DE3845007C2 - Ion beam generator for semiconductor processing - Google Patents

Abstract

The generator has a supply system for atoms of material, the supply system feeding a particle beam with the atoms to preset region. Laser beams are supplied to the region by a laser generator, in order to energise the material atoms into a Rydberg state. The atoms in the latter state are exposed to a preset electric field from a semiconductor assembly. Thus the material atoms are ionised and guided into a preset direction. The field generating assembly pref. comprises a substrate with an oppositely located electrode, supplied by a preset potential from a current supply. Thus generating the required electric field between the electrode and substrate.

Description

The invention relates to a system for producing thin layers on a substrate by means of an ion beam gene rators according to the preamble of claim 1 or 2.

Ion beam systems for epitaxial growth with ion beam Generators are for example from JP-OS 60-137012 or DE 35 35 062 A1, which describes a generic system, known. Such a known system has an ion source and a suction electrode. In addition, the use a mass analyzer known to extract special ions.

In an evaporator located in a place under the exit side a braking system to reduce the speed of the Ions is arranged, substances are vaporized, their atoms be prepared for thin layer formation. A substrate on which a thin layer is to be formed with such a system, is on the output side of the brake system.

In a method of growing a GaAs compound semiconductor thin film on a substrate, for example, gallium vapor is supplied to the surface of the substrate from the evaporator to deposit and deposit gallium atoms on the substrate. At the same time, a suction voltage of about 25 kV is applied between a suction electrode and the ion source, so that an ion beam which contains As ⁺ ions is extracted from the ion source.

The ion beam extracted in this way is introduced into the mass analyzer. The As ⁺ beam then enters a resolution aperture. The jet is then braked by the braking system already mentioned. The As ⁺ beam is implanted in the substrate after it has a low energy state of about 100 eV or less.

If an ion beam generator of the type described above is used in an ion beam system for epitaxial growth, a very high voltage of approximately 25 kV must be applied between the ion source and the suction electrode so that an As ⁺ beam can be obtained with the desired electrical current. The ion beam sucked off by the suction voltage of about 25 kV has a high jet speed. In order to prevent the beam from expanding due to a space conduction effect in the beam path from the mass analyzer to the substrate, the electrical potential of the ion source is kept at 100 V and the mass analyzer and the braking system are at a low negative potential.

Furthermore, the jet speed should be low when the jet hits the substrate. Accordingly, the speed of the beam must be reduced so that the incident energy of the ion beam onto the substrate is less than 300 eV or preferably less than 100 eV. This is because when the As ⁺ beam is supplied to the substrate at an impact speed corresponding to an energy of more than 300 eV, the amount of GaAs sputtered by the As ⁺ ions is equal to or larger than the amount of GaAs that adheres to the substrate so that layer growth is prevented. The ion beam must therefore be braked immediately before it reaches the substrate.

In a known system for producing thin layers however, an electrode in the braking system should be in the rays be long because the beam is in a large area must be braked. As a result, the raster scan of the ion beam supplied to the substrate is not good. Even if the scanning can be controlled, it is difficult to evenly distribute the layer thickness achieve and it is almost impossible to get a thin film only in  selectively a predetermined local area of the substrate to grow up.

It is therefore an object of the invention to provide a known system for Production of thin layers on a substrate by means of To improve ion beam generator so that on a braking system can largely be dispensed with and at the same time the There is a possibility of defined thin-film structures to obtain on the substrate mask-free in a reproducible manner.

The object of the invention is achieved with a Object according to claim 1 or 2, wherein the subclaims expedient refinements and developments include.

The invention will now be described with reference to the description of Embodiments and with the help of figures are explained in more detail.

Here show:

Figures 1 and 2 cross sections of the general structure or to a first embodiment of a system with an ion beam generator.

Fig. 3 is a timing chart for explaining an example of the supply timing of the laser and the system timing of the elec trical field for the embodiment of FIG. 1 or 2;

Fig. 4 is a timing chart for explaining another example of the supply timing of the laser and the plant timing of the electric field in the embodiment of Fig. 1 or 2;

Figs. 5 to 8 are perspective views of further illustrating embodiments of the invention;

Fig. 9 to 12 cross sections to explain additional embodiments of a system according to the inven tion; and

Fig. 13 to 18 are perspective views of further embodiments of a system for the production of thin films.

