EP0276731A2 - Method for electron beam guidance with energy selection, and electron spectrometer - Google Patents

Abstract

High energy resolution with a high electron current at the sample or at the detector is obtained by electron beam guidance with focusing energy selection, in particular in an electron spectrometer with emission system and at least one energy dispersive system with different focusing in two mutually perpendicular directions, by means of an energy dispersive system. or upstream non-circularly symmetrical lens system (4-10), which corrects the different focusing of the electrons in the two mutually perpendicular directions in such a way that either the virtual or real input aperture of the energy-dispersive system on a given image plane outside the energy-dispersive system or an object outside of the energy-dispersive system is shown on the virtual or real output panel of the same.

Description

The invention relates to a method for electron beam guidance with focussing energy selection in an energy-dispersive system with different focussing in two mutually perpendicular directions (especially in the energy selection direction and perpendicular to it with systems focusing only in one plane), and to electron spectrometers with at least one energy-dispersive system with such a beam guidance.

Bundled electrons with a certain energy are used for the treatment and investigation of surfaces and gases. For a focusing energy selection, energy-dispersive systems are known which are used either individually as analyzers or as monochromators or in combination of analyzer and monochromator as so-called electron impact spectrometers.

Energy dispersive systems as analyzers are used for example in UV or X-ray photoelectron spectroscopy (also known under the name ESCA) and in Auger spectroscopy. Here, electrons emitted by the sample are transmitted through analyzes the analyzer for its kinetic energy. A lens system located between the sample and the analyzer takes care of the beam transport, the adaptation of the electron energy to the transmission energy of the analyzer and the necessary enlargement or reduction of the image of the imaged area of the sample to adapt to the input slot of the analyzer.

Energy dispersive systems are also used to produce monochromatic electron beams, such as in inverse photoemission spectroscopy. Similar to the analyzer described above, lens systems are used between the monochromator and the sample for beam transport, for adjusting the energy and the image size.

In an electron impact spectrometer, the electrons emitted by a cathode are monochromatized in one or more monochromators and directed onto a sample through a lens system, the energy of the electrons on the sample usually being different from the energy in the monochromators. The electrons hitting the sample are scattered by it and suffer characteristic energy losses, for example through excitation of oscillation quanta. The scattered electrons are directed through a lens system onto the entrance slit of one or more energy-dispersive elements conducted, which analyze the scattered electrons with regard to their energy distribution, and detected in a detector. Electron spectrometers of this type are used in particular for vibration spectroscopy and for the investigation of electronic losses on solid surfaces and are manufactured by a number of companies.

In an electron impact spectrometer, the maximum achievable intensity of the beam falling on the sample and thus also the intensity of the useful signal generated by it is fundamentally limited by the space charge in the monochromator. Theoretical calculations show (H. Ibach, DL Mills, Electron Energy Loss Spectroscopy and Surface Vibrations, Academic Press, New York, 1982, p. 16 ff.) That the strength of the monochromatic current depends on the energy width of the electron beam transmitted through the monochromator and can only be influenced to a relatively modest extent by design parameters of the system.

Favorable conditions with regard to the space charge result in particular when using one or more cylindrical capacitors with slots as the inlet or outlet diaphragm. Focusing of the electrons from the entrance to the exit aperture and energy selection take place only in the radial direction, while vertical there is neither focusing nor energy selection. The lack of focusing perpendicular to the radial plane (without the beam guidance according to the invention) has an adverse effect on the intensity of the useful signal. The same applies analogously to the analyzer if cylindrical capacitors are used there.

Attempts have been made (see EP-PS 0013003) to compensate for this known disadvantage of cylindrical capacitors in that the electrons emitted by the cathode are focused in the radial plane by a suitable lens system on the entrance slit of the monochromator, while perpendicular to this by an appropriate design of the The cathode system and the lens system between the monochromator and the sample and between the sample and the analyzer are focused on the detector in an approximately parallel beam path without any further intermediate focus. Compared to a free, non-focusing beam spread, this beam guidance offers an improvement.

An analog type of focusing is described in U.S. Patent 4,559,449.

However, closer examination shows that a number of crucial disadvantages remain. So the angle of the beam reaching the detector perpendicular to the radial plane is small, which means according to the principles of optics, the intensity remains small. Furthermore, perpendicular to the radial plane, the beam path on the sample is almost parallel.

