Structural Evolution and Formation Mechanism of the Soft Colloidal

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Structural Evolution and Formation Mechanism of the Soft Colloidal Arrays in the Core of PAAm Nanofibers by Electrospun Packing Qifeng Mu, Qingsong Zhang, Lu Gao, Zhiyong Chu, Zhongyu Cai, Xiaoyong Zhang, Ke Wang, and Yen Wei Langmuir, Just Accepted Manuscript • DOI: 10.1021/acs.langmuir.7b02275 • Publication Date (Web): 06 Sep 2017 Downloaded from http://pubs.acs.org on September 7, 2017

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Structural Evolution and Formation Mechanism of the Soft Colloidal Arrays in the Core of PAAm Nanofibers by Electrospun Packing Qifeng Mu,† Qingsong Zhang,*,† Lu Gao,‡ Zhiyong Chu,‡ Zhongyu Cai,§ Xiaoyong Zhang,‖ Ke Wang,‖ and Yen Wei*,‖ † State Key Laboratory of Separation Membranes and Membrane Processes, School of Materials Science and

Engineering, Tianjin Polytechnic University, Tianjin 300387, China ‡School of Textiles, Tianjin Polytechnic University, Tianjin 300387, China §Department of Chemistry, University of Pittsburgh, Pittsburgh, PA 15260, USA ‖Department of Chemistry, Tsinghua University, Beijing 100084, China

*Corresponding

author. Email: [email protected], [email protected]

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ABSTRCT: Electrospinning provides a facile and versatile method for generating nanofibers from a large variety of starting materials, including polymers, ceramic, composites

and

micro/nanocolloids.

In

particular,

incorporating

functional

nanoparticles (NPs) with polymeric materials endows the electrospun fibers/sheets novel or better performance. This paper evaluates the spinnability of polyacrylamide (PAAm) solution containing thermo-responsive poly(N-isopropylacrylamide-cotert-Butyl acrylate) microgel nanospheres (PNTs) prepared by colloid electrospinning. In the presence of a suitable weight ratio (1:4) of PAAm and PNTs, the in-fiber arrangements of PNTs-electrospun fibers will evolve into chain-like arrays and beads-on-string structures by the confine of PAAm nanofibers, and then the free amide groups of PAAm can bind amide moieties on the surfaces of PNTs, resulting in the assembling of PNTs in the cores of PAAm fibers. The present work serves as references in the fabrication of novel thermo-responsive composite fibers involving functional nanospheres via electrospun packing. The prepared nanofibers with chain-like and thermo-responsive colloid arrays in the cores are expected to have potential application in various fields.

KEYWORDS: Polyacrylamide, colloidal spheres, colloid electrospinning, structural evolution, thermo-sensitive nanofibers

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INTRODUCTION One-dimensional (1D) nanostructures1-2 in the form of nanofibers3-4, nanowires5, nanotubes6, nanorods7, and nanobelts8 have been attracting significant attention lately due to their distinctive geometries, intriguing physical/chemical properties, and fascinating potential applications in topical drug or gene delivery9-11, nanodevices12, photonics13, chemical and biological sensors14-16, and catalytic supports17-18. Many approaches were explored to fabricate one-dimensional nanostructures such as hydrothermal process19, template-directed method20, vapor-liquid-solid (VLS) growth21, solvothermal synthesis22, chemical vapor deposition (CVD)23, and self-assembly24. Within these materials, one-dimensional chain-like core-shell nanofibers compose an important class. Up to now, much effort has been devoted to the

synthesis

of

diverse

chain-like

core-shell

nanofibers

such

as

polyacrylnitrile/TiO225, poly(vinyl alcohol)/SiO226, poly(vinyl alcohol)/polystyrene (PS) colloidal spheres27, and polyacrylamide (PAAm)/SiO228. Above all, chain-like core-shell nanofibers wrapped zero-dimensional colloidal arrays in the core have attracted a great deal of interest due to their challenging properties, such as large specific surface area, controlled release, and stimuli-responsivity. Among the various one-dimensional chain-like core-shell nanofibers production techniques, colloid electrospinning29 has been investigated most extensively due to its high stable and continuous process under mild conditions as well as the flexibility in regulating diameter and morphology of the fibers. On the other hand, coaxial electrospinning30-31 is proposed as one-step process to fabricate core-shell nanofibers,

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which needs higher complexity for electrospinning devices. However, single-nozzle colloid electrospinning is more versatile than coaxial electrospinning, because easy scale-up and a simple process are essential requirements for continuous production on a massive scale. Recently, several groups26,

28, 32-35

have reported attempts of electrospinning

colloidal spheres and polymer solution. In their studies, nanofibers were fabricated from a mixture of colloidal spheres and polymers solution via colloid electrospinning. Subsequently, new functional fibers such as water-stable fibers35, necklace-like fibers26, nanofibers containing colloidal arrays for programmable multi-agent delivery33, and colloidal fibers of structural color34 have been produced by the combination of the colloidal spheres and polymers via colloid electrospinning. However, the colloidal spheres applied in published papers were rigid inorganic or lyophobic high polymer colloidal particles (such as SiO2 latex particles or PS spheres) and didn’t show thermo-responsivity in nanofibers. The soft and stimuli-responsive colloidal spheres36 provided us with a simple and efficient way to produce one-dimension thermo-responsive nanofibers by colloid electrospinning, while enhancing the performances of electrospun hybrid fibers and expand their applications. The combination of polymers and thermo-responsive colloidal spheres, the corresponding structural evolution of the electrospun hybrid fibers and the force analysis of soft polymer spheres in high voltage filed were scarcely reported. Herein, we systematically investigated the interesting chain-like core-shell structure of PAAm with thermo-responsive PNTs via colloid electrospinning. The

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core was composed of thermo-responsive colloidal nanospheres, in which chemical crosslinking structures were synthesized by aqueous free radical precipitation polymerization37-38. The effects of the PAAm: PNTs-1 mass ratio, the applied electric field, and the different colloidal spheres on 1D packing morphology and stability of spheres were investigated. The forming mechanism of electrospun PAAm/PNTs fibrous structures and structural evolution were proposed accordingly. EXPERIMENTAL SECTION Chemicals and Materials. All chemicals are of analytical grade and used as purchased without further purification. Acrylamide (AM, 99%) and Rhodamine B (99%) were purchased from Tianjin Guangfu Fine Chemical Research Institute. N-isopropylacrylamide (NIPAm, 98%) was purchased from Tokyo Chemical Industry Co. Ltd. Tert-Butyl acrylate (tBA, 99%) was purchased from Aladdin Reagent (Shanghai) Co. Ltd. N, N '-methylenebisacrylamide (MBA, 98%) and ammonium persulfate (APS, 98%) were from Tianjin Kemi’ou Chemical Reagent Co. Ltd. N,N,N',N'-tetramethylethylenediamine (TEMED, 98%) was purchased from East China Normal University Chemical Factory. Ethanol (99%) was obtained from Tianjin Fengchuan Chemical Reagent Technologies Co. Ltd. Deionized (DI) water was used in all experiments. Preparation

of

Monodispersed

PNTs

Composite

Nanospheres.

