POEGMA) [40], which possess a well-defined thermal induced phase transition. Compared to the extensive studies of PNIPAM based thermoresponsive hybrid materials, the research on the thermoresponsive property of poly(Nvinylcaprolactam) (PVCL) based hybrid materials is still in its infancy. PVCL has many unique characteristics, such as solubility in water and organic solvents, non-toxicity, biocompatibilility, nonionic nature, temperature sensitivity, and the presence of both hydrophilic and hydrophobic 4 ACS Paragon Plus Environment

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groups in its structure [41-43]. These properties make it an interesting candidate for the applications in the biomedical and environmental areas. PVCL grafted carbohydrate polymer (chitosan, alginate or dextrans) hydrogel, nanoparticles, microspheres and beads have been studied for the application of drug delivery [44-45]. The chitosan-g-PVCL beads in the controlled release experiment showed a slow and steady release of the drug from the beads as its strong hydrophobic interactions with the drug molecules [45]. Another application of PVCL in the environmental field is to remove toxic wastes from water. PVCL was used to remove phenols from waste water due to its complexing ability with phenols [46]. Taking advantages of its biocompatibility as well as thermoresponsive properties, PVCL has also been used for the environmentally friendly flocculating polymer in combination with chitosan, a polyelectrolyte [47]. Although an increasing number of studies concerning PVCL appeared recently, cellulose or cellulose nanocrystals (CNCs) based thermoresponsive PVCL hybrid materials were only a few reported up to now. Studies on grafting of PVCL on cellulose (polysaccharide) or its derivatives were reported from the conventional free radical polymerization, such as PVCL grafted cotton fabrics, PVCL grafted dextran and PVCL grafted sodium alginate copolymers [48-51]. Although the synthesis and characterization of PVCL/CNCs nanocomposite hydrogels by the frontal polymerization were reported [52]. That particular paper was mainly focused on the reinforcement and dispersion of CNCs in the PVCL/CNCs nanocomposite hydrogels through dynamic viscoelastic measurements. However, there was a lack of detailed discussion on the chemical structure of the hydrogels with the frontal polymerization and their thermo-responsive behavior. Compared with the frontal polymerization/conventional free radical polymerization, the controlled radical polymerization could precisely control the molecular structure of grafted 5 ACS Paragon Plus Environment

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PVCL brushes on the surface of CNCs. To our knowledge, there are very few reports dealing with the surface initiated ATRP of NVCL-based polymers. The graphene oxide functionalized with PVCL by the ATRP strategy was reported by Kavitha and co-workers [53]. Karesoja and co-workers reported the surface modification of mesoporous silica particles with PEO-b-PVCL copolymers to prepare thermoresponsive hybrid nanoparticles through the ATRP and click reaction [54]. To the best of our knowledge, this is the first paper for the exploration of synthesis via the ATRP strategy and thermal responsive behavior of copolymer PVCL-g-CNCs. The biocompatible, biodegradable and thermos-responsive properties of PVCL-g-CNCs are useful in controlled drug delivery. The objective of this study was to functionalize CNCs with PVCL and to elucidate its temperature responsive behavior. The initiator modified CNCs (Br-CNCs) were first prepared through esterification reaction. PVCL was then grafted from macroinitiator Br-CNCs through SIATRP. The chemical structure of Br-CNCs and PVCL-g-CNCs was confirmed by attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR), solid-state CP/MAS

13C

NMR spectroscopy and X-ray photoelectron spectroscopy (XPS). The crystalline structure, morphology as well as thermal property were subsequently characterized by wide-angle x-ray diffraction (WAXD), solid-state CP/MAS

13C

NMR spectroscopy, transmission electron

microscopy (TEM) and thermogravimetric analysis (TGA). The temperature-induced phase transition behavior was further investigated through the rheology measurement. EXPERIMENTAL SECTION Materials. Microfibrillated cellulose (Celish KY 100-S grade, 25% solid content) was purchased from Daicel Chemical Industries, Ltd. (Tokyo, Japan). Copper bromide (CuBr, 98%,