This means that only a small solid angle of the scattered electrons is detected. In addition, the described type of beam guidance is susceptible to malfunctions, such as are unavoidable at the frequently used low energies due to inhomogeneities in the work functions.

The invention is therefore based on the object of providing such a beam guide with focusing energy selection or an electron spectrometer, by means of which a high energy resolution with a high electron current is achieved on the sample or on the detector.

To achieve this object, the inventive method of the type mentioned is characterized in that the different focusing of the electrons in the two mutually perpendicular directions is corrected by a non-circularly symmetrical lens system connected downstream or upstream of the energy-dispersive system in such a way that either the virtual or the real one Input aperture of the energy dispersive system on a given image level outside of the energy dispersive System or an object outside the energy-dispersive system on the virtual or real output aperture of the same is mapped.

The lens systems to be used for this purpose described with different focusing in two mutually perpendicular directions are designed or dimensioned in consideration of the focus specification and the electron trajectories in the energy-dispersive system. In a special embodiment of the invention, rectangular lens cross-sectional profiles can be used, in which the height and width are matched to one another in such a way that the described image occurs in cooperation with the different focusing of the electrons in the two mutually perpendicular directions within the energy-dispersive system. When using cylindrical capacitors as energy-dispersive systems, the symmetry axes of the rectangular profile must then be parallel or perpendicular to the radial plane. The required height and width of the lens cross-sectional profiles are calculated by solving the Laplace equation in three dimensions and calculating the electron orbits in three dimensions in the manner known to the person skilled in the art.

For the correction of image errors, in particular that important for the imaging of a slot Astigmatism error, it has been shown that it is advisable to deviate from the rectangular shape with one or more lens elements and to provide lens cross-sectional profiles in which the clear width along an axis of symmetry has a trapezoidal or stepped or curved taper, for example.

Devices with beam guidance according to the invention include electron monochromators with a subsequent corrective lens system between the monochromator and sample, analyzers with an upstream corrective lens system between the sample and analyzer, and electron impact spectrometers with such a lens system between the monochromator and sample and / or between the sample and analyzer. In the following, the invention will be explained primarily on the basis of an electron impact spectrometer constructed symmetrically with respect to the monochromator and analyzer. Since an electron impact spectrometer, as described, consists of a monochromator part with a downstream lens system and an analyzer part with a preceding lens system, the invention can, however, also be used separately for the monochromator with a downstream lens system and the analyzer with an upstream lens system for the various applications.

The different focus between monochromator and sample or sample and Analyzer distinguishes the arrangement according to the invention from the spectrometer according to US Pat. No. 4,559,449, in which no different focusing is provided in both directions at this point, but only a separation of the lenses for beam deflection.

Instead of cylinder capacitors as energy-dispersive systems in the monochromator and / or analyzer, plate capacitors can also be used, which also focus only in one plane. It is also possible to use energy-dispersive systems which have a different, in each case non-zero, focusing in two mutually perpendicular directions, in which case the lens system must be suitably adapted (selection of the height and width of the lens profiles) in such a way that the desired focusing occurs .

• Figur 1 ein Elektronenstoßspektrometer mit je zwei Monochromatoren und Analy­satoren.
• Figuren 2 und 3 Querschnittsprofile der Linsenelemente der in Figur 1 angedeuteten Linsen­systeme
• Figur 4 die Elektronenbahnen zwischen Austritts­spalt des Monochromators und der Probe (a) in der Radialebene und (b) senk­recht dazu, und
• Figur 5 ein Schaubild für den Verlauf des monochromatischen Stroms am Detektor in Abhängigkeit von der Energieauf­lösung mit und ohne erfindungsge­mäße Strahlführung.

The invention is explained in more detail below using an exemplary embodiment with reference to the attached drawings; it shows schematically:

• 1 shows an electron impact spectrometer, each with two monochromators and analyzers.
• Figures 2 and 3 cross-sectional profiles of the lens elements of the lens systems indicated in Figure 1
• 4 shows the electron paths between the exit gap of the monochromator and the sample (a) in the radial plane and (b) perpendicular thereto, and
• FIG. 5 shows a graph for the course of the monochromatic current at the detector as a function of the energy resolution with and without the beam guidance according to the invention.

