A novel scheme to obtain tunable fluorescent colors based on electrospun composite nanofibers

Yang, Fan; Ma, Qianli; Dong, Xiangting; Yu, Wensheng; Wang, Jinxian; Liu, Guixia

doi:10.1007/s10854-014-2405-1

Cited by 6 publications

(4 citation statements)

References 33 publications

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“…Quantum dots (QDs) are inorganic semiconductor nanoparticles that offer several advantages as a new fluorescent material over conventional fluorescent dyes, including greater photo yield, greater resistance to photobleaching and a wider range of excitation/emission wavelengths. ,, In spite of such strengths, the potential toxicity of QDs due to the liberation of free ions and their poor solubility depending on the process of particle synthesis and surface modification, are big concerns that restrict their wider applications in biological fields. ,, The choice of the rare earth fluorescent materials has been driven by their fascinating light emission properties, such as their sharp and intense excited-state luminescence, narrow-width and visible emission bands, long decay time and high quantum yields. ,− Apart from scandium and yttrium, rare earth metal ions comprise 15 lanthanide (Ln) elements with typical electron configurations of [Xe]4f n ( n = 0–14), which can generate different electronic levels, bringing about the unique photoluminescent property for almost all Ln 3+ . Nevertheless, the “buried” nature of the f orbitals and the forbidden transitions of electrons between 4f orbitals require an “antenna” for improving the absorption of energy to activate the f-f transitions of rare earth metal ions. , Because of this reason, various organic ligands have been chosen as “antenna” to prepare rare earth organic complexes such as rare earth carboxylate complexes, rare earth β-diketone complexes and rare earth macrocyclic complexes . However, these molecules likewise show several shortcomings such as the biotoxicity, poor mechanical flexibility, easy photodegradation and instability under thermal stress, which inevitably undermine their value.…”

Section: Introductionmentioning

confidence: 99%

“…28 Nevertheless, the "buried" nature of the f orbitals and the forbidden transitions of electrons between 4f orbitals require an "antenna" for improving the absorption of energy to activate the f-f transitions of rare earth metal ions. 28,29 Because of this reason, various organic ligands have been chosen as "antenna" to prepare rare earth organic complexes such as rare earth carboxylate complexes, 30 rare earth β-diketone complexes 31 and rare earth macrocyclic complexes. 32 However, these molecules likewise show several shortcomings such as the biotoxicity, poor mechanical flexibility, easy photodegradation and instability under thermal stress, which inevitably undermine their value.…”

Section: Introductionmentioning

confidence: 99%

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Highly Efficient Fluorescent Material Based on Rare-Earth-Modified Polyhydroxyalkanoates

Zhang

Wei

et al. 2019

Biomacromolecules

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Fluorescent materials play an important role in biomedical fields. However, the main types of fluorescent materials suffer from several disadvantages especially the biotoxicity, which largely restrict its wider applications in biological fields. In this study, a highly efficient rare-earthmodified fluorescent material was successfully designed and fabricated based on polyhydroxyalkanoates, which are known as biodegradable and biocompatible materials. A new Functional-PHA polymer was microbially synthesized by engineered Halomonas bluephagenesis and was used as a basal matrix to generate the rare-earth-modified PHA. N-Acetyl-L-cysteine-grafted PHA (NAL-grafted-PHA) was first produced via a UV-initiated thiol−ene click reaction and the rare earth metal ions (Eu 3+ and Tb 3+ ) were subsequently chelated onto the NAL-grafted-PHA through the coordination effect. The composite material exhibited intense photoluminescence properties under UV laser excitation, indicating the excellent features as fluorescent material. The enhanced hydrophilicity and superior biocompatibility of rare-earth-chelated PHA were confirmed, suggesting its great potential application value in biomedical fields.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Highly Efficient Fluorescent Material Based on Rare-Earth-Modified Polyhydroxyalkanoates