Monodispersed latex nanospheres of poly(N-isopropylacrylamide-N,N’-methylene bisacrylamide-tert-Butyl acrylate) (Poly(NIPAm-co-tBA), PNTs) were prepared by aqueous free radical precipitation polymerization. Refer to Supporting Information,

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Table S1, for monomer feed ratios for colloidal spheres PNTs 0-2. Briefly, NIPAm (12.4 mmol), MBA (0.7 mmol), tBA (1.6 mmol), and DI water (140 mL) were added sequentially to a three-necked flask equipped with a reflux condenser, an N2 inlet and a mechanical stirrer at a stirring speed of 200 rpm. The reaction mixture was initially performed at 70 oC for at least 15 min under a nitrogen atmosphere. The synthesis was carried out at 70 oC for 6 h under continuous stirring, following the rapidly addition of APS (0.45 mmol dissolved in 10 ml DI water). The amount of tBA determined the size and the volume phase transition temperature (VPTT) of the nanospheres, while all other parameters were kept constant. The prepared latex spheres were purified two times by high-speed centrifugation and redispersed in DI water by ultrasonication. Synthesis of PAAm and Determination of Molecular Weight. A solution of AM (3.38×10-2 mol), APS (8.76×10-5 mol) and TEMED (20 μL) in 20 mL mixture of DI water and ethanol (3:2 v/v) was heated to 40 oC, polymerization was carried out at 40 oC for 12 h with vigorous stirring. Polymerization was stopped by cooling the reaction mixture to 25 oC, and the resulting transparent polymer solution was dialyzed against DI water for 24 h in order to remove the residual monomers. The number average molecular weight (Mn), weight average molecular weight (Mw), and polydispersity index (Mw/Mn) were determined to be 1.17 ×105 g/mol, 1.46 ×105 g/mol and 1.24, respectively, by means of gel-permeation chromatography (Viscotek 270 Max, Malvern Instruments Ltd., America) analysis under the conditions (solvent: water and 0.1M NaNO3, calibration standards: commercial polyether polyol, and column set: CLM3017).

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Electrospinning of PAAm/PNTs Electrospun Precursor Solutions. As shown in Figure 1, the electrospun precursor solution was prepared by blending 1 mL PNTs colloidal latex with high concentration of 40 wt% and a measured amount of PAAm solution with 16 wt% concentration. The weight ratio of PAAm to PNTs was variable (4:1, 3:2, 1:1, 2:3 and 1:4, respectively), when the weight ratio of PAAm and PNTs-1 was 1:4, the weight fraction of PAAm in the total weight of solution was 6.15 wt% (M/V), and the weight fraction of PNTs-1 in the total weight was 24.6 wt% (M/V). And the mixture was ultrasonically treated for at least 5 min and then stirred vigorously for 30 min to obtain a homogeneous solution. The resulting solution was transferred into 10 mL plastic syringe fitted with a metallic needle of blunt-tip and 0.5 mm inner diameter. The syringe was fixed horizontally on the syringe pump and the solution was fed at a constant and controllable rate of 0.5 mL/h by using a syringe pump (LSP02-1B, Baoding Longer Precision Pump Co., Ltd., China). A high voltage of 10 kV was applied between the needle and collector, by using a direct current power supply (DW-P303, Tianjin Dongwen High Voltage Co., China). The white electrospun nanofibers were collected on a grounded rectangular metal collector covered by a piece of aluminum foil, with collecting distance of 15 cm. The complete electrospinning setup was enclosed in a fume hood and the electrospinning was carried out at surrounding environment, the temperature and relative humidity in all electrospinning processes were controlled at 20 oC and 30 ± 5%.

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Figure 1: Schematic illustration of the preparation process of PAAm/PNTs hybrid colloidal nanofibers. Characterization. The morphologies of colloidal nanospheres, electrospun pure PAAm nanofibers and colloidal spheres hybrid nanofibers were observed by a field emission scanning electron microscope (FE-SEM, S-4800, Hitachi Ltd., Japan), which were sputtered with gold film before observation. The mean diameter and polydispersity of nanospheres and electrospun fibers were measured from FE-SEM images using analysis software (Image J 1.4.3p, National Institutes of Health, USA). The mean size and polydispersity of colloidal nanosphers in latex were measured by dynamic light scattering (DLS, Zetasizer Brookhaven, Brookhaven Instruments Ltd., USA) under different temperatures (ranging from 20 oC to 50 oC). Fourier transform infrared (FTIR, Spectrum 100, Perkin Elmer Ltd., USA) spectra were recorded in the range of 500-4000 cm-1. The thermo-responsivity of colloidal nanospheres and PAAm/PNTs-1 fibers was studied by using an ultraviolet-visible spectrophotometer (UV, UV-1901, Purkinje General Instruments Ltd., China), at temperatures ranging from 20 oC to 50 oC. Contact angles were measured on an optical contact angle &

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interface tension meter (SL200KB, Solon Tech Ltd., China). Thermal property analysis of the colloidal ectrospun nanofibers was carried out by using a differential scanning calorimeter (DSC, 204F1 Phoenix, Netzsch Instruments Ltd., Germany) and thermo gravimetric analysis (TGA, STA449F3, Netzsch Instruments Ltd., Germany). The viscosity of the spinning solution was measured by a rheometer (HAAKE Rheo Stress 6000, Thermo Scientific Inc. Germany). The water-soluble fluorescent dyes (Rhodamine B) were embedded in PNTs colloids so that the distribution of colloidal spheres confined into PAAm fibers can be optically monitored by confocal laser scanning microscopy(CLSM, ECS SP8,Leica Microsystems Ltd., Germany). The surface morphology and roughness of PAAm/PNTs-1 hybrid fibers were observed by atomic force microscope (AFM, CSPM5500, Bing Nano-instruments Ltd., China) and true color confocal microscope (TCCM, CSM 700, Zeiss Ltd., Germany). RESULTS AND DISCUSSION The morphologies of colloidal spheres under dry condition are shown in Figures 2a-c. It can be seen clearly that the colloidal spheres with smooth surface were spherical in shape. Particle size distributions of PNTs-1, measured by the statistics of the FE-SEM images through Image J 1.4.3p and Origin Pro 8.5, were exceptionally uniform (Supporting Information, Figure S1). According to previous research39, massive hydrophobic ester groups were copolymerized in the structure of PNTs colloidal spheres. To verify the above results, the colloidal spheres were analyzed using FTIR spectra as shown in Figure 2d. In addition to the representative bands of the PNTs-0, the PNTs-1 and PNTs-2 colloidal spheres have the characteristic

