EP2737627A1

EP2737627A1 - Gas switch triggered by a laser filament

Info

Publication number: EP2737627A1
Application number: EP12753760.3A
Authority: EP
Inventors: Jean LAROUR; Léonid ARANTCHOUK; Aurélien HOUARD; André MYSYROWICZ
Original assignee: Centre National de la Recherche Scientifique CNRS; Ecole Polytechnique; Ecole Nationale Superieure des Techniques Avancees Bretagne
Current assignee: Centre National de la Recherche Scientifique CNRS; Ecole Polytechnique; Ecole Nationale Superieure des Techniques Avancees Bretagne
Priority date: 2011-07-29
Filing date: 2012-07-23
Publication date: 2014-06-04
Also published as: WO2013017774A1; FR2978620B1; FR2978620A1

Abstract

The invention relates to a high-voltage electrical switching system including at least: two remote electrodes adjusted so as to have a potential difference; and a laser device for electrically connecting the two electrodes so as to generate an electric arc. Said laser device includes a pulsed laser configured so as to generate, according to a so-called filamenting process, a laser filament electrically connecting the two electrodes.

Description

"Gas trigger triggered by laser filament."

The present invention relates to a high voltage electrical switching system. It finds a particularly interesting application in the field of pulsed powers.

The science and technology of pulsed powers are based on the manipulation of energy to pass from a storage on long times to a delivery on very short durations or with a very steep rising front. These performances are achieved by the realization of technological bricks which are optimized individually but also between each of which the adaptation is optimized. In the first place, the switching brick is a key element of the final performance and also an element where the margin of progression still exists.

By way of example, the system according to the present invention can be implemented as an eclator with its trigger in a Marx generator. Such a generator is an electrical circuit for producing a high voltage pulse with a strong current. To do this, several capacitors are charged in parallel at a given voltage. Then, all the capacitors are discharged in series by means of spark gap switches. The synchronization of the spark gaps placed between each stage is the key to a nominal operation.

Systems are known for the purpose of performing a fast switching with low inductance and a well synchronized triggering.

FR2702900 (A1) (also published as US5621255) discloses a surface spark gap Marx generator. It consists of three plane electrodes separated by a dielectric sheet. When a sufficient voltage is applied to one of the electrodes, the current flows between the other two electrodes serving as conductor for the capacitors.

US5399910 (A) discloses a very high voltage and high current pulse generator. Coaxial cables are loaded in parallel, and then electrically operated spark gaps are used to discharge them in series.

Work was inspired by a similar objective, namely the optical initiation of an electric discharge between two distant electrodes, brought to a high potential difference and bathed in a gas. There are differences mainly related to the mechanism of creating ionization sufficient to make a path in the gas. This path is generally rectilinear due to the slightly divergent nature of the laser light beams.

In general, electrically triggered gas switches are known:

These components have a high power withstand voltage, especially with the gas overpressure (air, nitrogen), or the use of highly electronegative gas (sulfur hexafluoride SF6). They have been in use for many years and have undergone few changes, except for the introduction of the electric tripping trigger ("trigatron" and "field distortion effect"). They are known for their reliability, tensile strength and ability to pass high loads and high peak currents. A powerful initiating discharge will provide ultraviolet photons capable of pre-ionizing the gas by volume and improving the growth of the main discharge.

Their weaknesses are at two levels:

- The need to organize pulsed high voltage circuits attached to bias the trigger electrode. These auxiliary circuits can be expensive, consume space, and themselves make use of spark gaps in general; the temporal uncertainties are thus stacked.

- The diffusion time of the plasma to fill the interelectrode space and ensure sufficient conduction.

Laser triggered gas switches are also known:

These switches are an evolution of the preceding type, but with a laser initiation of a plasma located between the electrodes. This plasma can be a plasma pen created in the middle of the gas (laser-gas interaction) or at the level of an electrode (laser-solid interaction). They gain in reliability because they allow to move further away from the point of self-triggering. The time taken by the plasma pen to develop in the interelectrode space induces a laser-current delay that can be long and a jitter over this time.

