A Nonperturbative Electrooptic Sensor for in Situ Electric Discharge Characterization

Pulsed power and intense electric field now apply to a large variety of domains for which the need of in situ nonperturbative measurements remains a challenge. The main requirements that sensors should fulfill for that purpose are nonmetallic composition, small size, ultrawide bandwidth, compatibili...

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Bibliographic Details
Published inIEEE transactions on plasma science Vol. 41; no. 10; pp. 2851 - 2857
Main Authors Gaborit, Gwenael, Dahdah, Jean, Lecoche, Frederic, Jarrige, Pierre, Gaeremynck, Yann, Duraz, Eric, Duvillaret, Lionel
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2013
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Crystals
Discharge measurement
Electric fields
Electricity
Electrooptic effects
electrooptics
Laser beams
Measurement by laser beam
Optical sensors
pigtailed sensor
Plasma physics
Probes
Sensors
vectorial measurement
Vectors
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Summary:Pulsed power and intense electric field now apply to a large variety of domains for which the need of in situ nonperturbative measurements remains a challenge. The main requirements that sensors should fulfill for that purpose are nonmetallic composition, small size, ultrawide bandwidth, compatibility with liquids and gases, possibility for remote measurements at long distances, true vectorial (field direction) time-domain measurements, capability of measuring electric fields up to the electric breakdown of air, and a large dynamic range. Obviously, all these requirements cannot be achieved by a unique sensor. However, most of them are fulfilled by pigtailed electrooptic (EO) sensors. In this paper, after recalling the principle of the EO effect and its use for electric field measurement, we deal with the measurement linearity and selectivity of the EO sensor. Associated with the nonperturbative behavior of the EO sensor, the measurement dynamics of EO sensors exceeds 100 dB. Furthermore, EO sensors present an intrinsic flat response from quasi d.c. (10 Hz) up to a few tens of gigahertz. Thanks to their composition of high dielectric strength materials and their optical pigtail, EO sensors are completely immune to the electromagnetic environment except on a very small volume (≅ 10 mm 3 ) corresponding to the transducer element of the sensor. This leads to a very high spatial resolution. We finally illustrate the capabilities of this technology through in situ measurement of the electric discharge transients and vectors.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2013.2257874