The electron impact spectrometer shown in Figure 1 comprises a cathode system 1, two monochromators 2 and 3, each a lens system consisting of three elements 4, 5 and 6 or 8, 9 and 10 between the monochromators and the sample 7 and between the sample 7 and the Analyzers 11 and 12, two analyzers 11 and 12 and a detector 13. The two lens systems between the monochromator and the sample and between the sample and the analyzer are symmetrical to one another, so that the lens elements 4 and 10, 5 and 9 and 6 and 8 are identical to one another.

The cross-sectional profiles of these lens elements 4 to 6 (or 8 to 10) are shown in FIGS. 2 and 3: Of these, the lens element 4 is tapered in a trapezoidal or stepped manner and the elements 5 and 6 are designed in a rectangular shape.

The height and width of the clear profile of the lens elements 4, 5 and 6 are adjusted so that in the radial plane (= drawing plane in Figure 1) the exit slit of the monochrome tors is mapped onto the sample (Figure 4a), but perpendicular to it the entrance slit (Figure 4b), so that, in cooperation with the image in the radial plane through the cylindrical capacitors, an image of the entrance slit of the first monochromator on the sample is formed in both directions . For this mode of operation, it is essential that no lens elements exist between the first and second monochromator. Rather, the required imaging on the sample is achieved exclusively by the lens system 4 to 6 in cooperation with the monochromators. In the same way, the height and width of the profiles of the lens elements 8, 9 and 10 are coordinated so that in the radial plane the sample is imaged on the inlet slit of the first analyzer, perpendicularly the sample is imaged on the outlet slit of the last analyzer, so that a total of one image the sample is created at the exit slit of the second analyzer.

The monochromatic current achieved using the lens system according to the invention, measured on the detector, as a function of the resolution is shown in FIG. 5, curve a. In comparison, curve b shows analog values for a spectrometer which does not have the lens system according to the invention, but is otherwise identical in terms of monochromators and analyzers. The results refer to one Electron energy on the sample of 100 eV, while the energy of the electrons in the monochromators and analyzers (depending on the resolution) is less than 1 eV.

Claims (9)

1. Method for electron beam guidance with focusing energy selection in an energy dispersive system with different focusing in two mutually perpendicular directions,
characterized,
that the different focusing of the electrons in the two mutually perpendicular directions is corrected by a non-circular-symmetrical lens system downstream or upstream of the energy-dispersive system in such a way that either the virtual or real input aperture of the energy-dispersive system on a predetermined image plane outside the energy-dispersive system or a Object outside of the energy dispersive system is shown on the virtual or real output aperture of the same. 2. The method according to claim 1,
characterized,
that lens systems with a rectangular, in particular tapered rectangular cross-sectional profile of the lenses are used. 3. electron spectrometer with an emission system and with at least one energy-dispersive system with different focusing in two mutually perpendicular directions,
characterized by it
a lens system (4 - 6) downstream of an energy-dispersive system (2, 3) for energy selection in front of the sample (7) with a non-circular focusing that differs in the two mutually perpendicular directions, which together with the focusing properties of the energy-dispersive system form an image of the Virtual or real input aperture of the energy-dispersive system (2, 3) generated at the sample location and / or a lens system (8-10) upstream of an energy-dispersive system (11, 12) for energy selection behind a sample (7) with non-circular, in the two to each other vertical directions of different focus, which, in cooperation with the focusing properties of the energy-dispersive system, images the image at the sample location on a virtual or real output aperture of the energy-dispersive system (11, 12). 4. electron spectrometer according to claim 3,
characterized,
that the energy-dispersive system (2, 3) in front of the sample (7) and / or the energy-dispersive system (11, 12) behind the sample (7) focuses only in one direction. 5. electron spectrometer according to claim 3 or 4,
characterized,
that one or more clear lens cross-sectional profiles of the lens elements (4-6 or 8-10) have a non-circular shape. 6. electron spectrometer according to claim 5,
characterized,
that one or more clear lens cross-sectional profiles are rectangular. 7. electron spectrometer according to claim 5,
characterized,
that one or more clear cross-sectional profiles of the lens elements have a trapezoidal, step-shaped or curved taper along an axis. 8. electron spectrometer according to one of claims 3 to 7,
characterized,
that the energy-dispersive system (2, 3) for energy selection before the sample is formed by a first and an immediately following second monochromator. 9. electron spectrometer according to one of claims 3 to 8,
characterized,
that the energy dispersive systems are formed by cylindrical capacitors.

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