Finally, semiconductor switches are known:

This type of component is under development but has not yet reached maturity. Indeed, these are components that can not support a static voltage very high (typically a few kV) and can not withstand a high conduction current (typically a few kA). As a result it is necessary to place several components in series to hold the static voltage. In addition it is necessary to install in parallel several of these chains to distribute the current in the limit of the bearable. This leads to a series / parallel assembly which may involve a large number of elementary components (tens, hundreds), which is expensive and cumbersome. Finally it is necessary to treat the reliability of the trigger, so as to have no elementary component not triggered. Failure to comply with this condition results in the destruction of all or part of the whole. This requires a powerful trigger system and complex circuitry to bring the trigger pulse to each element. An additional defect comes from power limitation and through load. An impulse too long will cause a deposit of energy and a prohibitive heating. Finally, the rise time of the current is often insufficient for many applications (200ns to 2ps) for a fairly high individual cost (typically 2000 to 3000 €).

The present invention aims to overcome the aforementioned drawbacks by proposing a fast switching system high voltage and high current.

Another object of the invention is to develop a laser-controlled switching system that is simple to implement, in particular when there are several stages.

At least one of the aforementioned objectives is achieved with a high voltage electrical switching system comprising at least:

two distant electrodes brought to a potential difference,

- A laser device for electrically connecting the two electrodes so as to initiate an electric arc.

According to the invention, the laser device comprises a pulsed laser configured to generate, according to a so-called filamentation process, a plasma filament, hereinafter referred to as a laser filament electrically connecting the two electrodes.

The potential difference between the two remote electrodes can be high, especially greater than the kilovolt. The laser device can initiate an electric arc by instantly creating a conductive plasma brush touching both electrodes.

The pulsed laser is in particular configured to generate, according to said so-called laser filamentation process, an ionized channel of suitable size and sufficiently high conductivity to close the external electrical circuit connected to said electrodes.

The electrodes are preferably polarized.

With the system according to the invention, a pulsed laser is used in particular of femtosecond type as described in the publication "Femtosecond Filamentation in Transparent Media Couairon and Mysyrowicz, Physics Reports, 441 (2007) pp. 47-189).

In other words, the system according to the invention consists in coupling an inter-electrode space with the extended and linear focus of an ultra-short and ultra-intense laser beam. The invention is a non-photonic application of ultra short lasers. If a laser flux condition (W / cm ² ) greater than a threshold which depends on the interelectrode medium is reached in the interelectrode space, this medium is ionised in a homogeneous filiform channel over a length much greater than extension of the linear focus. This ionization develops during the duration of the pulse, less than 0.1 nanosecond, and has a life of the order of 1 ns.

Thus the inter-electrode space, which is assumed to be below the breakdown threshold under high static voltage, is abruptly short-circuited by a resistant linear channel. This channel is advantageously weakly resistant. The passage of the current in this channel induces a heating and an increase in the diameter of the channel and the passage of a rapidly variable current. The growth of this current can be very fast.

One of the advantages of the invention is to provide a continuous resistive channel between the electrodes without any interruption. It is also possible to conduct a conductive channel abruptly between the electrodes without any interruption. This channel can be without interruption, in particular along the axis of the laser beam. If an interruption existed, as in systems of the prior art of laser breakdown, a time difficult to control would be necessary to fill this space (by diffusion or drift, including charged particles, electrons, ions, in the static electric field) and conduction, this time being strongly dependent on the pressure and the nature of the inter-electrode medium.

The breakdown field is the inter-electrode electric field allowing the creation of an electric arc between the two electrodes in the absence of a plasma.

Furthermore, in the system according to the invention, the incident laser beam provides a reliable time reference for the discharge. This electrical switching system is fast, high voltage and allows the circulation of a strong current.

According to an advantageous embodiment of the invention, the two electrodes are arranged one after the other along the laser filament. In this embodiment, the inter-electrode distance can be defined along the filament.

Advantageously, at least one of the electrodes has an opening therethrough on either side, the laser filament being intended to pass through said opening and reach the other electrode. The current path is in the filament parallel to the axis of the filament.

Preferably, the two electrodes each comprise an opening; the two openings being collinear, the filament then passes through the two openings. The pulsed laser can be configured so that the diameter of the filament is less than or equal to the diameter of the opening.

According to an advantageous characteristic of the invention, the two electrodes each have a cylindrical shape, the opening being made along the axis of revolution of the cylinder, this axis being collinear with the axis of the filament. In particular, it can be provided that the opening is made so that at least one of the two electrodes has a shape around the opening identical to the shape of a torus; the filament and this electrode thus being tangent along a circle. In other words, the inner surface of the electrode defining the opening is of rounded shape so that this electrode comes into contact with the filament on a circular line perpendicular to the filament axis.

