Preparation of aligned Eu(DBM)3phen/PS fibers by electrospinning and their luminescence properties

[Display omitted] •The super-long aligned luminescent composite fibers were prepared by electrospinning.•In an effort to aligning the fibers, two key techniques were employed simultaneously.•One was to make use of high molecular weight polystyrene (Mw=4.4×105).•The other was the usage of a low speed...

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Published in	Journal of colloid and interface science Vol. 400; pp. 175 - 180
Main Authors	Yu, Hongquan, Li, Tao, Chen, Baojiu, Wu, Yanbo, Li, Yue
Format	Journal Article
Language	English
Published	Amsterdam Elsevier Inc 15.06.2013 Elsevier
Subjects	Aligned composite fibers Alignment Ceramics Chemistry Continuous Electrospinning Electrostatic fields europium Europium complex Exact sciences and technology Fibers fluorescence Fluorescence lifetime General and physical chemistry High molecular weight polymer light intensity Low speed rotating drum Luminescence Molecular weight nanofibers photoluminescence Photoluminescence stability Physical chemistry of induced reactions (with radiations, particles and ultrasonics) polymers Polystyrene resins Sonochemical method Super-long Ultrasonic chemistry Sonochemical method Low speed rotating drum Continuous Electrospinning Aligned composite fibers Super-long Fluorescence lifetime Photoluminescence stability Europium complex High molecular weight polymer Speed Stability Sonochemistry Fiber Luminescence Photoluminescence Fluorescence Polymer Composite material Lifetime Preparation Molecular mass
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Abstract	[Display omitted] •The super-long aligned luminescent composite fibers were prepared by electrospinning.•In an effort to aligning the fibers, two key techniques were employed simultaneously.•One was to make use of high molecular weight polystyrene (Mw=4.4×105).•The other was the usage of a low speed rotating collecting drum (>0.5m/s)•The fibers with smaller diameter exhibited better photoluminescence stability. Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×105) in the electrospinning solution and the low speed (>0.5m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of 5D0 state and the luminescent intensity of Eu3+ in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen.
AbstractList	Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×10(5)) in the electrospinning solution and the low speed (>0.5 m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of (5)D0 state and the luminescent intensity of Eu(3+) in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen.Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×10(5)) in the electrospinning solution and the low speed (>0.5 m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of (5)D0 state and the luminescent intensity of Eu(3+) in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen. Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM = dibenzoylmethane, phen = 1,10-phenanthroline, PS = polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw = 4.4 X 105) in the electrospinning solution and the low speed (>0.5 m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of 5D0 state and the luminescent intensity of Eu3+ in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen. [Display omitted] •The super-long aligned luminescent composite fibers were prepared by electrospinning.•In an effort to aligning the fibers, two key techniques were employed simultaneously.•One was to make use of high molecular weight polystyrene (Mw=4.4×105).•The other was the usage of a low speed rotating collecting drum (>0.5m/s)•The fibers with smaller diameter exhibited better photoluminescence stability. Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×105) in the electrospinning solution and the low speed (>0.5m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of 5D0 state and the luminescent intensity of Eu3+ in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen. Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)3phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×10(5)) in the electrospinning solution and the low speed (>0.5 m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)3phen. The results showed that the fluorescence lifetime of (5)D0 state and the luminescent intensity of Eu(3+) in Eu(DBM)3phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)3phen. Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is an important step toward the exploitation and applications of these fibers. In the present report, super-long aligned luminescent composite Eu(DBM)₃phen/PS fibers (DBM=dibenzoylmethane, phen=1,10-phenanthroline, PS=polystyrene) were prepared via an electrospinning method. The key to the success of this method was the usage of high molecular weight PS (Mw=4.4×10⁵) in the electrospinning solution and the low speed (>0.5m/s) collecting drum. Luminescent properties of the composite fibers were systemically studied in comparison with that of the corresponding pure europium complex Eu(DBM)₃phen. The results showed that the fluorescence lifetime of ⁵D₀ state and the luminescent intensity of Eu³⁺ in Eu(DBM)₃phen/PS composite fibers increased gradually with the fiber diameter. The composite fibers with smaller diameter exhibited better photoluminescence stability than that of the pure complex Eu(DBM)₃phen.
Author	Yu, Hongquan Li, Yue Li, Tao Wu, Yanbo Chen, Baojiu
Author_xml	– sequence: 1 givenname: Hongquan surname: Yu fullname: Yu, Hongquan email: yuhq7808@yahoo.com.cn organization: College of Environmental and Chemical Engineering, Dalian Jiaotong University, Dalian, Liaoning 116028, PR China – sequence: 2 givenname: Tao surname: Li fullname: Li, Tao email: litao19871987@126.com organization: College of Environmental and Chemical Engineering, Dalian Jiaotong University, Dalian, Liaoning 116028, PR China – sequence: 3 givenname: Baojiu surname: Chen fullname: Chen, Baojiu email: chenmbj@sohu.com organization: Department of Physics, Dalian Maritime University, Dalian, Liaoning 116026, PR China – sequence: 4 givenname: Yanbo surname: Wu fullname: Wu, Yanbo email: wuyanbo_djd@126.com organization: College of Environmental and Chemical Engineering, Dalian Jiaotong University, Dalian, Liaoning 116028, PR China – sequence: 5 givenname: Yue surname: Li fullname: Li, Yue email: liyue871123@126.com organization: College of Environmental and Chemical Engineering, Dalian Jiaotong University, Dalian, Liaoning 116028, PR China
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Snippet	[Display omitted] •The super-long aligned luminescent composite fibers were prepared by electrospinning.•In an effort to aligning the fibers, two key... Electrospinning is a technique employed to prepare nanofibers of polymer, ceramics, and composite that are used in the high electrostatic field. Alignment is...
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SubjectTerms	Aligned composite fibers Alignment Ceramics Chemistry Continuous Electrospinning Electrostatic fields europium Europium complex Exact sciences and technology Fibers fluorescence Fluorescence lifetime General and physical chemistry High molecular weight polymer light intensity Low speed rotating drum Luminescence Molecular weight nanofibers photoluminescence Photoluminescence stability Physical chemistry of induced reactions (with radiations, particles and ultrasonics) polymers Polystyrene resins Sonochemical method Super-long Ultrasonic chemistry
Title	Preparation of aligned Eu(DBM)3phen/PS fibers by electrospinning and their luminescence properties
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