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Acros Organics, Morris Plains, NJ, USA) was purified by stirring in glacial acetic acid, filtering and washing with methanol, followed by drying in vacuum at 30oC overnight. N,N,N',N'',N''pentamethyldiethylenetriamine (PMDETA, 99%, Sigma-Aldrich, St. Louis, MO, USA), Nvinylcaprolactam (NVCL, 98%, Sigma-Aldrich, St. Louis, MO, USA), triethylamine (TEA, ≥99%, Sigma-Aldrich, St. Louis, MO, USA), 2-bromoisobutyryl bromide (BIBB, 98%, Acros Organics, Morris Plains, NJ, USA) and 4-dimethylaminopyridine (DMAP, 99%, Acros Organics, Morris Plains, NJ, USA) were used without further purification. N,N-dimethylformamide (DMF, anhydrous, ≥99.8%, Sigma-Aldrich, St. Louis, MO, USA) was purified with the solvent purification system. Other reagents were used as received. Preparation of CNCs. Microfibrillated cellulose was mixed with sulfuric acid (64 wt%), followed by mechanical stirring at 50 oC for 3 h to allow its hydrolysis. The obtained suspensions were subsequently diluted with excessive deionized water and then dialyzed with deionized water using semipermeable membrane (cutoff molar mass 12000-14000) to remove residual sulfuric acid for 7 days until neutrality was reached. The resultant CNC suspensions were further treated using a high pressure homogenizer (Microfluidizer M-110P, Microfluidics Corp., Newton, MA, USA). CNCs were finally recovered from the resultant suspensions by freeze-drying the suspensions for three days. Synthesis of Br-CNCs and PVCL-g-CNC copolymer. The synthesis of PVCL-g-CNC copolymer was performed in two steps as illustrated in Scheme 1. Dry CNCs (3.10 mmol) were dispersed in DMF (15.0 ml) under stirring, and TEA (10.04 mmol) was subsequently added after CNCs were completely dispersed, followed by the addition of DMAP (2.21 mmol). 2-bromoisobutyryl bromide (9.71 mmol) was then added dropwise to the

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above CNC suspensions in an ice/water bath. The mixture was stirred at room temperature for 24 h. The resultant mixture was poured into an excess amount of deionized water to remove any residual small molecules and then precipitated as white floccules. Purification of the modified CNCs was carried out by redispersing them in DMF and reprecipitating them in deionized water for three times. Yellow powder of Br-CNCs was finally obtained after drying the precipitated materials under vacuum at 30 oC for 24 h to a constant weight.

Scheme 1 Synthesis routes of PVCL-g-CNC copolymer The formed macroinitiator Br-CNCs then initiated the grafted polymerization of NVCL through a SI-ATRP procedure. The Br-CNCs (0.312 mmol), N-vinylcaprolactam (31.2 mmol) and PMDETA (0.312 mmol) were mixed in DMF in a 25 ml round bottom flask under magnetic stirring. The mixture was then degassed with three freeze-pump-thaw cycles after Br-CNCs were completely dispersed. CuBr (0.312 mmol) was then quickly added into the flask under nitrogen atmosphere, and the flask was degassed again with three freeze-pump-thaw cycles. Thereafter, 8 ACS Paragon Plus Environment

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the flask was immersed into an oil bath preheated at 75 oC. The polymerization was stopped after 12 h by exposing the mixture to air, and DMF was subsequently added to dilute the solution. The product was passed through an activated alumina column to remove copper complex, condensed by rotary evaporation and then precipitated in excess n-hexane. The resulting precipitation was dissolved in dichloromethane, strongly sonicated for 5 min and then centrifuged three times to remove unreacted NVCL monomer and PVCL homopolymer. Finally, the resultant PVCL-gCNC copolymer was collected and dried under vacuum at room temperature to a constant weight. Attenuated total reflectance Fourier transform infrared spectroscopy. ATR-FTIR analysis was conducted in the transmittance mode. The scanning range of wavenumbers was from 4000 to 800 cm-1 with a resolution of 2 cm-1 and accumulation of 132 scans. The spectra were collected using the FTIR spectrophotometer (Nicolet Nexus 670-FTIR, Thermo Electron Corporation, Gormley, Canada). Solid-state CP/MAS