According to another embodiment, the two electrodes may be arranged opposite each other along an axis perpendicular to the filament axis. In this case, the inter-electrode distance can be defined in a direction perpendicular to the filament axis. We can configure the pulsed laser so that the diameter of the filament is substantially equal to the interelectrode distance.

Advantageously, at least one of the electrodes may have a rounded profile on the filament side in a plane comprising the axis of the filament. In this case, the filament and the electrode are tangent at one point.

In general, a rounded (including cylindrical) shape of the electrode has the advantage of avoiding discharge primers at the corners, and of lengthening the plasma-metal contact lines and of attaching the arcs to solid parts. .

Otherwise, it can be expected that the two electrodes have an elongate shape along the filament. In this case, the contact between the filament and the electrode is along a line along the filament. The breakdown is then all along the electrode, the current is distributed, which greatly reduces the inductance. Having a low inductance is a guarantee of short response time, so a fast system. Indeed, the inductive elements introduce latency that is harmful to the speed of the system.

In practice, when the laser filament is not blocked by one of the electrodes, a blocking screen is disposed through and at the distal end of the filament. This screen is to be understood advantageously as a regulatory rollover element and has a purpose of securing. If it is metallic, it will have a role of faradisation. Its presence on the path of the laser beam has no influence on the phenomenon sought in the device.

According to the invention, there is used a holding piece of rigid material and electrically insulating, attached to the two electrodes to maintain fixed inter-electrode distance. This holding part can also be removable and / or adjustable, in particular to change the interelectrode distance if necessary.

This holding piece forms a cavity containing the two electrodes. The cavity may be provided with a conduit for introducing a priming gas or inter-electrode rinsing. The inter-electrode medium may be air at atmospheric pressure to simplify the embodiments. However, the laser filament can be implemented in a gas, from 0.1 bar to a few bars for gases, and also in a liquid. In order to allow the alignment of the various elements of the system according to the invention, there is further provided a positioner, carrying the electrodes, for positioning these electrodes with respect to the filament.

According to an advantageous embodiment of the invention, the two electrodes constitute a spark gap for an external electric circuit, one of the electrodes being connected to the ground (in particular the ground) of this electric circuit, the other electrode being connected to another terminal of this external electrical circuit. Said other terminal is in particular a polarized terminal of this external electrical circuit,

The system according to the invention associating high voltage and laser filamentation makes it possible to reduce to a very low level the residual time between the instant of application of an external stress, electrical or otherwise, with a view to triggering a gas spark gap subjected to a high electrical voltage, and the time of realization of a significant level of electrical current flowing through the spark gap.

In general, gas dischargers have trip delays considered to be small compared to other devices, but significantly longer than the present system according to the invention.

The present invention reduces at a sub-nanosecond level the closing jitter of a gas spark gap. The invention allows almost perfect synchronization of gas dischargers on switching systems up to the meter.

By way of non-limiting example, the external electrical circuit may be a Marx generator. The short delay accessible by the system according to the invention allows a direct use of switching power but also a synchronized association of such components to form a pulsed generator very high voltage, precisely Marx type generator, with improved performance by to the state of the art, or to form any other electrical device requiring such synchronization.

According to one embodiment of the invention, the system may comprise several pairs of electrodes arranged along the filament. This makes it possible to exploit the important spatial extension of the ionized channel (tens of cm to 100cm). Thus, it is possible to synchronize several laser-initiated breakdowns, mainly by arranging the inter-electrode spaces successively on the laser path. The propagation of ionization will be done with the speed of light, just like the wave of current that will be able to develop. Under these conditions, it is possible to have several spark gaps triggered according to a series electric circuit and to constitute, for example, an adder generator of the Marx generator type, or a cable generator with a single laser. With conventional laser triggers, it is not possible to create more than one optical focus except to divide the beam into several branches, but in this case, the initial power must be oversized to reach the breakdown threshold on each beam.

Advantageously, each electrode is made from a pure metal or a metal alloy, in particular from a copper and tungsten alloy. This alloy is sometimes called "cuten" and has a very good resistance to erosion.

The diameter of the filament varies between a fraction of a millimeter and a few millimeters.

The pulsed laser can deliver ultrashort pulses of high-power infrared, visible or ultraviolet light. These pulses preferably have a power greater than the filamentation threshold in the air, for example 5Gwatt at 800nm wavelength in atmospheric air.