Fig. 1 shows a cross section of the basic structure of a system for producing thin films with a Rydberg ion beam generator. As can be seen from FIG. 1, the system serves to produce a thin layer on the lower surface of a substrate 7 . An electrode 8 in the form of a flat plate is provided parallel to the substrate 7 in such a way that it lies opposite the substrate 7 . Evaporators 6 a and 6 b as a device for the supply of material atoms are laid out so that they evaporate atoms of the corresponding substances that are required for thin film formation in order to supply the evaporated material atoms to the space between the substrate 7 and the electrode 8 .

In this system, two laser oscillators 10 a and 10 b are provided. The laser oscillator 10 a generates a laser beam 9 a with the wavelength λ ₁ to excite the material atoms of a certain type from a basic state to a transition state, while the other laser oscillator 10 b generates a laser beam 9 b with a wavelength λ _{2 to} overlap material atoms to stimulate the current state into a Rydberg state. The electrode 8 is connected to a high-voltage pulse generator 11 which applies a high-voltage pulse to the electrode 8 in order to generate a pulsed electric field E in the space between the electrode 8 and the substrate 7 .

In a system for thin-film production, in the atomic beam supplied by the evaporators 6 a and 6 b, only material atoms of a certain type, the excitation energy of which corresponds to the excitation wavelength of the lasers 9 a and 9 b, are selectively changed from the ground state to the Rydberg state excited. Then, the excited material atoms are ionized by the electric field E applied to the space between the electrode 8 and the substrate 7 so that they are supplied to the surface of the substrate 7 as an ion beam to form a thin film on the substrate 7 .

In a case where, for example, a compound semiconductor layer of indium phosphide (InP) is to be formed on the substrate 7 , phosphorus (P) and indium (In) are generated in the respective evaporators 6 a and 6 b, respectively. By heating the evaporators 6 a and 6 b, atomic beams are generated from phosphorus and indium, which leads to the space between the substrate 7 and the electrode 8 .

When indium is ionized for a method of epitaxially growing an ion beam, the respective wavelengths λ ₁ and λ _{2 of} the laser beams 9 a and 9 b are 410.3 nm, corresponding to the transition wavelength from the 5p state to the 6s state, and on set about 448.6 nm, corresponding to the transition wavelength from the 6s state to the 25p state.

The electric field E , which is applied to the space between the substrate 7 and the electrode 8 , is set to a field strength of about 1 kV / cm, and the lasers 9 a and 9 b are focused on a location which is from the substrate 7 is spaced about 1 mm.

Under these conditions collides an in-beam with a jet velocity corresponding to a low energy of about 100 eV, with phosphorus atoms, which are supplied from the evaporator 6 a, or with an existing on the substrate 7 phosphor layer, so that on the substrate 7 InP is deposited. Accordingly, an InP thin film of high quality is gradually formed on the substrate 7 when the supply of the laser beams 9 a and 9 b and the application of the electric field E are repeated.

Although in the example described above, the thin film formed by the ionization of indium, the same thin film can also be produced by the Ioni sation of phosphorus with laser beams with a wavelength, which corresponds to the excitation wavelength of phosphorus. Dude natively both indium and phosphorus can also be ionized become.

The structure shown in FIG. 1 can also be used to produce a gallium arsenide (GaAs) thin film on the substrate 7 to change as a compound semiconductor layer, or construction without the Kon essential. In a case where Ga is to be ionized for epitaxial growth of the ion beam, the wavelength λ _{1 of} the laser beam 9 a is set to 403.3 nm, corresponding to the transition wavelength for the transition from the 4p state to the 5s state, and the wavelength λ _{2 of} the other laser beam 9 b is set to approximately 434 nm, corresponding to the transition wavelength from the 5s state to the 25p state. The other conditions are given in the same way as in the described production of the InP layer.

FIG. 2 shows a cross section of a first embodiment of a system for thin film production using a Rydberg ion beam generator. In this embodiment, a needle electrode 50 is used instead of the electrode 8 shown in FIG. 1. The needle electrode 50 is mounted on a Antriebsvorrich device 51 so that the electrode 50 can be moved to a desired position with it. Otherwise, the construction is constructed similarly to that in the system according to FIG. 1.

Using the needle electrode 50 , the electric field E , which is required for ionizing the material atoms, which are excited by the laser beams 9 a and 9 b in the Rydberg state, is concentrated on the tip part of the needle electrode 50 , so that the ionization region on one small area is limited. As a result, the ion beam is supplied only to the area on the substrate 7 opposite to the needle electrode 50 , so that the thin film can be formed in a predetermined area on the substrate 7 by moving the needle electrode 50 to the position corresponding to the predetermined one Area corresponds, specifically with the drive device 51 .