Zhang

Wei

et al. 2019

Biomacromolecules

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“…Double-crucible technique has been proved to be an efficient, convenient and simple way to fabricate nanofibers, nanobelts and hollow nanofibers [24]. Meanwhile, electrospinning is a promising, straightforward and convenient way to prepare one-dimensional (1D) nanomaterials [25,26] with diameters ranging from tens of nanometers up to micrometers owing to its easy control and low cost, including nanofibers [27,28], core-shell structured nanofibers [29,30], core-shell structured nanotubes [31,32], nanowires [33], nanosheets [34,35] and nanobelts [36][37][38], etc. Nevertheless, the fabrication of PbS or PbSe nanofibers via electrospinning combined with a doublecrucible technique is not reported.…”

Section: Introductionmentioning

confidence: 99%

A new route to fabricate PbS nanofibers and PbSe nanofibers via electrospinning combined with double-crucible technique

Dong

et al. 2016

J Mater Sci: Mater Electron

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PbO nanofibers were fabricated by calcination of the electrospun PVP/Pb (NO 3 ) 2 composite nanofibers. For the first time, PbS nanofibers and PbSe nanofibers were successfully synthesized by double-crucible sulfurization and selenidation methods using PbO nanofibers as precursors, respectively. X-ray diffraction (XRD) analysis shows PbS nanofibers and PbSe nanofibers are respectively pure cubic phase with space group of Fm-3 m. Scanning electron microscope (SEM) observation indicates that the diameter of PbS nanofibers and PbSe nanofibers are 295.52 ± 25.43 and 265.31 ± 21.90 nm under the 95 % confidence level, respectively. The photocatalytic activities of samples were studied by using rhodamine B (Rh B) as degradation agent. When PbS or PbSe nanofibers are employed as the photocatalysts, the respective degradation rates of Rh B solution under the ultraviolet light irradiation after 220 min irradiation are 70.79 and 73.17 %. This preparation technique could be applied to prepare other metal chalcogenides nanofibers. The photocatalytic mechanism and formation process of PbS and PbSe nanofibers are also provided.

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“…However, pure rare earth complexes have serious limitations in practical applications as a reason of their poor mechanical properties and physicochemical stabilities. Rare earth complexes were usually added into a polymer matrix to form polymer-based composites in order to overcome the defects, and the composites can present excellent fluorescent properties and the enhanced mechanical performance [27].…”

Section: Introductionmentioning

confidence: 99%

Flexible composite nanobelts: facile electrospinning construction, structure and color-tunable photoluminescence

Tian

Dong

et al. 2015

J Mater Sci: Mater Electron

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The flexible color-tunable [Eu(BA) 3 phen ? Tb(BA) 3 phen]/PMMA composite nanobelts have been fabricated by single axial electrospinning. Scanning electron microscopy (SEM), energy dispersive spectrometry (EDS) and fluorescence spectroscopy were used to characterize the final products. As-prepared nanobelts are almost uniform and the thickness and width of them are respectively ca. 890 nm and 16.6 ± 0.09 lm. The fluorescence intensity of Eu 3? is increased with adding more Eu(BA) 3 phen into the composite nanobelts, and the fluorescence intensity of Tb 3? is found to increase monotonically with introducing more Tb(BA) 3 phen into the composite nanobelts. By adjusting the ratio of Eu(BA) 3 phen to Tb(BA) 3 phen complexes, the fluorescence color of composite nanobelts can be tuned from red to yellow, yellow green, and green under the excitation of 290-nm single-wavelength ultraviolet light. Besides, the emission color could also be tuned easily from red to yellow, yellow to green via variation of excitation wavelengths. The novel color-tunable composite nanobelts have potential applications in the fields of color displays and sensor systems.

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A novel scheme to obtain tunable fluorescent colors based on electrospun composite nanofibers

Cited by 6 publications

References 33 publications

Highly Efficient Fluorescent Material Based on Rare-Earth-Modified Polyhydroxyalkanoates

Highly Efficient Fluorescent Material Based on Rare-Earth-Modified Polyhydroxyalkanoates

A new route to fabricate PbS nanofibers and PbSe nanofibers via electrospinning combined with double-crucible technique

Flexible composite nanobelts: facile electrospinning construction, structure and color-tunable photoluminescence

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