13C

NMR spectroscopy. Solid-state

13C

NMR spectroscopy

measurements were performed with a Bruker Avance 400 WB instrument operated at 100.6 MHz at room temperature. The CP/MAS experiments were performed with a relaxation delay of 4.0 s and a contact time of 2.0 ms. Magic angle spinning (MAS) was achieved at a rate of 4 kHz. The chemical shift was in ppm related to an external sample of tetramethylsilane (TMS). The change of CNCs in crystallinity before and after the esterfication reaction was further calculated. The crystallinity index (CrI) [27, 55] was determined according to:

CrI 

Area of crystallin e region Area of crystallin e region Area of amorphous region

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where the areas of crystalline region and amorphous region were corresponded to the integrals of C4 in the range of 86-92 ppm and 80-86 ppm, respectively. X-ray photoelectron spectroscopy. XPS spectra were recorded using a Specs PHOIBOS-100 spectrometer (SPECS, Berlinm, Germany) with an Al Ka irradiation (1486.61 eV) at 10 kV and 10 mA. Survey scans were conducted from 1200 to 0 eV with pass energy of 40 eV and scan step of 1.0 eV. The high resolution C 1s spectra were recorded at pass energy of 40 eV and scan step of 0.1 eV. Thermogravimetric analysis. TGA was carried out using a TA Q50 thermo-gravimetric analyzer (TA Instruments Inc., New Castle, DE, USA) from 25 to 600 oC at a heating rate of 10 oC/min

under nitrogen atmosphere.

Wide-angle x-ray diffraction. WAXD patterns were measured using a Bruker Siemens D5000 X-ray diffractometer (Bruker AXS Inc., Madison, WI, USA) operated at the Cu Ka radiation (λ=0.154 nm) with 40 kV and 30 mA in a 2θ range from 4 to 40o at a step size of 0.02o. Transmission electron microscopy. The morphology was observed with a transmission electron microscope (JEM 1400, JEOL, Peabody, MA, USA) at an accelerating voltage of 120 kV. Drops of about 0.001 wt% CNC or PVCL-g-CNC suspension were deposited onto glowdischarged carbon-coated TEM grids. The liquid in excess was absorbed with filter paper, and a drop of 2% uranyl acetate was deposited onto the specimen prior to drying. The stain in excess was blotted, and the remaining thin liquid film was allowed to dry. The TEM grids were allowed to dry at room temperature for 3 hours before imaging. Rheology. Rheology measurements were carried out using a TA Instruments Rheometer (AR 2000, TA Instruments Inc., New Castle, DE, USA). A cone-and plate geometry with a cone 10 ACS Paragon Plus Environment

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diameter of 40 mm and a 2o truncation angle was employed at a constant shear rate of 150 s -1, and the temperature was controlled by a Peltier plate. The dynamic viscoelastic properties (dynamic storage modulus G′ and loss modulus G″) of the sample were measured by oscillatory shear experiments performed at a fixed frequency of 1 Hz in a temperature ramp of 25 to 90 oC with a heating or cooling rate of 3oC/min. The steady state viscosity measurement for the aqueous dispersions of CNCs and PVCL-g-CNCs was carried out in a temperature ramp of 25 to 90 oC. The 1.0 wt% aqueous suspensions were prepared by dispersing the powder sample into deionized water with a strong stirring for more than 10 min in order to get a homogeneous suspension as much as possible. RESULTS AND DISCUSSION Chemical structure. The FTIR spectra of CNCs, Br-CNCs, NVCL and PVCL-g-CNCs as well as digital photographs of CNCs, Br-CNCs and PVCL-g-CNCs are shown in Figure 1 (a-b). Compared to the spectrum of CNCs, the appearance of C=O group at 1736 cm-1 in Br-CNCs indicated that the bromoisobutyryl ester moiety was bonded onto the surface of CNCs [21]. In addition, the broad stretching band of –OH groups at 3600-3100 cm-1 in CNCs was significantly decreased, demonstrating that the hydroxyl groups were substituted and converted to ester bonds. The peak of double bond (-C=C-) in the spectrum of NVCL was observed at 1651 cm-1, and the vinyl peaks (=CH and =CH2) were located at 3104 and 991 cm-1 [57]. However, the peaks of double bond were disappeared after polymerization. It can be concluded that the polymerization of PVCL was successfully achieved. The solid state