For example, an indium phosphide (InP) thin film can be produced as a compound semiconductor layer on the substrate 7 , in fact under almost the same conditions as in the embodiment according to FIG. 1. A necessary condition for setting the electric field strength E to approximately 1 kV / cm However, differs from the operating conditions of the system according to FIG. 1. For example, in the second embodiment, the tip part of the needle electrode 50 is formed so that it has a radius of curvature of 50 μm, the distance between the substrate 7 and the needle electrode 50 being 2 mm is set, and a voltage of 30 V is applied to the needle electrode 50 so that the electric field strength near the tip part of the needle electrode 50 is set to about 1 kV / cm.

The other operating conditions are given in the same way as in the embodiment according to FIG. 1. Under the mentioned operating conditions, the irradiation with the laser beams 9 a and 9 b and the application of the electric field E are repeated while the needle electrode 50 is driven by the drive device 51 is moved to the position opposite to a desired area of the substrate 7 on which the InP thin film is to be formed, so that a high quality InP thin film having a desired shape is formed on the substrate 7 .

Although pulsed lasers are used as the laser 9 a and 9 b, the material atoms in the arrangements of FIG. 1 or FIG. 2 from the ground state through the transition Anregungszu levels in the Rydberg state to excite the thin film can also be obtained if a continuously oscillating laser, the energy of which is relatively small, is used as laser 9 a, since the required laser energy density for the optical excitation of almost all material atoms from the ground state to the transition excitation state is only a few W / cm ² . In this case, the switch-on time control of the lasers 9 a and 9 b, the excitation wavelengths of which are λ ₁ and l ₂ , and the system time control of the electric field E can be predetermined as shown in FIG. 3.

Since the excitation cross section of the material atoms in the photo excitation from the transition excitation state to the Rydberg state is between 10 ^-18 cm ² and 10 ^-14 cm ² and the life time in the Rydberg state is longer than a few 10 µs, almost all Material atoms from the laser 9 b from the transition excitation state into the Rydberg state are optically excited, the laser 9 b being provided in the form of a continuously operating laser with relatively low energy. In this case, the switch-on times of the lasers 9 a and 9 b, the excitation wavelengths of which are λ ₁ and λ ₂ , and the application time of the electric field E can be predetermined, as shown in FIG .

Although two laser 9 a and 9 b λ with wavelengths ₁ and λ ₂ ver 1 applies to the material atoms in the arrangements shown in Fig. And Fig. 2 to stimulate state from the ground state to the Rydberg, even a single laser can with a shorter wavelength than that of the laser 9 used a and 9 b, to excite the material atoms from the ground state to the Rydberg state; alternatively, three or more lasers, the respective wavelengths of which differ from one another, can be used to excite the material atoms in the ground state via a large number of transition excitation states into the Rydberg state.

In the arrangements according to FIGS. 1 and 2, the laser beams can 9 a and 9 b, which are fed parallel to the surface of the substrate 7, periodically in the direction perpendicular to the drawing plane of FIG. 1 and FIG. 2 are deflected, with Mirrors or optical dispersion elements, such as. B. prisms, with the respective deflections being synchronized with one another in such a way that the laser beams 9 a and 9 b are focused on a common location which is moved periodically according to the periodic deflections. In such a case, the space irradiated with the laser beam moves within a plane opposite to the substrate 7 , the distance between the space irradiated with the laser and the substrate 7 being maintained, so that a thin layer of greater uniform thickness on the substrate 7 is formed.

If the focused laser location is restricted to be in a given space between the substrate 7 and the electrodes 8 , the thin film can be formed only on a part of the substrate 7 opposite to the given space. Thus, a thin film having a desired pattern can be formed on the substrate 7 by moving the focused laser location along the pattern.

Fig. 5 shows an example in which the lasers 9 a and 9 b are focused with lens systems 16 a and 16 b, respectively, and a thin layer is formed on a certain small area on the substrate 7 . In the system for manufacturing a thin film according to Fig. 5, the thin film is formed only on a certain area, which faces a space to which both laser 9 a and 9 b are focused.