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bands of ester carbonyl (C=O) and (C-O-C) at 1727.0 and 1146.5 cm-1, which certified the existence of ester group in the structure of the PNTs-1and PNTs-2 colloidal spheres. Large amounts of hydrophobic ester groups anchored in the structure of colloidal spheres, contributing to the decrease of VPTT of spheres compared to the pure PNTs-0 colloidal spheres. On the other hand, massive amide groups on the surface of colloidal spheres led to the formation of hydrogen bonds between spheres and PAAm during the subsequent mixture and electrospinning process. The PNTs-2 latex dispersions (10 wt%) appeared structural color after coated to the surface of black polyethylene plastic as shown in Figure 2e.The structural color was caused by a highly ordered and periodic structure of PNTs-2 aggregates, which was attributed to the photonic band gap effect40-41 and Mie scattering42. The PNTs-2 became into white dry powder when the latex was completely dried (Figure 2f). Interestingly, the PNTs-2 appeared different color again after wetted by the water.

Figure 2: (a-c) Typical FE-SEM images of PNTs series latex colloidal spheres. (d) FTIR spectra of PNTs series colloidal spheres. (e-g) Optical images of PNTs-2 dispersion in under different humidity conditions. The representative thermo-responsivity analyses of PNTs colloidal spheres at

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the temperature ranging from 20 oC to 50 oC are shown in Figure 3. It was found that ambient temperature can dramatically affect the hydrophilic-hydrophobic property of colloidal spheres, contributing to changes in the transmittance of visible light (500 nm) shown in Figure 3a. When there was no tBA (hydrophobic moieties) in the structure of PNTs-0 colloidal spheres, the most significant changes in visible light transmission aroused. The hydrophobic moieties tBA incorporated in the spheres such as PNTs-1 (molar ratio NIPAm : tBA=7.75 : 1) and PNTs-2 (molar ratio NIPAm : tBA=7.75 : 2), which had the weaker light transmission. When the molar ratio of tBA and NIPAm increased, the thermo-responsive properties of colloidal spheres faded away gradually that was due to out of balance of hydrophobic isopropyl and tert-butyl moieties and hydrophilic amide groups. The hydrodynamic diameters (DH) of colloidal spheres decreased with increasing ambient temperature as shown in Figure 3c. It can be observed that the decrease in DH values of PNTs-0 and PNTs-1 colloidal spheres was evident, the VPTT of PNTs-0 and PNTs-1 spheres were around 32 oC37, 43 and 30 oC, respectively. However, there was no evident change in the DH value of PNTs-2 spheres. While under the effect of hydrophobic tBA moieties, the DH value of spheres decreased, and thermo-responsive properties of colloidal spheres faded away gradually with increasing the molar ratio of tBA and NIPAm, which was same with the Figure 3a results.

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Figure 3: (a) Visible light transmission spectra at various temperatures of the latex spheres (the wavelength was 500 nm). (b) Optical images of PNTs-1 latex at different temperatures. (c) Hydrate particle size distributions of colloidal spheres at different temperatures analyzed by DLS (the wavelength was 660 nm and temperature ranging from 25 oC to 50 oC). (d) The normal distribution curves of colloidal spheres hydrodynamic diameters at 25 oC. Initially, three types colloidal spheres of a low concentration (0.2 wt%) were used to mix constant amount of the PAAm aqueous solution (8 wt%) to prepare the blend solution for electrospinning. The spindle-like structures appeared due to the change of spinning solution viscosity in the presence of minor latex colloidal spheres (see the Supporting Information Figure S2). Subsequently, PNTs-1 spheres were used

to

massively

produce

one-dimensional

colloidal

fibers

via

colloid

electrospinning process in order to investigate the characteristic of structural evolution. Colloid electrospinning is one of the electrospinning methods but significantly differs from the conventional electrospinning27, as it incorporates organic/inorganic colloidal particles into the spinning solution44-45. Figure 4 shows the structural evolution of the electrospun fibers that appear

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when the PAAm: PNTs-1 mass ratio is changed from 4:1 to 1:4, with a suitable concentration of PAAm solution (16 wt%) and same process conditions (voltage:15 kV, distance:15 cm, feed rate: 0.5 mL/h, relative humidity: 25%, temperature: 22 oC). The FE-SEM image in Figure 4a (PAAm: PNTs-1=4:1) indicates that PNTs-1 formed aggregates embedded in the PAAm fibers. In the fibers, PAAm was dominant in the mixture and the diameters of aggregate and fiber were 8.56 μm and 0.60 μm, respectively. When the amount of PNTs-1 in the mixture increased to 3:2 PAAm: PNTs-1, PNTs-1 formed into smaller aggregates packed by a layer of PAAm in Figure 4b. It can be seen in Figure 4c that a pile of PNTs-1 were bound and packed by PAAm, while the small aggregates transformed into beads-on-string structures, with a 1:1 PAAm: PNTs-1 weight ratio of the blend solution. With the further increase of PNTs-1 to obtain a mass ratio of 2:3, the emergence of smaller PNTs-1 aggregates and thicker PAAm fibers were observed, as shown in Figure 4d. To evaluate the influence of the mass ratio of PAAm and PNTs-1 on mean diameters of fibers and aggregates, the correlation curves were presented in Figures 4g-h, and the statistical information was shown in Supporting Information Table S2. When the mass ratio was 1:4 PAAm: PNTs-1, on the basis of wrapped PNTs-1, the chain-like arrays of zero dimensional colloidal spheres in the cores of PAAm fibers were obtained by electrospinning, as shown in Figure 4e-f. In such conditions, PAAm acted as the binder layer to pack PNTs-1 into the cores of fibers, and there were obvious adhesions between PNTs-1 colloidal spheres. The distinction between Figure 4, panels a and f indicates that the amount of PNTs-1 relative to PAAm is the key parameter for

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fabrication of chain-like arrays or beads-on-string structures. According to Yuan et al27, the PVA fibers confined the PS spheres into necklace-like structures, and the best necklace-like structures were obtained only when the weight ratio of PVA (11 wt%) and PS (473 nm) was 1:2. While the laws we got were different from the published paper. On the other hand, the PNTs-1 colloids were lyophilic and soft colloidal spheres, adjacent spheres tend to adhere to each other due to the confine of PAAm and the hydrogen bonding between lyophilic spheres and PAAm fibers. And the soft spheres had been deformed by axial pulling force during the spinning flight (Figure 4f). However, the lyophobic and rigid PS colloids were unable to experience the above mentioned interactions and deformation.