13C

NMR spectra of CNCs, Br-CNCs, NVCL and PVCL-g-CNC copolymer

are displayed in Figure 2. By comparison of CNCs and Br-CNCs, the new peaks in Br-CNCs at

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56 ppm (C7), 31 ppm (C8) and around 170 ppm (C9) were assigned to the quaternary carbon, methyl groups and carbonyl carbon of the attached 2-bromoisobutyryl ester groups, which indicated that the 2-bromoisobutyryl ester moiety reacted with the hydroxyl groups of CNCs. In addition, no substantial modifications were observed for CNC backbone in the 60-110 ppm region, indicating that the esterification reaction did not remarkably affect the backbone structure of CNCs. For PVCL-g-CNC copolymer, the peaks for CNC backbone were clearly observed. The characteristic peaks belonging to vinyl groups in NVCL shifted to the range of 38-45 ppm (C10 and C11) in the PVCL-g-CNC copolymer. The above analysis confirmed the successfully grafted polymerization of PVCL onto the surface of CNCs.

Figure 1 FTIR spectra of CNCs, Br-CNCs, NVCL and PVCL-g-CNC copolymer (a) and digital pictures of CNCs, Br-CNCs and PVCL-g-CNC copolymer (b) The solid-state

13C

NMR spectroscopy is not only used for structural identification, but also

used for the determination of degree of substitution (DS) and CrI [58-59]. The DS value of Br-

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CNCs was determined by the amount of 2-bromoisobutyryl bromide grafted, and calculated according to:

DS 

I CH3

(2)

2I O  CH  O

where I CH 3 represents the integral area of the carbon peak of methyl group from the grafted 2bromoisobutyryl ester moiety, and IO-CH-O denotes the integral area of the carbon peak of C1 in the backbone of CNCs. The DS value was calculated to be 0.78 [60]. The relatively low DS may be explained by the fact that most hydroxyl groups in CNCs were not available for the reaction due to the crystalline character and hydrogen bonding. The CrI values for CNCs and Br-CNCs were about 54% and 59%, respectively, which were in the typical crystallinity value range of 5580% [61]. The CrI values before and after esterification reaction confirmed that no damage occurred on the backbone structure of CNCs after the immobilization of 2-bromoisobutyryl ester moiety onto the surface of CNCs.

Figure 2 Solid-state CP/MAS 13C NMR spectra of CNCs (a), Br-CNCs (b), NVCL (c), and PVCL-g-CNC copolymer (d) 13 ACS Paragon Plus Environment

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The XPS spectra of CNCs, Br-CNCs and PVCL-g-CNC copolymer are shown in Figure 3. For Br-CNCs, bromine element as new peaks at around 182 eV (3p) and 70 eV (3d) was observed except for the same peaks in CNCs. In addition, a new peak for the C=O (288 eV) bond appeared in the high resolution spectrum of Br-CNCs. As shown in Table S1, the value for the O/C ratio in Br-CNCs was slightly reduced compared with that of CNCs. These results indicated the immobilization of 2-bromoisobutyryl ester moiety onto the surface of CNCs. For the PVCL-gCNC copolymer, the presence of distinctive nitrogen signal was a further indication that PVCL chains were presented on the surface of CNCs.

Figure 3 XPS full survey spectra of CNCs, Br-CNCs and PVCL-g-CNC copolymer (a) and deconvolved curves of C 1s in the high resolution spectrum of CNCs (b), Br-CNCs (c) and PVCL-g-CNC copolymer (d) It should be pointed out that the molecular weight of grafted PVCL chains is not available here as the process for sufficiently cleaved PVCL chains did not succeed. PVCL-g-CNCs were attempted for hydrolysis to cleave PVCL grafting chains from the CNC backbones for gel

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permeation chromatography test as the ester bond between CNCs and PVCL chains was the obvious site to hydrolyze [20,39]. It is possible that CNC backbones were tightly wrapped around by the grafted PVCL chains, resulting in the ester linkage less accessible. Similar issues were also reported for the hydrolysis of cellulose or CNCs based grafted polymer brushes [56, 62-63]. Crystallinity Structure and Morphology. WAXD patterns for CNCs, Br-CNCs and PVCLg-CNCs are shown in Figure S1. Both CNCs and Br-CNCs had typical patterns of the native crystalline form of cellulose I [20]. There were 2θ diffraction peaks at 14.8o, 16.5o, 22.6o and 34.4o, which represent the lattice planes (110), ( 110 ), (200) and (400), respectively [55, 64]. These results verified that esterification reaction just occurred on the surface of CNCs and did not significantly alter the crystallite region of CNCs. In addition, the X-ray patterns of CNCs did not show a considerable change after being grafted with PVCL, which indicated that the polymerization of PVCL only took place on the surface of CNCs.