FIG. 6 shows another example, in which a needle electrode 50 , which can be moved with a drive device 51 , is provided instead of the electrode 8 in the form of a flat plate according to FIG. 5. If the common focusing location of the lasers 9 a and 9 b is moved in the same way as in the arrangement according to FIG. 5 with periodic deflections in synchronism with the movement of the needle electrode 50 , a thin-film pattern is created according to the location of the focusing position on the substrate 7 high accuracy trained.

Fig. 7 shows a further embodiment, wherein the laser beams 9 a and 9 b in their cross section in the vertical direction in Fig. 7 with lens systems 17 a and 17 b, z. B. Zylin derlinsen to be expanded. The respective light paths of the laser beams 9 a and 9 b have a flat shape parallel to the surface of the substrate 7 and overlap one another in the region which lies opposite the surface of the substrate 7 . In the embodiment according to FIG. 7, a thin layer of uniform thickness can be formed on the substrate 7 , even if the surface area of the substrate 7 is large. The energy or the speed of the ion beam supplied to the substrate 7 can be easily adjusted by changing the distance X _L between the laser focusing location and the substrate 7 so that a desired thin film can be easily manufactured.

FIG. 8 shows a further example in which a needle electrode 50 is provided instead of a plate-shaped electrode 8 structured according to the invention according to FIG. 7. In the embodiment according to FIG. 8, both advantages of the embodiments according to FIG. 6 and FIG. 7 can be obtained. If the cross sections of the laser beams, which are sheet-like in shape, are made thin, the energy dispersion of the ion beam can be suppressed, so that the thin film can be produced under optimal conditions.

FIGS. 9 and 10 schematically show seventh and eighth imple mentation of a system for the production of thin films with an ion beam generator according to the invention. These embodiments are constructed in such a way that a magnetic field B is applied to the space between the substrate 7 and the electrode 8 or 50 parallel to the electrical field E in order to suppress the expansion of the ion beam traveling to the substrate 7 . The magnetic field B can be generated with a coil which is provided around a space which encloses the substrate 7 and the electrodes 8 and 50 , the electric current supplied to the coil being adjusted; alternatively, a permanent magnet can be provided in a predetermined position. The magnetic field B and the electric field E need not be parallel to each other, although it is preferred that they are parallel to each other.

FIGS. 11 and 12 show a general schematic diagram and a cross section of another embodiment of systems for thin film preparation with an ion beam generator for explaining the material supply atom. In this embodiment, the structure is such that the material atoms which are used to produce a thin layer are supplied in the space between the substrate 7 and the electrode 8 or 50 as a molecular beam which contains the material atoms. A gas bottle 18 is filled with a molecular gas which is supplied to the space between the substrate 7 and the electrode 8 or 50 as a molecular beam, specifically through a conduit 19 which is connected to the gas bottle 18 . When both an atomic beam and a molecular beam are used together to supply the material atoms to the space between the substrate 7 and the electrodes 8 and 50 , either the material atoms in the atomic beam or those in the molecular beam are ionized.

Further, if the flow or jet direction of the atomic beam or the molecular beam is set to be parallel to the surface of the substrate 7 , most of the impurities contained in the atomic or molecular beam are prevented from entering the substrate 7 thin film to be trained, and the quality of the thin film becomes particularly high.

FIG. 13 shows a perspective illustration of a further embodiment of a system for thin-film production using an ion beam generator according to the invention. In this embodiment, a patterned electrode 20 having a conductive portion, the shape of which is determined to correspond to the shape of a part of the substrate 7 on which a thin film is to be formed, is used in place of the electrode 8 formed as a flat plate in FIG. 1 . Otherwise, the structure is the same as in the system according to FIG. 1.

By using the patterned electrode 20 , the electric field E , which is required to ionize the material atoms, which are excited by the laser beams 9 a and 9 b in the Rydberg state, only to the space between the patterned electrode 20 and the substrate 7 created. Accordingly, the ion beam is supplied only to the area on the substrate (programmed area for producing the thin film) which is opposite to the conductive area of the electrode 20 , so that the thin film is formed on a predetermined area on the substrate 7 in accordance with that Pattern of the lead area.

The patterned electrode 20 can only be formed by the conductive area according to FIG. 13, alternatively it can be constructed in such a way that the patterned conductive area is integrated with an insulating layer, not shown. In the latter case, the electrode 20 can be manufactured by selectively etching a conductive layer provided on the insulating layer by photolithography, or by forming a patterned conductive layer on the insulating layer.

