RU2649914C1 - Device for studying characteristics of ion flow of plasma, created by pulse source, in particular by co2 laser - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to measurement means in plasma physics and charged particle physics. Device for studying the plasma produced by laser pulses consists of a vacuum chamber with an irradiated target, a time-of-flight tube, an electrostatic ion energy spectrum analyzer, a charged particle detector, which is used as a secondary electronic multiplier (SEM), a laser pulse sensor and a two-channel oscilloscope. Time-of-flight tube is completed with an insert of known length, with which additional calibration measurements are carried out, the result of which is the determination of the ion flight length and the time binding of the times of ion emission from the target to the laser pulse.

EFFECT: increase in the accuracy of determination of the flight length, eliminating the systematic error in measuring the arrival time and ion energy, as well as the possibility of direct measurement of the times of ion emission of different energy and charge from the plasma at the scale of the duration of the laser pulse due to an increase in the accuracy of the restoration of the energy spectra of ion dispersion.

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Description

The invention relates to the field of measurements in plasma physics and charged particle physics. It can be used to study plasma, in particular, to measure the characteristics of the ionic component of a plasma produced by pulsed heat sources, for example, laser pulses.

As analogues, one can choose the widely known from the literature analyzers of the energy of charged particles, in particular, electrostatic cylindrical deflectors [Afanasyev VP, Yavor S.Ya. Electrostatic energy analyzers for charged particle beams. - M .: Nauka, 1978. - 224 p., Page 78].

The closest analogue (prototype) of the present invention is a scheme for measuring the flow of ions from a laser plasma using a combination of an electrostatic energy analyzer (cylindrical deflector) and a span tube located in front of it, in which the plasma flow freely spreads [A.V. Kilpio, I.G. Kiselev, P.P. Pashinin, I.V. Rudskoy, B.Yu. Sharkov, E.V. Shashkov, A.V. Shumshurov. Investigation of the energy spectra of multiply charged ions 77 from a laser plasma. Quantum Electronics, T. 35, No. 7, 2005, S. 638]. The device allows to determine the charge and mass composition of ions and restore their energy distribution functions. It consists of a vacuum chamber with an irradiated target, a span tube attached to it, the axis of which coincides with the normal to the target surface, an electrostatic cylindrical analyzer and an ion detector, which is used as a secondary electron multiplier (WEC). The energy resolution of such a measuring circuit is determined by the length of the span pipe, the dispersion of the cylindrical deflector, and the dimensions of the input and output slots of the analyzer. The temporal resolution of the recording equipment and the stability of the power source of the deflector plates should be high enough so as not to spoil the resolution of the analyzer itself. For example, in the above prototype, the spectral resolution of the analyzer can be estimated by the oscillogram in Fig. 5, as ΔE / E = 2⋅10 ^-2 [A.V. Kilpio, N.G. Kiselev, P.P. Pashinin, I.V. Rudskoy, B.Yu. Sharkov, E.V. Shashkov, A.V. Shumshurov. Investigation of the energy spectra of multiply charged ions A from a laser plasma. Quantum Electronics, T. 35, No. 7, 2005, S. 638].

With higher requirements for spectral resolution, an appropriate choice of the parameters of the ion analyzer circuit can provide an energy resolution ΔЕ / Е close to 10 ^-4 . In accordance with [Afanasyev V.P., Yavor S.Ya. Electrostatic energy analyzers for charged particle beams. - M .: Nauka, 1978. - 224 p., P. 32, 85] ΔЕ / Е≈ (M⋅δ ₁ + δ ₂ ) / D _E , where δ ₁ , δ ₂ are the sizes of the entrance and exit slits, M - analyzer increase, D _E - energy dispersion. For example, for the device described below, this value is 8⋅10 ^-4 . The high spectral resolution of the device is not fully realized due to insufficient accuracy in determining the ion span from the target to the first wind turbine dynode, which creates a systematic error in calculating the arrival time and, therefore, the uncertainty δE of energy calculation.

The technical problem is the insufficiently high accuracy of determining the time-of-flight length of the circuit, which is a curved path and depends, in particular, on the position of the boundary of the outflow of ions from the plasma, a loosely defined configuration of the scattering fields at the inlet and outlet of the deflector, and the associated uncertainty in the particle paths which is not precisely determined by the length of the flight of particles from the entrance of the wind turbine to the first dynode, etc. The accuracy of direct measurement of the span length does not exceed ± 1 mm (ΔL = 2 mm) with a typical value of the total length of about 2 m. In this case, for particles having a velocity V, estimates of the span time t and its uncertainty Δt are: f = 200 / V , Δt = 0.2 / V, which corresponds to Δt / t = 1⋅10 ^-3 . As? E / E = 2Δt / t (E = mV ^2/2 = mL ² / 2t ^2, V = L / t, where m - mass of the ion, L - span length, t - time of flight, the ion energy will be determined relative error δЕ / Е = 2⋅10 ^-3 , which is significantly more than the possible resolution of the device itself (ΔЕ / Е).

The technical result of the proposed invention is to increase the accuracy of determining the flight length and, accordingly, eliminate the systematic error of measuring the arrival time and ion energy, as well as the possibility of directly measuring the departure times of ions of different energy and charge from the plasma on a laser pulse duration scale. These time points differ for ions of different energy and charge, but in the schemes for measuring the expansion spectra, including the prototype scheme, this difference is ignored, which can also cause errors in the restoration of energy spectra. Such errors are especially significant when using CO ₂ lasers operating in the free generation mode, the radiation duration of which exceeds 1 μs.