Figure 4 TEM images of CNCs (a and b) and PVCL-g-CNCs (c and d)

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The TEM images of CNCs and PVCL-g-CNCs are shown in Figure 4. The particle lengths of CNCs were between 100 and 300 nm. The particle widths were fairly uniform in the range of 1520 nm. These measurements are in close agreement with the dimensions of CNCs derived from microcrystalline cellulose, as observed in literature [1]. For PVCL-g-CNCs, the particle lengths and widths were about 172 and 32 nm, respectively. Compared to CNCs, PVCL-g-CNCs had similar shape and size with well-preserved nanorod-shaped morphology (except width increase), which was also consistent with the above results of WAXD and solid-state

13C

NMR

measurements. These results also indicated that the morphology of CNCs after grafting polymerization of PVCL was not apparently destroyed. On the other hand, CNCs had a relatively smooth surface, while a rough surface for the grafting PVCL layers was observed. These results indicated the grafted PVCL brushes were covered on the surface of CNCs. Thermal Stability Properties. Thermogravimograms of CNCs, Br-CNCs and PVCL-g-CNC copolymer are shown in Figure 5. The CNCs showed two separate pyrolyses within a wider temperature range rather than one pyrolysis because trace residue of sulfuric acid in the CNCs reduced the degradation temperature. The decomposition ranges were from 150 to 230 oC and from 250 to 375 oC with a maximum decomposition rate at 301 oC and a residual weight of 6.4 wt%. The Br-CNCs showed an initial pyrolysis at 169 oC with a maximum decomposition rate at 264 oC and a higher residual weight of 22.0 wt%. The decomposition shifted to lower temperature due to the lower thermal stability of grafted initiator (2-bromoisobutyryl ester moiety) on the surface of CNCs. The decomposition of PVCL-g-CNCs displayed two stages with the first stage from 200 to 400oC for CNCs and the second stage from 450 to 577 oC for grafted PVCL [65]. The maximum decomposition rate of PVCL-g-CNC copolymer was about 281 oC, and its residual weight was 1.64 wt%. 16 ACS Paragon Plus Environment

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Figure 5 Thermal stability (TG (a) and DTG (b)) of CNCs, Br-CNCs and PVCL-g-CNC copolymer

Figure 6 Viscoelastic properties (G′ and G″) for 1.0 wt% aqueous suspensions of CNCs and PVCL-g-CNCs from oscillatory shear experiments at a frequency of 1 Hz, a strain amplitude of 1.0 and a heating rate of 3oC/min Thermal Responsive Behavior. The viscoelastic properties (storage modulus G′ and loss modulus G″) as a function of temperature for 1.0 wt% aqueous suspensions of CNCs and PVCL17 ACS Paragon Plus Environment

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g-CNCs are shown in Figure 6. For CNCs, the values of G′ and G″ were nearly constant as the temperature raised from 25 to 60 oC. However, in the case of PVCL-g-CNC copolymer, below its low critical solution temperature (LCST, 36 oC determined at the point, G′ > G″), the PVCL chains were extended due to their hydrophilic nature, and it had low G′ and G″. The LCST of 36 oC

was relatively higher than that of the PVCL homopolymer reported in the literature (32 oC)

[42, 44]. The slightly higher LCST observed in PVCL-g-CNCs may be due to the solubility issues. The PVCL-g-CNCs was not soluble in water and appeared in the suspensions at room temperature although both CNCs and PVCL are hydrophilic polymers. The heterogeneous suspensions should have somewhat influence on the performance of rheology test. Similar situation was found for the PNIPAM-g-CNCs reported in the reference [60]. Above the LCST, PVCL chains collapsed into a thin hydrophobic layer on the CNC surface, and hence G′ and G″ significantly increased.