FIG. 14 shows a perspective illustration of a further embodiment in which an electrode 21 is used instead of the electrode 20 according to FIG. 13; otherwise, the structure is the same as in Fig. 13. A part of the electrode 21 which is opposed to the substrate 7 is formed irregularly, such that the one area which is opposed to a surface of the substrate 7 on which a thin film is formed is located relatively close to the substrate 7 , while the other region, which is opposite to that surface of the substrate 7 on which no thin layer is to be formed, can be relatively far away from the substrate 7 .

If a pulse voltage generated by the high-voltage pulse generator 11 is applied to the electrode 21 in order to apply a pulse-shaped electric field E in the space between the electrode 21 and the substrate 7 , the electric field E is in the space in front of a convex part 21 a stronger than in the room in front of a concave part 21 b. The distance between the electrode 21 and the substrate 7 is determined so that the electric field E only in the space in front of the convex part 21 a of the electrode 21 has a field strength above the threshold value required for the ionization of the material atoms in the Rydberg state is.

Under the conditions mentioned, only the material atoms, which are in the space between the substrate 7 and the convex part 21 a, were ionized with high efficiency, and the ion beam generated in this way is supplied in an accurate form only to the region of the substrate 7 on which a thin layer is to be formed so that the thin layer is formed exactly on the desired area of the substrate 7. ?

The applicant has carried out an experiment for the production of an InP thin film, the wavelengths of the laser beams 9 a and 9 b being set to values of 410.3 nm and 448.6 nm; the laser beams 9 a and 9 b were directed to a position which was about 1 mm away from the substrate 7 ; the distances of the substrate from the convex part 21 a and from the concave part 21 b were 5 mm and 10 mm, respectively; a voltage of 500 V was applied to the electrode 21 in order to generate the desired electric field E.

With such an experiment, it was confirmed that only the In atoms in the space between the substrate 7 and the convex portion 21 a were ionized, and an In ion beam of about 100 eV was supplied to the substrate 7 , so that an InP thin film was formed only on the area of the substrate 7 which was opposite to the convex part 21 .

Fig. 15 shows in a schematic diagram the same structure as Fig. 1, with the difference that a different electrode 22 is provided between the substrate 7 and the electrode 8 to control the speed of the ion beam. The electrode 22 is a sieve electrode with many small holes so that the ion beam can pass through it. A current source 23 is provided to apply a bias voltage between the screen electrode 22 and the substrate 7 . The atomic beam, which is supplied by the evaporators 6 a and 6 b, and the laser beams 9 a and 9 b are supplied to the space between the electrodes 8 and 22 . Otherwise, the structure of the system is the same as in the arrangement according to FIG. 1.

The laser beams 9 a and 9 b are focused in the space between the electrodes 8 and 22 , and an electric field E is applied to the space between the substrate 7 and the electrode 8 . Only the material atoms to be used for the production of the thin film are selectively ionized at the laser focusing location with high efficiency and accelerated by the electric field E to give an ion beam which is fed to the sieve electrode 22 . The ion beam is accelerated or braked by the electric field that exists between the sieve electrode 22 and the substrate 7 , so that it is supplied to the substrate 7 as an ion beam with a uniform energy of less than 100 eV, so that a desired thin film in a precise form is formed on the substrate 7 .

An experiment was carried out under the following conditions: the screen electrode 22 was placed at a position 1 mm from the substrate 7 , the laser beams 9 a and 9 b were focused on a spot with a diameter of about 1 mm, which was a distance of 5 mm from the substrate 7 ; an electric field with a field strength of 5 kV / cm was applied to the space between the electrodes 8 and 22 . In this experiment, it was observed that the energy of the ion beam was about 2 keV when the bias of the electrode 22 was 0 V, and the energy of the ion beam was about 200 eV when the bias was -1500 V. The experiment confirmed that the energy of the ion beam is easily adjustable by changing the bias.

Another experiment for producing an InP thin film on the substrate 7 was carried out. The respective wavelengths of the laser beams 9 a and 9 b were set to 410.3 nm and 448.6 nm, respectively; the laser beams 9 a and 9 b were supplied to a position which was spaced from the bias electrode 22 by about 5 mm. The electric field strength E was set at about 1 kV / cm, and a DC bias of -450 V was applied to the screen electrode 22 . Under the above conditions, an In ion beam with an energy of about 500 eV was generated, which was supplied to the substrate 7 , so that a high quality InP thin film was formed.