With the system according to the invention, the length of the laser filament can be between a few centimeters and a meter. This gives a system that is simple to implement and can be controlled remotely.

Of course, the various features, forms and embodiments of the invention may be associated with each other in various combinations to the extent that they are not incompatible or exclusive of each other.

Other advantages and characteristics of the invention will appear on examining the detailed description of a non-limiting embodiment, and the appended drawings, in which:

FIG. 1 is a diagrammatic view of a high-voltage, high-current fast electric commutation system triggered by laser filamentation according to the invention, in a coaxial arrangement of the electrodes;

- Figure 2 is a side sectional view of the system of Figure 1; FIG. 3 is a cross-sectional view of the system of FIG.

1; FIG. 4 is a diagrammatic view of a high-voltage, high-current fast electric switching system triggered by laser filamentation according to the invention, in a crossed arrangement of the electrodes;

FIG. 5 is a cross-sectional view of the system of FIG. 4; and

FIG. 6 is a schematic view of a system according to the invention comprising several pairs of electrodes.

In Figures 1 to 3, there is shown an external electrical circuit C which may include one or more of the following in combination: capacitor, resistor and inductor. This external electric circuit is connected to ground (in particular ground) and has an input E. The system according to the invention comprises in particular a spark gap consisting of two electrodes 1 and 2 for discharging the external electric circuit; this circuit has been previously loaded via a not shown charging system. To do this, the electrode 1 is connected to the ground (in particular earth) by means of a conductor 11 supporting a high electric current and the electrode 2 is connected to the input E by means of a conductor 21 supporting a high electric current. Each electrode 1 and 2 is of cylindrical shape with an opening in the middle. In each electrode, the opening 12, 22 is a central hole passing through the electrode along the axis of revolution. The two openings 12, 22 are aligned and have a diameter substantially identical to the diameter of a laser filament 8 generated by a laser device L. These electrodes can be made of stainless steel, brass, copper or metal alloy at high temperature. melting and consequently low erosion rate, for example a copper-tungsten alloy. The constituent materials of the electrodes 1 and 2 do not have asperities or sharp angles to prevent spontaneous electrical breakdowns in the air or in another gas.

In response to a discharge command, the laser device L generates a laser beam 6 which then passes through a focusing optic 7 so as to create a laser filament 8 according to the filamentation process.

Focusing optics 7 can make it possible to manipulate the position of the beginning of the filament and to adjust its length, in order to better adapt the filament to the geometry of the spark gap. This optics is optional insofar as an ultra short and powerful laser beam, as described in the introduction (cf. Couairon and Mysyrowicz, Physics Reports, 441 (2007) p. 47-189), can self-localize and then spin alone. Advantageously, it is possible to position the triggerable electrical device at a great distance from a laser L devoid of focusing optics.

In general, the process of forming an ionized region of the air greater than the Rayleigh distance of the laser beam is generally described in the scientific literature as femtosecond filamentation. A high power laser pulse is able to ionize the molecules of the atmosphere. The technology of short-pulse lasers makes it possible to reach the necessary powers for the ionization of the air with very modest pulse energies, much lower than the joule. These lasers have a duration of the pulse less than one picosecond, that is to say 10 ^"12 second and can reach an instantaneous power superior to 10 GW, that is to say 10 ⁷ watts.Infrared pulses of some millijoules of energy, focused in the air single lens are sufficient to create a conductive plasma over distances of several centimeters around the focus of the lens.The laser pulses can come from a femtosecond laser with titanium-doped sapphire as active medium. physical process leading to long-range ionization of the air is well identified, it is a competition between the autofocusing of the laser beam and the multiphoton ionization involving the simultaneous absorption of a large number of infrared photons The ionized filament, which easily reaches 20 cm and can exceed one meter in length, can be very thin, 100 to 200 μm in diameter. created plasma can be 10 ¹⁶ el ./cm ³ . The laser filament provides a continuous bond between the electrodes as the filament passes near both electrodes. When the laser is powerful, the laser filament may actually consist of several dense filaments (a bundle of filaments) within a channel-shaped plasma.

The laser filament 8 first passes through the electrode 2 via the opening 22 by touching the inner surface of the electrode 2 forming said opening 22. Then the filament 8 travels the inter-electrode distance before reaching the electrode 1 and pass through the opening 12 also touching the inner surface of the electrode 1 forming the opening 12. Thus, the two electrodes 1 and 2 come into contact with the laser filament 8 which makes it possible to circulate a strong current between the two electrodes. When the laser filament 8 is not present, the two electrodes have a high potential difference, of the order of several tens of kV.