Figure 4: FE-SEM images of electrospun PAAm (16 wt%)/PNTs-1 (266 nm) fibers with different PAAm:PNTs-1 mass ratio. (a) 4:1, (b) 3:2, (c) 1:1, (d) 2:3, (e) and (f) 1:4. The (f) image was taken under higher magnification. (g, h) The curve of PAAm

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fibers and PNTs-1 aggregates mean diameters with the change of mass ratio of PAAm and PNTs-1, respectively. To evaluate the influence of voltages on the fibers and PNTs-1, three different voltages were applied. As shown in Supporting Information, Figure S3a, colloidal spheres aggregates (red circle marked), smaller aggregates (red arrow marked) and chain-like (red rectangle marked) structures were fabricated when 16 wt% PAAm solution was used and the voltage was 10 kV. PNTs-1 with a diameter of 266 nm (under dry condition) aligned along most fibers, with obvious distance between two neighboring PNTs-1. When the external electric field was increased, PNTs-1 tended to aggregate and the chain-like arrays tended to reduce, as shown in Figure S3b. PNTs-1 formed clusters of aggregates when the voltage was 20 kV (Figure S3c). Meanwhile, the chain-like arrays or beads-on-string structures almost disappeared. In previous research46, it has been indicated that when the external voltage is increased, the flight speed of polymer jet is improved and the jet whipping is more vigorous at the same time. Therefore, PNTs-1 suspended in PAAm solution tended to aggregates instead of chain-like arrays along the fibers under faster flight speed. The smooth colloidal fibers were electrospun from a blend solution of latex spheres and PAAm solution, PAAm served to adhere and capsulate spheres. During the electrospinning process, the wrapped spheres were packed and notably deformed and thinned into the fibers, and their functionality remained in the final materials. To further explore the surface morphologies and roughness of PAAm and PAAm/PNTs-1 (1:4) hybrid fibrous mat, TCCM and AFM were performed on the final electrospun fibrous mats as shown in Figure 5 and 6, respectively. The typical

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three dimensional surface morphologies of PAAm/PNTs-1 fibrous mat (Figure 5d) was rougher than PAAm fibrous mat (Figure 5b), which mainly due to the aggregates produced by accumulation of PNTs-1 in the cores of PAAm fibers.

Figure 5: The TCCM images of electrospun fibrous mats. (a) PAAm fibrous mat, two-dimension optical image, (b) PAAm fibrous mat, three-dimension scanning image, (c) PAAm/PNTs-1 fibrous mat, two-dimension optical image, (d) PAAm/PNTs-1 fibrous mat, three-dimension scanning image.

Figure 6: The AFM images of electrospun fibers. (a) PAAm fibers, two-dimension scanning image, (b) PAAm fibers, three-dimension scanning image, (c) PAAm/PNTs-1 fibers, two-dimension scanning image, (d) PAAm/PNTs-1 fibers, three-dimension scanning image.

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The Figure 6 shows a comparison of the PAAm fibers and PAAm/PNTs-1 hybrid fibers, the PAAm nanofibers prepared using electrospinning had a mean diameter of 650 nm, exhibiting smooth surface as shown the areas marked with black arrows of Figure 6a and b. The PAAm/PNTs-1 hybrid nanofibers exhibited wrinkled surface morphologies, and it was clearly that the PNTs-1 colloidal spheres were sequentially packed in chain-like arrays, as shown the areas marked with black rectangle in Figure 6c and d. The investigation of the array of polymeric colloidal spheres encapsulated in electrospun fibers can be however challenging due to the contrast between polymeric colloidal spheres and polymer fibers is usually low in transmission electron microscopy. Confocal laser scanning microscopy is an appealing tool to circumvent the problem of low contrast between polymer phases. Since PNTs-1 colloids are stimuli-responsive polymeric colloidal spheres and demonstrate pronounced thermo-responsive properties and show VPTT around T=30 oC in pure water (see Figure 3c), the colloidal spheres can be swollen and deswollen at the temperatures below and above the VPTT. Water-soluble fluorescent dye rhodamine B can be readily incorporated in PNTs-1 colloidal spheres by employing the swelling and deswelling characteristic in water on heating33 (see Figure 7a). And PNTs-1 spheres that internally contained Rhodamine B were dialyzed in distilled water for 48h, until Rhodamine B was not detected in the dialysate. Figure 7b and c show typical confocal laser scanning microscopy (CLSM) images of chain-like fibers consisting of an array of colloidal spheres core and PAAm sheath. The red dots of arrangement in

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partially order indicate that the zero dimensional PNTs-1 colloidal spheres lined up to form an array and chain-like structure in the central region of the fibers. The blue lines added to represent the PAAm fibers, which connected PNTs-1 colloidal spheres together to form the necklace-like structures, as shown in Figure 7b. The diameter of isolated colloidal sphere was around 600 nm in the 400 nm thick fibers, which indicates that the colloidal spheres were evenly distributed and confined into PAAm nanofibers during the jet whipping and thinning process.

