Porous PTFE space-charge electrets for piezoelectric applications

Gerhard, Reimund; Künstler, W.; Gome, T.; Pucher, A.; Weinhold, Till J.; Seiß, M.; Xia, Zhang; Wedel, Armin; Danz, R.

doi:10.1109/94.868065

Cited by 90 publications

(46 citation statements)

References 26 publications

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“…Since the thermal stability of d 33 in ferroelectrets is dependent on the retention of the internal space charges, two approaches are possible to achieve this goal. One is the development of new ferroelectrets based on thermally stable electret materials, such as cross-linked PP (XPP) [10], cycloolefines (COC) [11], polyethyleneterephthalate (PET) [12], polyethylene-naphthalate (PEN) [13], and fluorocarbon polymers [14][15][16][17][18][19][20][21][22][23][24][25]; the other is chemical modification, such as surface modification of cellular PP by using fluorination [26]. Of these two approaches, the former one, in particular the one using fluorocarbon films, has shown the most promise.…”

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confidence: 99%

Fluoroethylenepropylene ferroelectrets with patterned microstructure and high, thermally stable piezoelectricity

et al. 2012

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Layered fluoroethylenepropylene (FEP) ferroelectret films were prepared from sheets of FEP films by template-patterning followed by a fusion-bonding process and contact charging. The layered ferroelectret films show consistency and regularity in their void structures and good bonding of the layers. For films composed of two 12.5 µm thick FEP layers and a typical void of 60 µm height, the critical voltage necessary for the built-up of the "macrodipoles" in the inner voids is approximately 800 V. At room temperature, Young's modulus in the thickness direction, determined from dielectric resonance spectra of the fabricated films with a typical thickness of 85 µm, is about 0.21 MPa. Initial quasistatic piezoelectric d 33 coefficients of samples contact charged at a peak voltage of 1500 V are in the range of 1000-3000 pC/N. From these, ferroelectrets with high quasistatic and dynamic (up to 20 kHz) d 33 coefficients of up to 1000 pC/N and 400 pC/N, respectively, which are thermally stable at 120°C, can be obtained by proper annealing treatment. This constitutes a significant improvement compared to previous results.

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confidence: 99%

Fluoroethylenepropylene ferroelectrets with patterned microstructure and high, thermally stable piezoelectricity

et al. 2012

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“…% of carbon content the piezo-activity is reduced as shown in Fig. (1), possibly because the electrical conductivity of the composite has increased so much [8,9]. 2) shows the piezoelectric constants of PZT/UPE/C (49/50/1) as a function of poling time .It appears that a very short poling time of 7h was enough to polarize this composite while without carbon the composite require almost 24 h to be poled.…”

Section: Resultsmentioning

confidence: 95%

Piezoelectric Coefficient Properties of a Flexible PZT/Upe/C Composite

Noori¹,

Noori²

2010

JNUS

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A flexible piezoelectric composite, made from Lead Zirconate Titanate(PZT) powder and Unsaturated polyester (UPE) resin, was doped with small amount of carbon semiconductor powder. The piezoelectric strain coefficient (d 33 ) and the dielectric behavior have been studied for this ceramic/polymer composite. The dielectric constant processes of the composite were observed to be dominated by those of undoped ceramic-polymer. The practical results of PZT/UPE/C with ratio 49/50/1 adding a semiconductor phase in the composite showed piezoelectric strain coefficient can be controlled and a continuous electric flux path could be created between the PZT grains. This composite may be poled at low voltage and in shorter time compared with composites without a conductive phase.

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“…For example, piezoelectrets with improved thermal stability were prepared from cycloolefines, 8 polyethylene-terephthalate, 9 polyethylene-naphthalate, 10 and from fluoropolymers. [11][12][13][14][15][16][17] Moreover, new methods to fabricate films with void structure are also being actively developed to further improve the piezoelectric activity.…”

Section: Introductionmentioning

confidence: 99%