The present invention is a device for studying plasma produced by laser pulses, and consists of a vacuum chamber with an irradiated target, a time-of-flight tube with a calibrated insert, an electrostatic ion energy spectrum analyzer, a charged particle detector, which is used as a secondary electron multiplier (VE), laser radiation detector and two-channel oscilloscope.

New physical properties in the proposed device are implemented due to the following technical changes:

1) an additional insert of a well-known length, comprising (20 ÷ 30)% of the length of the main pipe, is introduced into the span pipe design, and with the help of which an additional measurement of the ion spectrum is carried out;

2) simultaneously with the signal of ions from a wind turbine, a signal of a laser pulse received from a laser radiation detector is simultaneously recorded on a two-channel oscilloscope.

The advantages of the device are realized in the process of measurement and data processing using technical changes.

Brief Description of the Drawings:

FIG. 1 - circuit diagram of the device according to the invention.

FIG. 2 (a, b, c, d, e) are oscillograms showing the dependences of the energy of C ⁵⁺ , C ⁴⁺ , C ³⁺ , C ^{2+ ions} (a, b, c, d) generated from the plasma on time and showing the shape of the laser pulse, scaled to the radiation flux density on the target (e).

The operation scheme of the proposed invention is illustrated in FIG. one.

The device consists of a vacuum chamber 1, where the studied target 2 is placed, which is irradiated with a laser pulse 5 introduced into the chamber through the optical window 4 and focused by the objective 3 focused on the target surface. The plasma generated by heating the target expands predominantly normal to the target surface in the vacuum space chamber and span pipe 6, at the output of which an energy analyzer of ion spectrum 8 is installed with input 7, output 10 and intermediate 9 slots, which provide high resolution together with the span pipe The instrument. At the output of the analyzer, a charged particle detector 11 is installed, which is used as a secondary electron multiplier (WEC) with a short response time. The wind turbine is loaded with a resistance 12, from which the signal is fed to the input of a two-channel oscilloscope 13. A laser pulse signal, obtained using a laser radiation detector 15, to which a part of the radiation reflected by the optical window 4 is connected, is connected to the second input of the oscilloscope. Technical "travel difference" signals of the analyzer and the optical detector associated with different cable lengths, etc., are measured independently and taken into account during processing.

For additional measurements, the device is equipped with an insert into the span tube 14 with a precisely changed length (ΔI <0.1 mm). Before carrying out measurements of the ion energy spectrum, calibration measurements of the span length and determination of the temporal reference of the laser pulse to the wind turbine signal are preliminarily carried out. To do this, at a fixed energy setting of the analyzer (fixed voltage on the deflector plates ± U) and for an ion of the chosen charge, two measurements of the absolute arrival time relative to the laser pulse are carried out: with and without insertion into the span tube. As a result, two expressions (equations) with two unknowns are obtained: the base length of the passage pipe L and the instant of time t (z, E) of the emission of the selected ion relative to the peak of the laser pulse. The accuracy of these measurements is limited only by the spectral resolution of the analyzer (the width of the spike on the waveform generated by the selected ion). Next, a series of measurements of the spectrum of all the observed ions is carried out and the results are processed with reference to the arrival times. Thus, firstly, the maximum accuracy in determining the ion energies is achieved, and secondly, qualitatively new data on the times of the release of various ions from the plasma are extracted.

So, as a result of the proposed structural changes and emerging new physical properties, we can assume that the proposed work meets the criteria of the invention.

Example 1

The performance of the device was tested in model experiments when measuring the spectrum of carbon ions (C ²⁺ ÷ C ⁶⁺ ) at a radiation flux density on the target of 10 ¹¹ W / cm ² . It is illustrated by the set of graphs in FIG. 2. The lower graph (e) represents the shape of the laser pulse, scaled by the radiation flux density at the target, graphs (a, b, c, d) show the energy dependences of C ⁵⁺ , C ⁴⁺ , C ³⁺ , C ions generated from the plasma ²⁺ , respectively, from time to time. The data were obtained with statistics of 20 shots at one analyzer tuning point, and the rms spread of the generation times are indicated as an error along the time axis.

This invention can be widely used to study the ionic component of a plasma produced by pulsed sources. Of particular interest is the use of pulsed CO ₂ lasers operating in the free-running mode, for which the radiation pulse is a long process. As a rule, it consists of a peak with a duration of (30–150) ns and a long (up to several microseconds) “tail”. The present invention allows to study the dynamics of the generation of ions in time relative to the laser pulse, as well as to conduct a deeper analysis of the spectra of ion expansion, for example, to distinguish between the signal components that result from the recombination of ions.

The invention allows, firstly, to increase the accuracy of restoration of the energy spectra of ion expansion, and secondly, to obtain qualitatively new information about the temporal nature of the generation of individual groups of ions relative to the plasma heating pulse.

Claims (1)

A device for studying the ion plasma flow generated by heating using a pulsed laser radiation source, containing a vacuum chamber with a target, a span tube connected to it along the axis of expansion, an electrostatic cylindrical ion energy spectrum analyzer and a charged particle detector, which use a secondary electron multiplier (WEC) ), the signal of which is fed to the input of the oscilloscope, characterized in that to increase the accuracy of absolute measurements of energy and ion arrival times to a level , determined only by the spectral resolution of the analyzer, the measurement scheme is completed with an insert of known length, using which an additional measurement of the arrival times of ions is carried out, which allows us to calculate the exact value of the total flight length, while to determine the time of departure of ions relative to the laser pulse, a signal is connected to the second input of the oscilloscope laser radiation detector.

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