Figure 7: (a) Schematic illustration of incorporating rhodamine B in Poly(NIPAm-co-tBA) colloidal spheres (PNTs) by employing the swelling and deswelling characteristic in water on heating. (b,c) CLSM images of the PAAm-based

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fibers containing PNTs-1 colloidal spheres arrays in the core. (b) Rhodamine B was incorporated in the PNTs-1 colloidal fibers and two-dimensional scanning image. (c) The side view image with three-dimensional scanning. To further investigate if the PNTs-1 colloidal spheres are stained in the hybrid fibers, a morphology comparison of wetted PAAm and PAAm/PNTs-1 (1:4) fibrous mats is shown in Figure 8, and blue dotted lines (Figure 8a&c) display the edges of water to soak. The clear structure of wetted PAAm fibers, shown in Figure 8b, demonstrates that the PAAm fibers were partially dissolved, and the overlapping of PAAm fibers (marked with red ellipse) collapsed and hardened. It should be noted that there are not many evident fibers in Figure 8c, because most of the fibrous structures were dissolved by water, and the upper right part of the blue dotted line shows many aggregates of spheres. Corresponding higher magnification FE-SEM image is shown in Figure 8d, and it should be noted that there are some residual necklace-like structures (marked with red rectangle), PNTs-1 colloidal spheres that were insoluble in water converged together to form aggregates (marked with red circle) due to the hydrogen bonding between spheres and the surface tension of water, when PAAm fibers were dissolved. Here, PAAm fibers acted as the confining template for the colloidal spheres. Compared to 1D continuous nanowires47-48 and 1D tubular nanostructures49-50, confining colloidal spheres into PAAm nanofibers to obtain 1D colloidal chain-like structures was a relatively straightforward process.

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Figure 8: (a,b) FE-SEM images of wetted electrospun PAAm fibrous mat. (c,d) FE-SEM images of wetted electrospun PAAm/PNTs-1 (1:4) fibrous mat. Based on the results mentioned above, the deformation mechanism of the chain-like arrays and colloidal spheres, as shown in Figure 9, is summarized in this section. In general, only if the viscosity of polymer solution is optimal a continuous jet from the Taylor Cone adjacent to the needle tip is generated. Once PAAm dominated the blend spinning solution, small amounts of PNTs-1 aggregated and were wrapped in the viscous polymer solution then confined into PAAm fibers during the jet whipping and thinning process (Figure 9a, case Ⅰ ). Meanwhile, the blackberry-like and ideal necklace-like structures were simultaneously prepared by colloid electrospinning, when PNTs-1 occupied a large portion of the solution (PAAm: PNTs-1=1:4), as shown in Figure 9b. The PNTs-1 aggregate marked with a red circle

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was called blackberry-like structure, and blackberry-like structure evolved into the near necklace-like structure (marked with red arrows) during the spinning flight, as described in the situationⅠ. PNTs-1 aggregates deformed by sliding the soft and wet spheres along the axis of the jet to the lowest energy state. The PAAm thick layer acted as the confining template for the PNTs-1 under such conditions. It can be seen from Figure 9a Ⅱ, case Ⅱ that the PNTs-1 spheres were more feasible in the formation of necklace-like arrays under the confinement of PAAm layers. The beads-on-string marked with a red rectangle was called necklace-like structure as shown in Figure 9b, PNTs-1 colloidal spheres encapsulated in the cores of PAAm fibers evolved into ellipsoids during the spinning flight. The PNTs-1 colloidal spheres consist of elastic crosslinked networks and fluid filling the interstitial spaces of the networks. Therefore, PNTs-1 colloidal spheres are wet and soft and capable of undergoing large deformation, as reported in the references37,

51

. Here, PNTs-1

underwent deformation from sphere to ellipsoid or spindle under the interactions of four kinds of external force in the process of high-speed flight (Figure 9a case Ⅲ). Therefore, the chain-like arrays along the PAAm nanofibers were fabricated.

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Figure 9: (a) Schematic representation of the deformation mechanism of diverse hybrid nanofibers under different conditions via colloid electrospinning. (b) FE-SEM image of PAAm/PNTs-1 fibers via colloid electrospinning. (c) The normal distribution curves of fibers, spheres and aggregates of PAAm/PNTs-1 (1:4) fibers from (b). To study the thermal behavior of PAAm/PNTs-1 nanofibers, TGA was performed on the obtained electrospun fibrous mat as shown in Supporting Information, Figure S4. The onset mass loss of as-electrospun PAAm observed in this temperature range (from 50 oC to 180 oC) on the TGA curve was consistent with the volatilization of water, and the characteristic thermal gravimetric of pure PAAm fibers possessed three different stages in the upper 200

o

C as reported in

literatures52-53. And the incorporation of PNTs-1 colloidal spheres decreased the initial decomposition temperature of the last stage, which was due to the fracture of ester bond in PNTs-1 molecular structure. The grass transition temperature (Tg) of pure PAAm fibers was 182.0 oC (see the Supporting Information, Figure S5). The PAAm/PNTs fibers appeared two different Tg values, which indicated that PAAm and

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PNTs were not compatible completely.

Figure 10: (a) DSC curves of PAAm and PAAm/PNTs-1 fibrous mats in wet condition. (b) Schematic representation of macromolecule and hydrogen bonding between water and macromolecule. (c) UV absorption spectra of three samples of different compositions. (d) The intensity of UV absorption peak at various temperatures of three samples (the wavelength was 198 nm). Figure 10a shows the enthalpy change of PNTs-1 wrapped by PAAm nanofibers in the chain-like arrays. Corresponding endothermic and exothermic peaks were measured by differential scanning calorimeter. A broad exothermic peak was found when the temperature was about 23 oC to 31 oC, the hydrogen bonding between the carbonyl group of PAAm and water would form simultaneously in this temperature range54. The VPTT of PNTs-1 colloidal spheres was about 30 oC as the above results (Figure 3), and the exothermic peak would move to higher temperature (above 30 oC) due to the rupture of hydrogen bonding between carbonyl and amino of PNTs-1 with water, in the meanwhile, the hydrogen bonding between water and

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carbonyl of PAAm formed as shown in Figure 10b. A remarkable endothermic peak was found about 26 oC, the hydrogen bounding interaction between PNTs-1 and PAAm would dissociate near this temperature. In order to demonstrate the thermo-responsivity of PAAm/PNTs-1 fibers more scientifically and neatly, the UV absorption spectra at different wavelengths (190-600 nm) were tested, as shown in Figure 10c. It was found that the absorption intensity of three samples at 198 nm was the largest, where peaks assigned to amide group55. And it can be seen from Figure 10d that the UV absorption (198 nm) intensity of PAAm/PNTs-1 fibers was related to the temperature, which was same as thermo-responsive PNTs-1 colloidal spheres. According to Chen et al56, to discern if PAAm/PNTs-1 hybrid fibers are thermo-responsive, the water contact angle (CA) measurements were performed (see the Supporting Information, Figure S6). The PAAm fibers showed super hydrophilicity at different temperatures, while the wettability of PAAm/PNTs-1 fibers displayed evident changes from good (CA=35.67o) to poor (CA=50.27o) with the temperature changes from 25 oC to 50 oC. And they indicated that the PNTs-1 colloidal spheres wrapped in cores of PAAm fibers still show thermo-responsivity. The use of thermo-responsive spheres to obtain smart nanofibers is effective for a wide variety of stimuli responsive materials combinations. It should be emphasized that, the programmable topical drug delivery applications of the prepared thermo-responsive nanofibrous mats will be investigated further. CONCLUSIONS In conclusion, it is demonstrated that a one-step production of 1D chain-like

