Investigation of β phase formation in piezoelectric response of electrospun polyvinylidene fluoride nanofibers: LiCl additive and increasing fibers tension

Mokhtari, Fatemeh; Shamshirsaz, Mahnaz; Latifi, Masoud

doi:10.1002/pen.24192

Cited by 66 publications

(56 citation statements)

References 39 publications

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“…Additives can aid the electrospinning process, and also improve the piezoelectric performance of the composites bers. The presence of inorganic salt LiCl of 0.00133 wt% in PVDF DMF/acetone (4/6) solution in 16 wt% concentration, 211 decreased the ber diameter from 340 nm to 65 nm due to the increased charge carried by the jet, and increased the b-phase formation to 93.6%. The voltage response of PVDF was increased from 1.89 V to 8 V for composite bers with 0.00133 wt% of LiCl, which is of interest for harvesting.…”

Section: Structure Of Polyvinylidene Uoride (Pvdf) and Polymorphsmentioning

confidence: 99%

Multiscale-structuring of polyvinylidene fluoride for energy harvesting: the impact of molecular-, micro- and macro-structure

2017

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Section: Structure Of Polyvinylidene Uoride (Pvdf) and Polymorphsmentioning

confidence: 99%

Multiscale-structuring of polyvinylidene fluoride for energy harvesting: the impact of molecular-, micro- and macro-structure

2017

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“…[213][214][215][216][217][218][219] It has indeed been demonstrated that aligned PVDF nanofiber arrays possess superior piezoelectric properties compared to random nanofibers meshes. [220][221][222][223] Hence, a very promising research topic is how the molecular configuration of piezoelectric polymers and their polymorphic states relate to the nanofiber geometry and how piezoelectric properties can be induced by electrospinning.…”

Section: Polymeric Fibersmentioning

confidence: 99%

Electrospinning Piezoelectric Fibers for Biocompatible Devices

Azimi

Milazzo

Lazzeri

et al. 2019

Adv Healthcare Materials

110

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The field of nanotechnology has been gaining great success due to its potential in developing new generations of nanoscale materials with unprecedented properties and enhanced biological responses. This is particularly exciting using nanofibers, as their mechanical and topographic characteristics can approach those found in naturally occurring biological materials. Electrospinning is a key technique to manufacture ultrafine fibers and fiber meshes with multifunctional features, such as piezoelectricity, to be available on a smaller length scale, thus comparable to subcellular scale, which makes their use increasingly appealing for biomedical applications. These include biocompatible fiber-based devices as smart scaffolds, biosensors, energy harvesters and nanogenerators for the human body. This paper provides a comprehensive review of current studies focused on the fabrication of ultrafine polymeric and ceramic piezoelectric fibers specifically designed for, or with the potential to be translated toward, biomedical applications. It provides an applicative and technical overview of the biocompatible piezoelectric fibers, with actual and potential applications, an understanding of the electrospinning process, and the properties of nanostructured fibrous materials, including the available modeling approaches. Ultimately, this This article is protected by copyright. All rights reserved. 3 review aims at enabling a future vision on the impact of these nanomaterials as stimuli-responsive devices in the human body.

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“…It should be noted that the fiber diameter is a factor that has an influence on the piezo‐response of fabricated samples as it was investigated before. Within the context of the efficacy of nanofiber's diameter on the piezoelectric response of PVDF nanofibers, Mokhtari et al [ 26 ] applied two approaches to achieve more content of the β crystalline phase and higher output voltage. In both of those methods, the addition of different concentrations of LiCl salt and applying tension on fiber by high‐speed drum collector, the smaller nanofibers were obtained that enhanced the piezo‐response.…”

Section: Resultsmentioning

confidence: 99%

“…To evaluate the potential of the prepared nanofibers for sensor and energy harvesting applications, the direct piezoelectric properties were characterized under the pressure mode using dropping ball test as described by Mokhtari et al [ 26 ] First, the samples were placed on a rectangular metal plane. To apply a uniform force on the external surface of the sensor, and also exploit all the exterior parts of the sensor for the voltage creation and avoid from any damage due to successive impacts, a squared plate with the dimension of 2 × 2 cm 2 was used on the samples.…”

Section: Methodsmentioning

confidence: 99%

Enhancement of β‐Phase Crystalline Structure and Piezoelectric Properties of Flexible PVDF/Ionic Liquid Surfactant Composite Nanofibers for Potential Application in Sensing and Self‐Powering

Varposhti

Yousefzadeh

Kowsari

et al. 2020

Macro Materials & Eng

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Polyvinylidene fluoride (PVDF) is a piezo‐polymer which among its crystalline phases, the β‐phase has been researched for the improvement of piezoelectric properties. In this study, to improve the β‐phase contents and thereby the piezoelectric response of the polymer, the effect of adding self‐synthesized ionic liquid surfactant (ILS) in PVDF nanofibers is studied. This material is added in different weight percentages into the PVDF solution and the nanofibers are produced by electrospinning to prepare active piezoelectric thin layers. SEM, XRD, FTIR, and piezo‐tests are employed for assessing the effect of the ILS on the enhancement of β‐phase in electrospun nanofibers and their piezoelectric performance. The results indicate ≈98.6% β‐phase formation in the sample containing 4 wt% ILS and in comparison with the pure nanofibers, the output voltage and its power density are improved 186.9% and 275%, respectively. Considering the results, it is suggested that the ILS can improve the piezoelectric response of the polymer in the fabricated structure by simple mixing in solution compared to other additives.

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Investigation of β phase formation in piezoelectric response of electrospun polyvinylidene fluoride nanofibers: LiCl additive and increasing fibers tension

Cited by 66 publications

References 39 publications

Multiscale-structuring of polyvinylidene fluoride for energy harvesting: the impact of molecular-, micro- and macro-structure

Multiscale-structuring of polyvinylidene fluoride for energy harvesting: the impact of molecular-, micro- and macro-structure

Electrospinning Piezoelectric Fibers for Biocompatible Devices

Enhancement of β‐Phase Crystalline Structure and Piezoelectric Properties of Flexible PVDF/Ionic Liquid Surfactant Composite Nanofibers for Potential Application in Sensing and Self‐Powering

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