One-step synthesis of amino-functionalized fluorescent carbon nanoparticles by hydrothermal carbonization of chitosan

Yang, Yunhua; Cui, Jianghu; Zheng, Mingtao; Hu, Chaofan; Tan, Shaozao; Xiao, Yong; Qu, Yang; Liu, Yingliang

doi:10.1039/c1cc15678k

Cited by 868 publications

(595 citation statements)

References 42 publications

(16 reference statements)

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“…The pure chitosan raw material shows diffraction peaks at 11.9°, 19.7°a nd 29.1°that can be assigned to (020), (110) and (130), respectively (Zhang et al 2005). The diffraction peaks at 11.9°(020) and 19.7°(110) represent the amorphous and the crystalline regions of chitosan (Yang et al 2012). The regenerated chitosan, showing a strong peak at 10.6°and a minor peak at 20.7°, has a diffraction profile, which is rather different than the raw material.…”

Section: Analysis Of Nanocomposites By Xrdmentioning

confidence: 99%

“…The regenerated chitosan, showing a strong peak at 10.6°and a minor peak at 20.7°, has a diffraction profile, which is rather different than the raw material. This implies a dominant amorphous feature of the regenerated chitosan (Yang et al 2012). If the compatibility between cellulose and chitosan would have been poor in the nanocomposite materials, their diffraction peaks would have been found at the same positions as in the individual, regenerated raw materials.…”

Section: Analysis Of Nanocomposites By Xrdmentioning

confidence: 99%

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Spherical nanocomposite particles prepared from mixed cellulose–chitosan solutions

et al. 2016

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Novel cellulose-chitosan nanocomposite particles with spherical shape were successfully prepared via mixing of aqueous biopolymer solutions in three different ways. Macroparticles with diameters in the millimeter range were produced by dripping cellulose dissolved in cold LiOH/urea into acidic chitosan solutions, inducing instant co-regeneration of the biopolymers. Two types of microspheres, chemically crosslinked and non-crosslinked, were prepared by first mixing cellulose and chitosan solutions obtained from freeze thawing in LiOH/KOH/urea. Thereafter epichlorohydrin was applied as crosslinking agent for one of the samples, followed by water-inoil (W/O) emulsification, heat induced sol-gel transition, solvent exchange, washing and freeze-drying. Characterization by X-ray photoelectron spectroscopy, total elemental analysis, and Fourier transform infrared spectroscopy confirmed the prepared particles as being true cellulose-chitosan nanocomposites with different distribution of chitosan from the surface to the core of the particles depending on the preparation method. Field emission scanning electron microscopy and laser diffraction was performed to study the morphology and size distribution of the prepared particles. The morphology was found to vary due to different preparation routes, revealing a core shell structure for macroparticles prepared by dripping, and homogenous nanoporous structure for the microspheres. The non-crosslinked microparticles exhibited a somewhat denser structure than the crosslinked ones, which indicated that crosslinking restricts packing of the chains before and under regeneration. From the obtained volume-weighted size distributions it was found that the crosslinked microspheres had the highest median diameter. The results demonstrate that not only the mixing ratio and distribution of the two biopolymers, but also the morphology and nanocomposite particle diameters are tunable by choosing between the different routes of preparation.

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Section: Analysis Of Nanocomposites By Xrdmentioning

confidence: 99%

Section: Analysis Of Nanocomposites By Xrdmentioning

confidence: 99%

Spherical nanocomposite particles prepared from mixed cellulose–chitosan solutions

et al. 2016

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“…The bathochromic emission of the CNPs has been extensively reported previously. [14,15,20,28] The emission intensity shows the highest valve of 439 nm and 405 nm for cellulose-CNPs (FWHM, 90 nm) and cyclodextrinCNPs (FWHM, 135 nm), respectively, under the excitation at 360 nm. It is reasonable to assume that the different carbon resources lead to the different excitation energy traps and the different fluorescence properties.…”

Section: Fluorescence Characterization Of Cnpsmentioning

confidence: 99%

“…Preparation of fluorescent CNPs from bioprecursors may provide a new approach for bottom-up CNPs fabrications. Although carbon nanoparticles derived from [20,32] to the best of our knowledge, the direct synthesis of fluorescent CNPs from linear polysaccharides and cyclic oligosaccharides and their fluorescent properties remains less studied.…”

Section: Introductionmentioning

confidence: 99%

“…Because of these features, various methods for fluorescent CNP synthesis have been reported by using carbon-based materials as carbon resources. [14,19,20] For example, top-down methods include laser ablation of carbon powder [14], electrochemical oxidation [21] and arc discharge [22]; bottom-up methods consist of microwave synthesis, [23,24] combustion soots of candles, [25,26] thermal oxidation of carbon precursor by employing silica or zeolites as carriers [27,28] commercial activated carbon [29], lampblack [30] and watermelon peel as carbon resources [31]. All these methods suffer to some degree from drawbacks like tedious processes, harsh synthetic conditions or expensive starting materials.…”

Section: Introductionmentioning

confidence: 99%

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