Characterization of laser-driven shocks of high intensity using piezoelectric polymers

Rességuier, T. de; Couturier, S.; Boustie, M.; David, Jean‐Christophe; Nierat, G.; Bauer, F.

doi:10.1063/1.363312

Cited by 13 publications

(12 citation statements)

References 8 publications

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“…The relationship for the oscilloscope response is given by de Rességuier et al (1996) and Peyre et al (2000) …”

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

“…However, the most common technique for shock pressure measurements is piezoelectric gauges. Thin polyvinylidene-fluoride (PVDF) film and its copolymer with trifluoroethylene P(VDF/TrFE) after specific treatments (stretching and subsequent application to electric field) demonstrate strong piezoelectric effect, being the most suitable material to construct different types of pressure gauges (Obara et al, 1995;de Rességuier et al, 1996;Bauer, 2003). The polymer piezoelectric gauges in comparison with more usual X-cut crystalline quartz (Graham, 1975;Fabbro et al, 1990;Devaux et al, 1993) have evident advantages: (1) higher sensitivities, which is important for moderate laser intensities and respectively moderate generated pressures in the presence of a strong parasitic noise; (2) linear response for higher pressure values.…”

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

“…A specific resin whose acoustic impedance was matched with the copolymer's one filled the transducer body to avoid SW reflection on the rear surface of the copolymer. The calibration test with flyer impacts was carried out earlier that gave for a piezoelectric constant a value K ¼ 5.35 mC/cm 2 (de Rességuier et al, 1996). The transducer current was delivered to Tektronix TDS 2024 scope with 100-V twisted-pare cable loaded by two 100-V resistors in parallel.…”

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

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Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

et al. 2008

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The paper is devoted to research and development of a novel experimental technique-liquid-filled laser-driven shock tube (LST) for modeling of Rayleigh-Taylor (RT) and Richtmyer-Meshkov (RM) hydrodynamic instabilities development at the contact surface of two immiscible liquids under shock wave (SW) passage. 100-J, 100-ns KrF laser facility GARPUN has been used to irradiate some opaque liquids. A homogenizing focusing system combined multi-element prism raster and a lens to provide non-uniformity less than a few percents across a square 7 Â 7-mm spot, laser intensities being varied in the range of q ¼ 0.004-2 GW/cm 2 . Surface plasma blow-off produced a planar SW, which propagated into the liquid. SW amplitudes as high as 0.8 GPa weakly damping with increasing thickness were measured in dibutyl-phthalate (DBP), which volumetrically absorbed ultraviolet (UV) laser light. Nonlinear absorption coefficients and laser breakdown thresholds were measured for pure water and UV optical materials intended to confine plasma. Test bench experiments were performed to produce standing acoustic waves as initial perturbations at the interface between two immiscible liquids.

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“…The relationship for the oscilloscope response is given by de Rességuier et al (1996) and Peyre et al (2000) …”

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

Section: Pressure Gauges and Layout Of Pressure Measurementsmentioning

confidence: 99%

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Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

et al. 2008

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“…This technique has already been used to evaluate the shock amplitudes induced by 10-20 ns pulses and some 5-6 GPa maximum levels were evidenced with saturation occurring above 10 GW cm −2 due to breakdown phenomena at the surface of the water [4]. Other techniques can also be used to measure shock amplitudes: we present here some original results obtained by EMV [8] and copolymer [9,10] techniques to characterize laser-driven shock amplitudes † Laboratoire pour l'Utilisation des Lasers Intenses -UMR No 7605 CNRS-CEA-Ecole Polytechnique-Université Paris VI-91128 Palaiseau, France. induced by 0.6 ns and 3 ns pulses as compared with more than 10 ns shocks.…”

Section: Shock Measurement Techniquesmentioning

confidence: 99%

Experimental determination by PVDF and EMV techniques of shock amplitudes induced by 0.6-3 ns laser pulses in a confined regime with water

Peyre

Berthe

Fabbro

et al. 2000

J. Phys. D: Appl. Phys.

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With the objective to envisage short pulses for laser-shock hardening of materials, this paper reports experiments where laser-shock amplitudes P generated with 0.6-3 ns laser pulses at λ = 1.06 µm in a confined regime with water have been compared with those achieved with the usual 10-30 ns configuration. First, the experimental characterization of shock waves with polyvinylidene fluoride (PVDF) and electromagnetic (EMV) gauges shows that the short durations allow the generation of higher shock amplitudes than longer duration pulses (10 GPa versus 5 GPa) because of an increase of the pressure saturation intensity threshold I th with short pulses (up to 100 GW cm −1 at 0.6 ns). Above I th , a pressure pulse shortening accompanies the saturation. The P = f (I ) curves have been confirmed by surface deformation measurements induced on a Al12Si alloy. Second, the use of 10 µm aluminium coatings on 316L steel targets impacted at 40 GW cm −2 irradiance was shown to provoke a 25% maximum increase of the peak pressures by type mismatch acoustic impedance effects. Lastly, the PVDF technique is shown to be an accurate method to measure laser shock wave profiles in the 0-200 GW cm −2 regime, whereas the EMV technique is limited to intensity values of less than 20 GW cm −2 .

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“…ii) Transductores de presión cuarzo [Bushnell68,Fairand76a,Devaux91], piezoeléctricos [Fabbro90,Resseguier96,Resseguier98] o cerámicos [Bushnell68]. En todos los casos se transforma el pulso de presión que alcanza al transductor en una señal eléctrica que permite visualizar temporalmente la magnitud del mismo.…”

Section: Evolución De La Presión Generadaunclassified

Optimización de campos de tensiones residuales en procesos de tratamiento superficial de materiales metálicos mediante ondas de choque generadas por láser

González¹

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Characterization of laser-driven shocks of high intensity using piezoelectric polymers

Cited by 13 publications

References 8 publications

Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

Experimental determination by PVDF and EMV techniques of shock amplitudes induced by 0.6-3 ns laser pulses in a confined regime with water

Optimización de campos de tensiones residuales en procesos de tratamiento superficial de materiales metálicos mediante ondas de choque generadas por láser

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