DE2420275C3 - Device for analyzing a surface layer by ion scattering - Google Patents

Description

The invention relates to a device for analyzing a surface layer by ion scattering, comprising means for generating a primary, almost monoenergetic ion beam, the axis of which is attached to the surface layer bordering area coincides with the axis of an electrostatic analyzer, the two nearly contains cylindrical, hollow, coaxial electrodes, a nearly ring-shaped and coaxial with the analyzer Aperture opening for the passage of ions, which is arranged such that ions are passed through the are scattered over an angle greater than 90 ° to the axis of the primary ion beam, and one Detector for determining the kinetic energy of the ions that are scattered and allowed through the diaphragm.

Such a device is described in the earlier patent application DE-OS 24 02 728. In such an ion scattering spectrometer is the surface layer to be examined with a primary ion beam bombarded. The ions of this beam collide with the atoms of the surface layer on, whereby the impacts can be regarded as elastic under certain conditions. This means that the kinetic energy of an ion after impact using the laws of conservation of energy and momentum can be calculated. If:

£ i = kinetic energy of an ion before impact,
E ₂ = kinetic energy of an ion after impact, / Mi = mass of the ion,

m ₂ = mass of the atom in the surface layer against which the ion impacts,

γ = / nj // T7i,

θ = the angle of dispersion, i.e. the angle between the velocity vectors of the ion before and after the impact,

holds, if γ> 1, it is known that:

E ₂ = [! Cos "+ (y ² - sin ¹ ") *} / (! + Y) f Ei · It follows that mj can be determined by

ίο that £> is measured if nt \, £ 1 and θ are known and if it can be assumed that only simple impacts take place. This is done in an ion scattering spectrometer in the following manner. An ion beam, mostly made up of noble gas ions, with a known mass πΐ \ and known energy £ 1 is applied to the investigated Surface layer shot. The diaphragm is arranged so that the direction of scattered ions that the Gap, makes a known angle θ with the direction of the primary beam. The energy the transmitted ions are measured in an energy analyzer. At a certain voltage on the electrodes of the energy analyzer ^ only scattered ions with a certain energy £ 2 can pass the analyzer. This energy is so if w \, E \ and θ are given, indicative of the mass ΠΙ2 of the atoms in the surface layer struck by the primary beam. By changing the voltage on the electrodes of the analyzer, a spectrum can be obtained in the surface layer occurring atomic types are preserved. At certain voltages on the analyzer, a Peak in the signal emitted by the detector. The size of the tip is a measure of the relative Set of atoms in question, while those to the

) 5 peak associated voltage on the analyzer a measure for is the mass of the atoms in question.

The device described in the earlier patent application DE-OS 24 02 728 has openings in the coaxial electrodes of the analyzer through which the primary ion beam enters, further deflection means to deflect the primary ion beam along the axis of the analyzer.

It is the object of the invention to fit such an analysis device with coaxial electrodes

ben, in which, however, these openings and deflection means, which constitute a complication of the device, are superfluous.

To solve this problem are in a device of the type mentioned according to the invention

in means for generating the primary ion beam in such a way arranged that the axis of the latter coincides with the axis of the electrostatic throughout the analyzer Analyzer coincides and that the detector is almost annular and coaxial with the analyzer and encloses the primary beam of sound.

In a further embodiment of the invention, the mean angle of divergence of the detected ions have a value between 137 and 150 °. With these At angles of confusion it is possible to have a focus second order of the scattered ions on the To achieve detector without the scattered ions first pass the axis of the analyzer. A Second order focus has the advantage that ions from a relatively wide area around the mean divergence angle can be focused around on the detector.

The invention is explained in more detail below with reference to the drawings. It shows

F i g. 1 shows, in perspective, a partially broken open cylindrical analyzer for use in a Device according to the invention and

2 shows a schematic section through a device according to the invention.

In Fig. 1, a primary meets almost monoenergetic Ion beam 1 with an energy of e.g. B. a few hundred eV on a target 2. The ions should be selected in terms of mass, charge and energy, which is based on the prior art known means can be carried out, which do not need to be described in detail. Preferably be Noble gas ions, such as helium or neon ions, are used. One advantage of these ions is their high ionization energy; this makes it very likely that their charge will be neutralized on impact, which is true a small number of scattered ions result, but also the risk of multiple detection Impacts that spoil the measurement are significantly reduced. Has a device according to the invention precisely the property that even with a small number of scattered ions there is still a sufficiently strong one Signal generated by the detector.

The axis of the primary ion beam 1 coincides with the axis of an energy analyzer 3. Of the Energy analyzer 3 contains two coaxial, cylindrical electrodes 4 and 5. The ions of beam 1 collide against atoms in the surface layer of the target 2 and are scattered. Because of that, they lose a certain amount of energy that depends on the scattering angle and the mass of the atom in the The energy analyzer 3 measures this energy loss for a certain angle θ (Fig.2), which is greater than 90 °. So here is from Backscatter the speech. The angle θ can be ζ. Β. 14Γ amount, whereby the accepted by the energy analyzer 3 ions orbits over the surface of a Describe a cone with an apex angle of 78 °. The angle θ is determined by the position of the aperture 6 in the cylindrical electrode 4 with respect to the target 2 is determined. The scattered ions describe apparently parabolic orbits in the radial electric field between electrodes 4 and 5, some of which are labeled 7,8,9 and 10, and can only use the second aperture 11 if there is a certain potential difference between the electrodes 4 and 5 happen, which is a measure of their energy. The energy analyzer 3 focuses ion trajectories that are in begin at a point 12 on the target 2, in an annular focus behind the aperture 11. At this point, an annular detector 13 is for Detecting the scattered ions arranged. This ring-shaped detector 13 surrounds the primary Ion beam 1, as a result of which it can reach the target 2 without hindrance.