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nanofibers may be obtained from PAAm and PNTs colloidal spheres. Tunable structures of electrospun colloidal fibers were obtained from a blended solution of PAAm and PNTs colloidal spheres. It was found that the PAAm fibers acted as a template to confine PNTs-1 into chain-like nanofibers, and PNTs-1 were not easy to disperse and were wrapped by PAAm solution in a PAAm-dominant blend solution (the weight ratio of PAAm and PNTs-1: 4/1, 3/2). In contrast, PNTs-1 spheres were packed by PAAm solution to form core-shell and chain-like structures in a PNTs-1-dominant blend solution (the weight ratio of PAAm and PNTs-1: 1:4). In such conditions, PAAm acted as the adhesive agent to adhere PNTs-1 to form several different structures, such as blackberry-like aggregates, beads-on-string and chain-like arrays. The structural evolution of electrospun hybrid colloidal fibers was mainly affected by the weight ratio of PAAm and PNTs-1 and the external electric field applied. The thermo-responsive PNTs colloidal spheres were successfully encapsulated for the first time into the cores of PAAm nanofibers in chain-like arrays by colloid electrospinning. The distribution and arrangement of PNTs-1 spheres as small as ~200 nm embedded in PAAm nanofibers can be clearly observed via fluorescent tracking. It is worthy to note that (i) the VPTT of PNTs spheres can be turned by adjusting the molar ratio of hydrophobic tBA and thermo-responsive NIPAm and its composition and (ii) not only the morphologies of the PAAm/PNTs mat but also the hybrid fiber diameter can be controlled accurately by colloid electrospinning conditions. Additionally, the study will open up a new approach to prepare thermo-responsive

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nanofibers or fibrous mats, and these chain-like arrays contained thermo-responsive colloidal spheres present valuable potential applications such as in drug delivery systems or smart surfaces. ASSOCIATED CONTENT Supporting Information: The Supporting Information is available free of charge via the internet at http://pubs.acs.org. PNTs colloidal spheres preparation recipes, and the hydrophobic tBA was used to adjust the VPTT of colloidal spheres (Table S1); the statistical information for the diameters of PAAm fibers and PNTs-1 aggregates were measured by Image J 1.4.3p under different weight fraction of PAAm and PNTs-1 (Table S2); normal distribution histogram showing the particle size distribution of PNTs-1 in dry condition (Figure S1); morphologies, structural evolution and spindle-like fibers of PAAm/PNTs hybrid nanofibrous mats with various PNTs colloidal spheres (Figure S2); FE-SEM images of the PAAm/PNTs-1 nanofibers with various external voltages: 10 kV, 15 kV and 20 kV (Figure S3); thermogravimetric analysis of PAAm nanofibrous mats and PAAm/PNTs-1 hybrid mats, conducted from 50 to 800 oC in air (Figure S4); typical DSC results of electrospun fibers, conducted from 30 to 250 oC (Figure S5); water contact angles of electrospun fibers, conducted at 25 and 50 oC, respectively (Figure S6) (PDF) Corresponding Author *E-mail: [email protected], [email protected] ACKNOWLEDGMENTS: We gratefully acknowledge the financial support from the

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National Natural Science Foundation of China (21104058, 31200719, 21134004 & 21174103), the State Scholarship Fund of China Scholarship Council (201508120037), Applied Basic Research and Advanced Technology Programs of Science and Technology

Commission

15JCYBJC18300),

Science

Foundation and

of

Tianjin

technology

(12JCQNJC01400

correspondent

of

&

Tianjin

(14JCTPJC00502 & 15JCPJC62200), and National Training Programs of Innovation and Entrepreneurship for Undergraduates (201510058005 & 201510058051). REFERENCES 1.

Lu, X. F.; Wang, C.; Wei, Y. One-Dimensional Composite Nanomaterials: Synthesis by

Electrospinning and Their Applications. Small 2009, 5, 2349-2370. 2.

Zhang, C. L.; Yu, S. H. Nanoparticles Meet Electrospinning: Recent Advances and Future

Prospects. Chem. Soc. Rev. 2014, 43, 4423-4448. 3.

Li, D.; Xia, Y. N. Electrospinning of Nanofibers: Reinventing the Wheel? Adv. Mater. 2004, 16,

1151-1170. 4.

Agarwal, S.; Greiner, A.; Wendorff, J. H. Functional Materials by Electrospinning of Polymers.

Prog. Polym. Sci. 2013, 38, 963-991. 5.

Liu, J. W.; Liang, H. W.; Yu, S. H. Macroscopic-Scale Assembled Nanowire Thin Films and Their

Functionalities. Chem. Rev. 2012, 112, 4770-4799. 6.

Yang, W. X.; Liu, X. J.; Yue, X. Y.; Jia, J. B.; Guo, S. J. Bamboo-like Carbon Nanotube/Fe3C

Nanoparticle Hybrids and Their Highly Efficient Catalysis for Oxygen Reduction. J. Am. Chem. Soc. 2015, 137, 1436-1439. 7.

Cai, Z. Y.; Xu, L.; Yan, M. Y.; Han, C. H.; He, L.; Hercule, K. M.; Niu, C. J.; Yuan, Z. F.; Xu, W.

W.; Qu, L. B.; Zhao, K. N.; Mai, L. Q. Manganese Oxide/Carbon Yolk-Shell Nanorod Anodes for High Capacity Lithium Batteries. Nano lett. 2015, 15, 738-744. 8.

Wang, Z. L. ZnO Nanowire and Nanobelt Platform for Nanotechnology. Mat. Sci. Eng. R 2009, 64,

33-71. 9.