FIG. 16 shows an additional embodiment in which a needle electrode 50 was used instead of the flat electrode 8 according to FIG. 15. In order to move the needle electrode 50 into a desired position, a drive device 51 is connected to the needle electrode 50 . Otherwise, the construction is the same as that of the system shown in FIG. 15. In this embodiment shown in FIG. 16, the speed of the ion beam supplied to the substrate 7 is precisely controlled by the function of the screen electrode 22 , and it may be one Thin film with a desired pattern can be formed on the substrate 7 in an exact manner by moving the needle electrode 50 with the drive device 51 .

FIGS. 17 and 18 illustrate further implementation form. The constructions of these embodiments are substantially the same as in the system shown in FIG. 15, except that the special electrode 20 shown in FIG. 13 or the special electrode 21 shown in FIG. 14 is used in place of the electrode 8 shown in FIG. 15 . In the case of this off according EMBODIMENTS FIGS. 17 and 18, the speed of the ion beam is supplied to the substrate 7, precisely controlled by the function of the sieve 22, and it may be a thin film in an accurate shape only on one particular area of the substrate 7 formed by using the function of the special electrodes 20 and 21 .

An experiment was carried out with the system according to FIG. 17 under the following conditions: The wavelengths of the laser beams 9 a and 9 b were 410.3 nm and 448.6 nm; the laser beams 9 a and 9 b were fed to a position at a distance of approximately 5 mm from the biasing electrode 22 , the electric field strength E being approximately 1 kV / cm. A DC bias of -450 V was applied to the (pre-voltage) sieve electrode 22 . In this experiment, an In-ion beam with an energy of about 50 eV was generated, which was supplied only to the area on the substrate 7 opposite to the conductive area of the electrode 20 , and an InP thin film of high quality was formed in an exact form formed on the desired area of the substrate 7 .

An experiment with the following conditions was also carried out with the system according to FIG. 18: The wavelengths of the laser beams 9 a and 9 b were the same as in the experiment with the system according to FIG. 17, the distance between the projecting or convex part 21 a of the electrode 21 and the substrate 7 was 5 mm, and the distance between the concave or retracted part 21 b of the electrode 21 and the substrate 7 was 10 mm; a voltage of 500 V was applied to the electrode 21 , while a DC bias voltage of -150 V was applied to the sieve electrode 22 . As a result, only the InP atoms in the space in front of the convex part 21 a were ionized and converted into an ion beam with an energy of about 50 eV, which was supplied to the substrate 7 ; an InP thin film was formed in an exact manner only on the area of the substrate 7 which was opposite the convex part 21 a.

Claims (14)