Figure 7 Elucidation of temperature responsive phase transition of PVCL-g-CNC copolymer influenced by temperature change (a), and digital photographs of aqueous suspensions of PVCLg-CNCs (1.0 wt%) at 25 oC (b) and 70 oC (c). 18 ACS Paragon Plus Environment

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The mechanism for temperature induced phase transition behavior of PVCL-g-CNCs is proposed as shown in Figure 7 (a). At temperature below the LCST, the hydrophilic PVCL chains were extended. Entropic repulsive interactions between particles made the aggregation or connection between particles unfavorable [66]. Therefore, they had low G′ and G″ as confirmed by the dynamic rheology measurement. Upon heating above the LCST, the hydrophobic nature of the PVCL globules dominated the inter-particle attractions among CNC particles, and the absence of any electrostatic repulsion formed coagulation of PVCL-g-CNCs with evidence of the increased G′ and G″ in the dynamic rheology measurement [39]. In addition, the digital photographs of aqueous suspensions of PVCL-g-CNCs (1.0 wt%) in Figure 7 (b-c) displayed the opaque-to-transparent transition, which also confirmed the temperature responsive phase transition behavior. CONCLUSIONS Temperature responsive PVCL-g-CNC copolymer was synthesized through SI-ATRP. The peaks of double bond as well as the vinyl group disappeared in the spectrum of CNCs-g-PVCL copolymer by the ATR-FTIR spectroscopy and solid-state 13C NMR spectroscopy measurement confirmed grafting polymerization of PVCL on the surface of CNCs. A new signal of nitrogen element observed in the spectrum of PVCL-g-CNC copolymer by the XPS measurement also supported the grafting polymerization. The crystalline structure and nanorod-shaped morphology of CNCs before and after polymerization were well-preserved, confirmed by the WAXD, solidstate

13C

NMR spectroscopy and TEM measurements. The dynamic rheology measurement

confirmed the temperature responsive phase transition behavior for aqueous suspensions of PVCL-g-CNCs (1.0 wt%). The mechanism for temperature responsive phase transition was that the hydrophilic PVLC chains transformed into hydrophobic ones upon its LCST, and then 19 ACS Paragon Plus Environment

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collapsed into a thin hydrophobic layer on the surface of CNCs. The temperature sensitivity of the aggregation properties provides the polymer-decorated CNCs as an opportunity for preparation of advanced CNC-based functional materials. ASSOCIATED CONTENT Supporting Information Atomic percentage and WAXD patterns of CNCs, Br-CNCs and PVCL-g-CNC copolymer were shown in the supporting information. AUTHOR INFORMATION Corresponding Authors * E-mail: [email protected] and [email protected] Author Contributions The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript. Notes The authors declare no competing financial interest. ACKNOWLEDGMENT The authors would like to acknowledge the financial support from Louisiana Board of Regents [LEQSF(2015-17)-RD-B-01], Louisiana State University EDA program, and Korea National Institute of Forest Research through a cooperative project to the LSU AgCenter. Appreciation is also given to Dr. Donghui Zhang and her graduate student Zhaoyuan Liu in the Department of Chemistry at LSU for the technical help and for the access of the solvent purification system in her group. 20 ACS Paragon Plus Environment