In other words, the filamentous plasma forming the laser filament 8, created by a focused laser light, has sufficient electrical conductivity to initiate the passage of a high electric current between the electrodes 1 and 2 when their prior connection to the electrical circuit outside C imposes a high potential difference. The electric arc initiated along the laser filament 8 between the electrodes 1 and 2 can be maintained after the end of the laser pulse when the circuit C is connected by the conductors 11 and 21.

The nature and shape of each of the electrodes 1 and 2 enable them to withstand the passage of a current of high intensity, typically 1000 amps to several hundreds of thousands of amperes. The passage of a high current between the electrodes 1 and 2 is not limited by the set "electrodes and laser filament", but by the characteristics of resistance, inductance and capacitance of the external electrical circuit C. This set "Electrodes and laser filament" introduces a small or negligible additional inductance in front of that of circuit C.

According to the invention, the electrodes 1 and 2 are held together by a holding part 3 (or a stack of moving parts) made of rigid and insulating electrical materials. The holding part makes it possible to maintain the distance between the electrodes 1 and 2 fixed. It is possible to adjust this distance by a mechanical adjustment of a stack of parts constituting the holding part 3. The nature and the shape of the retaining piece 3 allow it to withstand a high potential difference applied between the electrodes 1 and 2, typically more than 10000 volts.

The laser filament 8 is in the form of a cylinder with an axis of revolution A. The electrodes can be positioned precisely and separately with respect to the predefined axis A by means of a positioner 4 adjustable in at least three directions. This positioner serves as a support for the electrodes 1 and 2. The combined action of the focusing optics 7 and the positioner 4 ensures the proximity of the laser filament 8 and each of the electrodes 1 and 2.

The holding piece 3 defines a cavity containing the two electrodes 1 and 2 in the atmospheric air or in a controlled gas flow. A gas supply is provided via the duct 5 ensuring an appropriate flow of gas (air dry, other dry gas such as nitrogen, argon) for the rinsing of the interelectrode zone.

There is also provided (not shown in the figures) a protective cover for the laser filament including in particular a locking screen 9, for example a metal or insulating plate, which can withstand the direct impact, when the laser device L is of very high power. . The protective cowling advantageously makes it possible to block the output of the laser filament.

This protective cover according to the invention can simply allow the device to ultimately comply with the safety rules (blocking laser radiation) or electrical shielding (faradisation).

In Figure 2, we see a particular embodiment of the electrodes 1 and 2 wherein the inner surface of each electrode is identical to an inner surface of a torus, that is to say rounded. Thus, the contact surface between the electrode and the laser filament is a circle perpendicular to the axis A.

In Figures 4 and 5, the elements playing the same roles as in Figures 1 to 3 are identified in the same way. The difference lies in the arrangement and the shape of the electrodes 1 and 2 which are here elongated along the laser filament 8. The contact surface is no longer a circle around the laser filament 8, but a longitudinal line along the laser filament 8. Each electrode has a rounded shape on the contact side with the laser filament 8, and a flat shape on the side opposite to the laser filament 8. Therefore, the inter-electrode distance is substantially identical to the diameter of the laser filament 8. The current high intensity that must travel through the electrodes passes through the laser filament perpendicular to the axis A. In fact, it creates several lines of current, all along the line of contact of each electrode, this to limit the inductance between the two electrodes.

In FIG. 6, several spark gaps are associated to fill a function within a more complex circuit, the association of neighboring devices being done via insulating mechanical adaptations 3ab, positioners 4a and 4b and adapted connection circuits 12ab (FIG. for example a capacitor). There are two groups a and b of systems as shown in Figure 2 with external electrical circuits Ca and Cb placed in series along the axis A to exploit the synchronous conduction of each by the laser filament 8. The group has, identically to the system of the FIG. 2, two electrodes 1a and 2a, a holding part 3a, the positioner 4a and a conduit 5a. Group b comprises, identically to the system of Figure 2, two electrodes lb and 2b, a holding member 3b, the positioner 4b and a conduit 5b. The electrical conductors 1a, 21a and 11b, 21b respectively allow to connect each spark gap a, b to an external electrical circuit Ca, Cb. On the other hand, a single laser device L is used to generate a single laser filament 8 over a distance large enough to reach the four aligned electrodes.