1. System for the production of thin layers on a substrate by means of an ion beam generator, comprising a supply device ( 6 ; 6 a; 6 b) for material atoms, which supplies a particle beam ( 12 ) with the material atoms to a predetermined area, a laser generator ( 10 ; 10 a; 10 b), which supplies the area with laser beams ( 9 ; 9 a; 9 b) in order to excite the material atoms into a Rydberg state, a device with electrodes ( 20 ; 21 ;) for applying a predetermined electrical field ( e) to the located in the Rydberg state material atoms (13), so that this material atoms (13) is ionized and the ions are directed in a predetermined direction, wherein one of the electrodes (20; 21) facing the substrate (7), a high-voltage source ( 11 ) is connected to this electrode ( 20 ; 21 ) and the ionized material atoms ( 13 ) are moved along the elec trical field (E) to the substrate ( 7 ), characterized in that
the high voltage source provides a pulse voltage and the surface of the electrode ( 20 ) has a shape which corresponds to the pattern of the thin layer to be applied to the substrate ( 7 ), or that
the electrode ( 21 ) has a surface opposite the substrate ( 7 ), which is unevenly shaped and has a first region ( 21 a) closer to the substrate ( 7 ) and a second region ( 21 b) further away from the substrate ( 7 ), in which
the distance between the electrode ( 21 ) and the substrate ( 7 ) is determined so that the electric field ( E ) has a field strength above the threshold only in the space in front of the closer part ( 21 a) of the electrode ( 21 ) is required for the ionization of the material atoms in the Rydberg state. 2. System for the production of thin layers on a substrate by means of an ion beam generator, comprising a supply device ( 6 ; 6 a; 6 b) for material atoms which supplies a partial beam ( 12 ) with the material atoms to a predetermined area, a laser generator ( 10 ; 10 a; 10 b), which supplies the area with laser beams ( 9 ; 9 a; 9 b) in order to excite the material atoms in a Rydberg state, a device with electrodes ( 8 ; 50 ) for applying a predetermined electrical field ( e) to the located in the Rydberg state material atoms (13), so that this material atoms (13) is ionized and the ions are directed in a predetermined direction, wherein one of the electrodes (8; 50) facing the substrate (7), a high-voltage source ( 11 ) is connected to this electrode ( 8 ; 50 ) and the ionized material atoms ( 13 ) are moved along the electric field (E) to the substrate ( 7 ), characterized in that
the high-voltage source provides a pulse voltage and the laser beams are focused on a laser location in the space between the substrate ( 7 ) and the electrode ( 8 ; 50 )
and that the laser location is moved according to the pattern of the thin film to be deposited on the substrate, wherein
when using a needle electrode ( 50 ) this is moved synchronously with the laser location. 3. System according to claim 2, characterized by a drive device ( 51 ) to move the electrode ( 50 ) in a direction parallel to the surface of the substrate ( 7 ). 4. System according to claim 1, characterized in that
the laser generator ( 10 a, 10 b) generates two laser beams ( 9 a, 9 b) with corresponding, different wavelengths
and that the ion beam generator has a device ( 17 a, 17 b) to expand the two laser beams ( 9 a, 9 b) two-dimensionally, so that the corresponding light paths of the two laser beams ( 9 a, 9 b) have a flat shape parallel to the surface of the substrate ( 7 ) and overlap in an area which lies opposite the surface of the substrate ( 7 ). 5. System according to any one of the preceding claims, characterized in that
the material atoms ( 12 ) are gallium atoms,
that a laser beam ( 9 a) with a wavelength of 403.3 nm is supplied to the gallium atoms in order to excite them from a ground state to a transition state, and
that another laser beam ( 9 b) with a wavelength of about 434 nm is fed to the gallium atoms in order to excite them from the transition state to the Rydberg state. 6. System according to any one of claims 1-4, characterized in that
the material atoms ( 12 ) are indium atoms,
that a laser beam ( 9 a) with a wavelength of 410.3 nm is fed to the indium atoms in order to excite them from a ground state to a transition state, and
that another laser beam ( 9 b) with a wavelength of about 448.6 nm is fed to the indium atoms in order to excite them from the transition state to the Rydberg state. 7. System according to any one of the preceding claims, characterized in that the distance between a location to which the laser beams ( 9 , 9 a, 9 b) are supplied, and the surface of the substrate ( 7 ) is predetermined so that the value of Product from the distance and the electric field strength (E) has a value of 300 V or less. 8. System according to any one of the preceding claims, characterized in that the supply device ( 6 , 6 a, 6 b) for material atoms supplies the particle beam ( 12 ) in a direction substantially parallel to the surface of the substrate ( 7 ). 9. System according to any one of the preceding claims, characterized in that
the device for applying the electric field (E) also a sieve electrode ( 22 ), which is seen between the substrate ( 7 ) and the electrode ( 8 , 20 , 21 , 50 ) and is constructed so that an ion beam ( 14 ) it can happen and
a current source ( 23 ) to apply an electrical control potential to the sieve electrode ( 22 ) to control the speed of the ion beam. 10. System according to claim 9, characterized in that the particle beam containing the material atoms ( 12 ) a space between the electrode ( 8 , 20 , 21 , 50 ) and the sieve electrode ( 22 ) is supplied and that the direction of the elec trical field ( E) is predetermined such that the material atoms that are ionized are guided from the electrode ( 8 , 20 , 21 , 50 ) to the substrate ( 7 ). 11. System according to one of the preceding claims, characterized in that a device for applying a magnetic field (B) in the predetermined range is provided. 12. System according to any one of the preceding claims, characterized in that at least one of the laser generators ( 10 ; 10 a, 10 b) is a pulse laser. 13. System according to claim 12, characterized in that the electric field (E) is applied to the space between the substrate ( 7 ) and the electrode ( 8 , 20 , 21 , 50 ) after the pulsed laser beam the material atoms ( 12 ) has been supplied and before the life of the material atoms ( 12 ) in the Rydberg state is over, in which they have been excited with the pulsed laser beam. 14. System according to any one of the preceding claims, characterized in that at least one of the laser generators ( 10 ; 10 a, 10 b) is a continuously oscillating laser and the electrical field (E) is a periodic pulse field.