For a more detailed explanation, FIG. 2 shows a section by a device according to the invention along a plane through the axis of the primary ion beam 1. The Beam 1 is generated by an ion source 14, extracted from an extraction electrode 15, from focusing electrodes 16 and 17 in focus and selected for mass by a mass filter 18. The parts of the Energy analyzer 3 are given the same reference numerals as in F i g. I referred to.

For a satisfactory effect of the energy analyzer 3, the electric field between the electrodes should 4 and 5 must be equal to the field between two infinitely long, coaxial cylinders at all points. Since the Cylinders in practice have a limited length, electrodes must be attached to to define the general conditions for the field and to correct the field somewhat if necessary. To this "> Purpose, the cylindrical electrodes 4 and 5 are closed with the aid of the plates 19 and 20, which are shown in FIG are not shown for the sake of clarity. The plates 19 and 20 have a medium potential, the between the potentials of the cylindrical electrodes

in 4 and 5 lies. It is also possible to have the plates 19 and 20 in to divide several electrodes with different potentials in order to better approximate the required electric field. The panels can also be made of a material with a high electrical resistance must be made and connected to the cylindrical electrodes 4 and 5 to to get a steady potential.

A device according to the invention acts as has already been noticed with backscattering. There will be fewer ions in the reverse direction rather than pointing in the forward direction, but the device according to the invention is just as suitable particularly good for detecting small quantities of ions. The backscattering described offers on the other hand great advantages. First, when the primary beam strikes the target at right angles, the Risk of atomization is much lower, which means that the surface layer of the probes is less affected by the primary beam is damaged. At a win of incidence

At a 90 ° angle, sputtering often only occurs at 60 eV, while at an angle of incidence of 45 ° 10 eV suffice. Second, there is the risk of multiple impacts, which spoil the measurement result, at approximately vertical incident primary ray on the target much

J5 less than at an angle of incidence of less than 90 °.

When deriving the applied impact shape, the movement of the atoms on the impact plate is neglected This movement results in a broadening of the peak in the signal from the detector. Cooling down the Impact plate can therefore be advantageous in order to avoid closely adjacent peaks of the spectrum from one another to be able to distinguish.

An electron gun can be placed near the target low energy or a filament can be arranged in order to ensure a space charge equalization in a known manner. Next is it is possible to slowly move the target in layers with a separate ion beam or with the primary one Peel off the beam at an increased intensity so that deeper layers can also be analyzed can.

In the device shown in the drawing, the inside diameter of the electrode 5 is 125 mm and dc-f outer diameter of the electrode 4 50 mm. Of the Distance between the point 12 on the Auftreffplat'e 2 and the center of the annular detector 13 is 90 mm. The angle θ is 14Γ. The electrode 4 is related to the transport of the primary ion beam 1 grounded. To select ions with

With an energy of VEIelectronvolt, the potential of the electrode S (with respect to the electrode 4) must then be VVoIt .

The ion source 14 supplies a stream of ions in the On the order of a few nA to a few mA with an energy between a few tens of eV and a few keV can be set. The energy spread of the ions emerging from the ion source 14 is as already noted, relatively high

Requirements. In practice, this spread should be between 0.1 and 1.0 eV, which is evident from the State of the art known ion sources can be achieved.

The mass filter 18 preferably consists of the known Wien filter. In it is the ray of -, Subject to the action of an electric and a magnetic field, the directions of which are perpendicular to each other and are to the axis of the ray. As a result, only ions with a certain mass of the almost monoenergetic ion beam 1 not ab- i < > be steered and the filter 18 can pass. The other ions are likely to be deflected and in some Removal from the mass filter 18 intercepted with the help of a diaphragm.

The detector 13 must detect such a small ion current that direct current measurement is not possible with sufficient accuracy. In the described exemplary embodiment, a so-called channel plate is used as the detector 13, which consists of a plate with a large number of extremely thin secondary emitting channels. Per striking lon. which after passing the aperture II is accelerated to an energy of a few keV in that the detector 13 is applied to a suitable potential with respect to the electrode, such a channel plate supplies the output 10 ^J to 10 "electrons. These electrons form pro The pulse frequency is measured by known electrical means and is in this way a measure of the number of ions entering the detector 13 per second and thus of the ion current.

Hhitl / cichnuniien

Claims (2)

Patent claims: 1. Apparatus for analyzing a surface layer by ion scattering containing Means for generating a primary, almost monoenergetic ion beam, its axis in an area adjoining the surface layer with the axis of an electrostatic analyzer coincides, which contains two almost cylindrical, hollow, coaxial electrodes, an almost ring-shaped and with the analyzer coaxial aperture aperture for the passage of ions, which is arranged so that ions are transmitted through a Angles of more than 90 ° to the axis of the primary ion beam are scattered, and a detector to Determination of the kinetic energy of the ions scattered and transmitted by the diaphragm, characterized in that the means (14-18) zl'ttj generation of the primary ion beam (1) are arranged such that the axis of the latter (1) in the entire analyzer area with the Axis of the electrostatic analyzer (3) coincides and that the detector (13) almost is ring-shaped and coaxial with the analyzer (3) and encloses the primary ion beam (1). 2. Device according spoke 1, characterized in that the mean angle of dispersion of the detected ions has a value between 137 and 150 °.