Yu, D. G.; Li, X. Y.; Wang, X.; Yang, J. H.; Annie Bligh, S. W.; Williams, G. R. Nanofibers

Fabricated Using Triaxial Electrospinning as Zero Order Drug Delivery Systems. ACS Appl. Mater. Interfaces 2015, 7, 18891-18897. 10. Salem, A. K.; Searson, P. C.; Leong, K. W. Multifunctional Nanorods for Gene Delivery. Nature Mater. 2003, 2, 668-671. 11. Timko, B. P.; Dvir, T.; Kohane, D. S. Remotely Triggerable Drug Delivery Systems. Adv. Mater. 2010, 22, 4925-4943. 12. Kundu, S.; Gill, R. S.; Saraf, R. F. Electrospinning of PAH Nanofiber and Deposition of Au NPs for Nanodevice Fabrication. J. Phys.Chem. C 2011, 115, 15845-15852. 13. Ma, H.; Tang, K.; Luo, W.; Ma, L.; Cui, Q.; Li, W.; Guan, J. G. Photonic Nanorods with Magnetic

ACS Paragon Plus Environment

Page 29 of 31

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Langmuir

Responsiveness Regulated by Lattice Defects. Nanoscale 2017, 9, 3105-3113. 14. Wang, X. Q.; Li, Y.; Li, X. Q.; Yu, J. Y.; Al-Deyab, S. S.; Ding, B. Equipment-Free Chromatic Determination of Formaldehyde by Utilizing Pararosaniline-Functionalized Cellulose Nanofibrous Membranes. Sensor. Actuat. B-Chem. 2014, 203, 333-339. 15. Rajavel, K.; Lalitha, M.; Radhakrishnan, J. K.; Senthilkumar, L.; Rajendra Kumar, R. T. Multiwalled Carbon Nanotube Oxygen Sensor: Enhanced Oxygen Sensitivity at Room Temperature and Mechanism of Sensing. ACS Appl. Mater. Interfaces 2015, 7, 23857-23865. 16. Jiang, S. H.; Liu, F. Y.; Lerch, A.; Ionov, L.; Agarwal, S. Unusual and Superfast Temperature-Triggered Actuators. Adv. Mater. 2015, 27, 4865-4870. 17. Jiang, C. L.; Nie, J.; Ma, G. P. Polymer/Metal Core–Shell Nanofiber Membrane by Electrospinning with Electric Field and Application for Catalyst Support. RSC Adv. 2016, 6, 22996-23007. 18. Shao, L. J.; Ren, Y.; Wang, Z. N.; Qi, C. Z.; Lin, Y. Developing Chitosan-Based Composite Nanofibers for Supporting Metal Catalysts. Polymer 2015, 75, 168-177. 19. Wang, W.; Ai, T. T.; Yu, Q. Electrical and Photocatalytic Properties of Boron-Doped ZnO Nanostructure Grown on PET-ITO Flexible Substrates by Hydrothermal Method. Sci. Rep. 2017, 7, 42615-42625. 20. Susapto, H. H.; Kudu, O. U.; Garifullin, R.; Yilmaz, E.; Guler, M. O. One-Dimensional Peptide Nanostructure Templated Growth of Iron Phosphate Nanostructures for Lithium-Ion Battery Cathodes. ACS Appl. Mater. Interfaces 2016, 8, 17421-17427. 21. Yang, B.; Yuan, F.; Liu, Q. Y.; Huang, N.; Qiu, J. H.; Staedler, T.; Liu, B. D.; Jiang, X. Dislocation-Induced Nanoparticle Decoration on a GaN Nanowire. ACS Appl. Mater. Interfaces 2015, 7 , 2790-2796. 22. Gou, X. L.; Cheng, F. Y.; Shi, Y. H.; Zhang, L.; Peng, S. J.; Chen, J.; Shen, P. W. Shape-Controlled Synthesis of Ternary Chalcogenide ZnIn2S4 and CuIn(S,Se)2 Nano-/Microstructures via Facile Solution Route. J. Am. Chem. Soc. 2006, 128, 7222-7229. 23. He, C. N.; Zhao, N. Q.; Shi, C. S.; Liu, E. Z.; Li, J. J. Fabrication of Nanocarbon Composites Using In Situ Chemical Vapor Deposition and Their Applications. Adv. Mater. 2015, 27, 5422-5431. 24. Shimizu, T.; Kameta, N.; Ding, W. X.; Masuda, M. Supramolecular Self-Assembly into Biofunctional Soft Nanotubes: From Bilayers to Monolayers. Langmuir 2016, 32, 12242-12264. 25. Choi, S. K.; Kim, S.; Lim, S. K.; Park, H. Photocatalytic Comparison of TiO2 Nanoparticles and Electrospun TiO2 Nanofibers: Effects of Mesoporosity and Interparticle Charge Transfer. J. Phys. Chem. C. 2010, 114, 16475-16480. 26. Jin, Y.; Yang, D. Y.; Kang, D. Y.; Jiang, X. Y. Fabrication of Necklace-like Structures via Electrospinning. Langmuir 2010, 26, 1186-1190. 27. Yuan, W.; Zhang, K. Q. Structural Evolution of Electrospun Composite Fibers from the Blend of Polyvinyl Alcohol and Polymer Nanoparticles. Langmuir 2012, 28, 15418-15424. 28. Lim, J. M.; Moon, J. H.; Yi, G. R.; Heo, C. J.; Yang, S. M. Fabrication of One-Dimensional Colloidal Assemblies from Electrospun Nanofibers. Langmuir 2006, 22, 3445-3449. 29. Crespy,

D.;

Friedemann,

K.;

Popa,

A.

M.

Colloid-Electrospinning:

Fabrication

of

Multicompartment Nanofibers by the Electrospinning of Organic or/and Inorganic Dispersions and Emulsions. Macromol. Rapid Commun. 2012, 33, 1978-1995. 30. Li, D.; McCann, J. T.; Xia, Y. N. Use of Electrospinning to Directly Fabricate Hollow Nanofibers with Functionalized Inner and Outer Surfaces. Small 2005, 1, 83-86.