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Green Composites with High Performance from Poly(lactic acid) and Surface-Modified Microcrystalline Cellulose. J. Mater. Chem. 2012, 22, 15732-15739. DOI: 10.1039/C2JM32373G (59) Yue, Y. Y.; Han, J. Q.; Han, G. P.; Zhang, Q. G.; French, A. D.; Wu, Q. L. Characterization of Cellulose I/II Hybrid Fibers Isolated from Energycane Bagasse during the Delignification Process: Morphology, Crystallinity and Percentage Estimation. Carbohydr. Polym. 2015, 133, 438-447. DOI: 10.1016/j.carbpol.2015.07.058 (60) Ifuku, S.; Kadla, J. F. Preparation of a Thermosensitive Highly Regioselective Cellulose/ N-isopropylacrylamide Copolymer through Atom Transfer Radical Polymerization. Biomacromolecules 2008, 9, 3308-3313. DOI: 10.1021/bm800911w (61) Han, J. Q.; Zhou, C. J.; Wu, Y. Q.; Liu, F. Y.; Wu, Q. L. Self-Assembling Behavior of Cellulose Nanoparticles during Freeze-Drying: Effect of Suspension Concentration, Particle Size, Crystal Structure, and Surface Charge. Biomacromolecules 2013, 14, 1529-1540. DOI: 10.1021/bm4001734 (62) Sui, X. F.; Yuan, J. Y.; Zhou, M.; Zhang, J.; Yang, H. J.; Yuan, W. Z.; Wei, Y.; Pan, C. Y. Synthesis of Cellulose-Graft-Poly(N,N-dimethylamino-2-ethyl methacrylate) Copolymers via Homogeneous ATRP and Their Aggregates in Aqueous Media. Biomacromolecules, 2008, 9, 2615-2620. DOI: 10.1021/bm800538d (63) Lacerda, P. S. S.; Barros-Timmons, A. M. M. V.; Freire, C. S. R.; Silvestre, A. J. D.; Neto, C. P. Nanostructured Composites Obtained by ATRP Sleeving of Bacterial Cellulose Nanofibers with Acrylate Polymers. Biomacromolecules, 2013, 14, 2063-2073. DOI: 10.1021/bm400432b (64) Sèbe, G.; Ham-Pichavant, F.; Pecastaings, G. Dispersibility and Emulsion-Stabilizing Effect of Cellulose Nanowhiskers Esterified by Vinyl Acetate and Vinyl Cinnamate. Biomacromolecules 2013, 14, 2937-2944. DOI: 10.1021/bm400854n (65) Kozanoglu, S. Polymerization and Characterization of N-vinylcaprolactam. Master Thesis, Middle East Technical University, Ankara, Turkey, 2008. (66) Azzam, F.; Siqueira, E.; Fort, S.; Hassaini, R.; Pignon, F.; Travelet, C.; Putaux, J. L.; Jean, B. Tunable Aggregation and Gelation of Thermoresponsive Suspensions of PolymerGrafted Cellulose Nanocrystals. Biomacromolecules 2016, 17, 2112-2119. DOI: 10.1021/acs.biomac.6b00344

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Synopsis: Cellulose nanocrystals as sustainable and biodegradable materials were used for the synthesis of temperature responsive materials, poly(N-vinyl caprolactam) grafted cellulose nanocrystals.

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Scheme 1 Synthesis routes of PVCL-g-CNC copolymer 152x100mm (300 x 300 DPI)

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Figure 1 FTIR spectra of CNCs, Br-CNCs, NVCL and PVCL-g-CNC copolymer (a) and digital pictures of CNCs, Br-CNCs and PVCL-g-CNC copolymer (b) 101x103mm (300 x 300 DPI)

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Figure 2 Solid-state CP/MAS 13C NMR spectra of CNCs (a), Br-CNCs (b), NVCL (c), and PVCL-g-CNC copolymer (d) 101x85mm (300 x 300 DPI)

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Figure 3 XPS full survey spectra of CNCs, Br-CNCs and PVCL-g-CNC copolymer (a) and deconvolved curves of C 1s in the high resolution spectrum of CNCs (b), Br-CNCs (c) and PVCL-g-CNC copolymer (d) 101x81mm (300 x 300 DPI)

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Figure 4 TEM images of CNCs (a and b) and PVCL-g-CNCs (c and d) 101x102mm (300 x 300 DPI)

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Figure 5 Thermal stability (TG (a) and DTG (b)) of CNCs, Br-CNCs and PVCL-g-CNC copolymer 101x37mm (300 x 300 DPI)

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Figure 6 Viscoelastic properties (G′ and G″) for 1.0 wt% aqueous suspensions of CNCs and PVCL-g-CNCs from oscillatory shear experiments at a frequency of 1 Hz, a strain amplitude of 1.0 and a heating rate of 3oC/min 152x109mm (300 x 300 DPI)

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Figure 7 Elucidation of temperature responsive phase transition of PVCL-g-CNC copolymer influenced by temperature change (a), and digital photographs of aqueous suspensions of PVCL-g-CNCs (1.0 wt%) at 25 oC (b) and 70 oC (c). 152x169mm (300 x 300 DPI)

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TOC 200x110mm (96 x 96 DPI)

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