The distances between two neighboring groups along the axis A are sufficiently proportioned so that there is no triggering of an intense electric arc between them but only within each of the groups, respectively between the electrodes. la and 2a and between lb and 2b. The laser beam from L can trigger several similar devices placed not necessarily on the same axis A if the beam 6 is divided into several sub-beams each leading to the creation of a laser filament.

The invention consists in exploiting the filiform plasma channel created during the focusing of an ultra-short and ultra-intense laser in order to short-circuit a highly polarized gaseous inter-electrode space and thus ensure rapid, precise conduction over time. (sub nanosecond) and able to withstand a strong current (tens of kilo amperes).

The long length of the laser filament makes it possible to associate several gas dischargers and to synchronize them very precisely. The invention makes it possible to design new topologies for the associations of spark gaps, for example in the spark gaps of Marx (we can speak more specifically of spark gaps of a Marx generator).

Of course, the invention is not limited to the examples that have just been described and many adjustments can be made to these examples without departing from the scope of the invention.

Claims

1. High voltage electrical switching system comprising at least:

two distant electrodes brought to a potential difference,

a laser device for electrically connecting the two electrodes so as to initiate an electric arc,

characterized in that the laser device comprises a pulsed laser configured to generate, according to a so-called filamentation process, a laser filament electrically connecting the two electrodes.

2. System according to claim 1, characterized in that the two electrodes are arranged one after the other along the laser filament.

3. System according to claim 1 or 2, characterized in that at least one of the electrodes comprises an opening therethrough on both sides, the laser filament being intended to pass through said opening and reach the other electrode.

4. System according to any one of the preceding claims, characterized in that the two electrodes each comprise an opening; the two openings being collinear, the filament passes through the two openings.

5. System according to claim 3 or 4, characterized in that the pulsed laser is configured so that the diameter of the filament is less than or equal to the diameter of the opening.

6. System according to any one of claims 3 to 5, characterized in that the two electrodes each have a cylindrical shape, the opening being made along the axis of revolution of the cylinder, this axis being collinear with the axis of the filament.

7. System according to any one of claims 3 to 6, characterized in that the opening is made so that at least one of the two electrodes has a shape around the opening identical to the shape of a torus; the filament and this electrode thus being tangent along a circle.

8. System according to claim 1, characterized in that the two electrodes are arranged opposite each other along an axis perpendicular to the axis of the filament.

9. System according to claim 8, characterized in that the pulsed laser is configured so that the diameter of the filament is substantially equal to the inter-electrode distance.

10. System according to claim 8 or 9, characterized in that at least one of the electrodes has a rounded profile on the filament side in a plane comprising the axis of the filament.

11. System according to claim 8 or 9, characterized in that the two electrodes have an elongate shape along the filament.

12. System according to any one of the preceding claims, characterized in that when the filament is not blocked by one of the electrodes, a locking screen is disposed through and at the distal end of the filament.

13. System according to any one of the preceding claims, characterized in that it comprises a holding piece of rigid material and electrically insulating, attached to the two electrodes to maintain fixed inter-electrode distance.

14. System according to claim 13, characterized in that the holding member forms a cavity containing the two electrodes, this cavity being provided with a conduit for introducing an ignition gas or inter-electrode rinsing.

15. System according to any one of the preceding claims, characterized in that it comprises a positioner for positioning the electrodes relative to the filament.

16. System according to any one of the preceding claims, characterized in that the two electrodes form a spark gap for an external electrical circuit, one of the electrodes being connected to the ground of this electric circuit, the other electrode being connected to a positive terminal of this external electrical circuit.

17. System according to claim 16, characterized in that the external electrical circuit is a Marx generator.

18. System according to any one of the preceding claims, characterized in that it comprises several pairs of electrodes arranged along the filament.

19. System according to any one of the preceding claims, characterized in that each electrode is made from a pure metal or a metal alloy.

20. System according to any one of the preceding claims, characterized in that each electrode is made from a copper alloy and tungsten.

21. System according to any one of the preceding claims, characterized in that the diameter of the filament varies between a fraction of a millimeter and a few millimeters.

22. System according to any one of the preceding claims, characterized in that the pulsed laser delivers ultrashort pulses of infrared light, visible or ultraviolet at high power.

23. System according to any one of the preceding claims, characterized in that the length of the laser filament is between a few centimeters and a meter.