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Langmuir

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

31. Li, D.; McCann, J. T.; Xia, Y.; Marquez, M. Electrospinning: A Simple and Versatile Technique for Producing Ceramic Nanofibers and Nanotubes. J. Am. Ceram. Soc. 2006, 89, 1861-1869. 32. Friedemann, K.; Turshatov, A.; Landfester, K.; Crespy, D. Characterization via Two-Color STED Microscopy of Nanostructured Materials Synthesized by Colloid Electrospinning. Langmuir 2011, 27, 7132-7139. 33. Jo, E.; Lee, S.; Kim, K. T.; Won, Y. S.; Kim, H. S.; Cho, E. C.; Jeong, U. Core-Sheath Nanofibers Containing Colloidal Arrays in the Core for Programmable Multi-Agent Delivery. Adv. Mater. 2009, 21, 968-972. 34. Yuan, W.; Zhou, N.; Shi, L.; Zhang, K. Q. Structural Coloration of Colloidal Fiber by Photonic Band Gap and Resonant Mie Scattering. ACS Appl. Mater. Interfaces 2015, 7, 14064-14071. 35. Stoiljkovic, A.; Ishaque, M.; Justus, U.; Hamel, L.; Klimov, E.; Heckmann, W.; Eckhardt, B.; Wendorff, J. H.; Greiner, A. Preparation of Water-Stable Submicron Fibers from Aqueous Latex Dispersion of Water-Insoluble Polymers by Electrospinning. Polymer 2007, 48, 3974-3981.

36. Jiang, S.; Lv, L. P.; Li, Q. F.; Wang, J. W.; Landfester, K.; Cresy, D. Tailoring Nanoarchitectonics to Control the Release Profile of Payloads. Nanoscale 2016, 8, 11511-11517. 37. Clarke, K. C.; Dunham, S. N.; Lyon, L. A. Core/Shell Microgels Decouple the pH and Temperature Responsivities of Microgel Films. Chem. Mater. 2015, 27, 1391-1396. 38. Zhang, Q. S.; Zha, L. S.; Ma, J. H.; Liang, B. R. Synthesis and Characterization of Novel, Temperature-Sensitive Microgels Based on N-isopropylacrylamide and tert-Butyl Acrylate. J. Appl. Polym. Sci. 2007, 103, 2962-2967. 39. Parker, A. R.; McPhedran, R. C.; McKenzie, D. R.; Botten, L. C.; Nicorovici, N. A. P. Photonic Engineering Aphrodite,s Iridescence. Nature 2001, 409, 36-37. 40. Zhang, J. T.; Wang, L. L.; Luo, J.; Tikhonov, A.; Kornienko, N.; Asher, S. A. 2-D Array Photonic Crystal Sensing Motif. J. Am. Chem. Soc. 2011, 133, 9152-9155. 41. Dong, B. Q.; Liu, X. H.; Zhan, T. R.; Jiang, L. P.; Yin, H. W.; Liu, F.; Zi, J. Structural Coloration and Photonic Pseudogap in Natural Random Close-Packing Photonic Structures. Opt. Express 2010, 18, 14430-14438. 42. Fujishige, S. Phase Transition of Aqueous Solutions of Poly(N-isopropylacrylamide) and Poly(N-isoprop ylmethacrylamide). J. Phys. Chem. 1989, 93, 3311-3313. 43. Yang, D. Y.; Lu, B.; Zhao, Y.; Jiang, X. Y. Fabrication of Aligned Fibrous Arrays by Magnetic Electrospinning. Adv. Mater. 2007, 19, 3702-3706. 44. Wu, S. J.; Li, F. T.; Wang, H. T.; Fu, L.; Zhang, B. R.; Li, G. T. Effects of Poly (vinyl alcohol) (PVA) Content on Preparation of Novel Thiol-Functionalized Mesoporous PVA/SiO2 Composite Nanofiber Membranes and Their Application for Adsorption of Heavy Metal Ions from Aqueous Solution. Polymer 2010, 51, 6203-6211. 45. Fridrikh, S. V.; Yu, J. H.; Brenner, M. P.; Rutledge, G. C. Controlling the Fiber Diameter during Electrospinning. Phys. Rev. Lett. 2003, 90, 144502-144505. 46. Shin, K.; Park, J. S.; Han, J. H.; Choi, Y.; Chung, D. S.; Kim, S. H. Patterned Transparent Electrode with a Continuous Distribution of Silver Nanowires Produced by an Etching-Free Patterning Method. Sci. Rep. 2017, 7, 40087-40096. 47. Liu, G.; Rumyantsev, S.; Bloodgood, M. A.; Salguero, T. T.; Shur, M.; Balandin, A. A. Low-Frequency Electronic Noise in Quasi-1D TaSe3 van der Waals Nanowires. Nano Lett. 2017, 17, 377-383. 48. Yu, L.; Hu, H.; Wu, H. B.; Lou, X. W. Complex Hollow Nanostructures: Synthesis and

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Langmuir

Energy-Related Applications. Adv. Mater. 2017, 29, 1604563-1604601. 49. Maeda, K.; Hong, L.; Nishihara, T.; Nakanishi, Y.; Miyauchi, Y.; Kitaura, R.; Ousaka, N.; Yashima, E.; Ito, H.; Itami, K. Construction of Covalent Organic Nanotubes by Light-Induced Cross-Linking of Diacetylene-Based Helical Polymers. J. Am. Chem. Soc. 2016, 138, 11001-11008. 50. Yuan, Q. P.; Gu, J. J.; Zhao, Y. N.; Yao, L. J.; Guan, Y.; Zhang, Y. J. Synthesis of a Colloidal Molecule from Soft Microgel Spheres. ACS Macro Lett. 2016, 5, 565-568. 51. Lu, P.; Hsieh, Y. L. Organic Compatible Polyacrylamide Hydrogel Fibers. Polymer 2009, 50, 3670-3679. 52. Shaban, M.; Ramazani S. A.; Ahadian, M. M.; Tamsilian, Y.; Weber, A. P. Facile Synthesis of Cauliflower-Like

Hydrophobically

Modified

Polyacrylamide

Nanospheres

by

Aerosol

Photopolymerization. Eur. Polym. J. 2016, 83, 323-336. 53. He, X. R.; Cai, S. W.; Yu, H.; Chen, Q.; Hou, H. L. DSC Differential Spectrum Applied in the Study of Hydrogen Bonding Interaction in Aqueous Solution. Int. J. Polym. Anal. Ch. 2014, 19, 141-150.

55. Qi, H. B.; Li, S. T.; Wang, Q. S.; Wu, G. Z.; Li, D. Optical Property of Concentration Optical Detection of Polyacrylamide Solution. Spectrosc. Spect. Anal. 2017, 37, 1466-1470. 56. Chen, M. L.; Dong, M. D.; Havelund, R.; Regina, V. R.; Meyer, R. L.; Besenbacher, F.; Kingshott, P. Thermo-Responsive Core-Sheath Electrospun Nanofibers from Poly (N-isopropylacrylamide)/Polycaprolactone Blends. Chem. Mater. 2010, 22, 4214-4221.

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