DE19600993A1 - Appts. for high rate anodic evapn. for substrate coating - Google Patents

Abstract

An appts. for anodic evapn. of material by vacuum arc discharge has: (a) an anodic crucible (5) positioned vertically above and on the axis (7) of a cathode (2); (b) an ignition electrode (8) which surrounds the cathode (2) in a sheath-like manner; and (c) a perforated screen (10) which is biased at the ignition electrode potential and which is provided between the ignition electrode (8) and the cathode (2) on the one hand and the crucible (5) on the other hand. Also claimed is a process for anodic evapn. in which anodic vacuum arc discharge is maintained by constantly biasing an ignition electrode (8) at a positive potential which is lower than the potential of an anodic crucible (5) and higher than the extinguishing potential of the discharge.

Description

The invention relates to an anodic device Material evaporation with a vacuum arc discharge according to the preamble of claim 1, and a method to use this device according to the preamble of Claim 6.

For coating substrates with the physical Layer deposition in vacuum (PVD - Physical Vapor Deposi tion), various processes are known. The older ones The coating material is processed by various methods ne types of energy supply evaporated in a vacuum. The corresponding evaporators generate an electrical new central particle beam. With the electron beam evaporator is above the molten vapor deposition material a cloud of ionized material particles formed, however, the rate of ionization of the plasma is due to the high acceleration voltage is not essential to the process. The vaporization material brought into the gaseous state can only absorb the equivalent energy level which corresponds to the surface temperature of the melt. Because in this state of aggregation does not require further energy consumption is possible, the material particles move in the evacu ized space only at the thermal speed that dependent on the particle mass and the particle temperature is away from the source. In the event of an impact on a surface the kinetic and condensation energies are released given. These conditions of layer deposition result only insufficient for many technical requirements appropriate adhesive strength and density of the deposited Layers.

In the more recent plasma-assisted physi layer deposition in vacuum become essential better conditions for an adherent layer deposition reached. The have been particularly effective Evaporator enforced using the coating material  a vacuum arc, also an electric arc or just vacuum vacuum called vaporizing. The vacuum arc discharge is the most powerful form of all discharges in a vacuum. The Vacuum arc discharge is formed depending on the Material properties of the cathode material, at approx. 20 volt terminal voltage off and goes out below 20 amps. The upper current limit is mainly through the performance of the power supply is limited.

The usual vacuum arc evaporator evaporates this Coating material from the cathode, i.e. H. the Coating material is on as a cathodic target a suitable cathode holder. Doing so the physical principle of vacuum arc discharge exploited. The vacuum arc always burns from one Cathode focal spot, also the base of the vacuum arc called discharge, starting towards the anode. Here is the Cathode focal point is always a very small point where the energy of the vacuum arc is extraordinarily strong bundles into the cathode and there a thermoem initiates mission while the other pole of vacuum light arc discharge has no such point, but over the entire area of the respective anode stretches. The anode can be a separate one in the vacuum chamber arranged electrode, but it can also Entire, grounded, vacuum chamber used as an anode will. These conditions make it practical only for evaporation of the cathode material in the cathode burner spot comes, forming a dense plasma and the vaporized material is highly ionic at the same time is settled. It mostly occurs on the large-area anode neither significant heating nor evaporation conditions or material dusting.

The main disadvantages of cathodically evaporating Vacuum arc evaporators are that the Ver damping of the cathodic target due to the high energy gie concentration explosive and constantly largely uncontrolled location on the target. It forms  no melt pool in the real sense, but that Micro-localized melt pool is created by the Ener casting concentration explosively flung away. The The result is small droplets of material, including droplets called, which is mostly disadvantageous on the sub deposit strat. Especially with very thin layers these droplets are very bothersome and often they match the layers for the intended technological purpose unusable. Technical measures to reduce the Droplet formation is usually very complex and not very effective sam.

Another disadvantage is the poor target use. Typically, the cathode torch migrates stain at high speed uncontrolled over the Target surface. Precautions must be taken be that the cathode focal point does not cause destruction leads to the target holder or the cathode base. All known measures to prevent destruction this type lead to the cathode focal spot middle area of the target more eroded than the outer area. The result is a target, which in the Middle quickly reached its erosion limit while the marginal area has evaporated only slightly. Expensive As a result, targets are often only used to 30 to 40%.

In order to counter these problems, ver is looking for ways to use instead of evaporation of the essentially the anodic cathodic material ordered material by means of a vacuum arc discharge can be evaporated. As already described, this must be done the area of the anode can be changed so that this is sufficiently heated by the electron bombardment. To the anode surface must be covered in this way nern that the energy concentration to evaporate is sufficient.

DE 34 13 891 C2 describes e.g. B. a method and a device in which the coating  material anodically by means of a vacuum arc discharge is evaporated. It is between a cathode and an arc ignited and the arc Discharge controlled so that the electrons in the Focal spots arise, get directly to the anode and the anode material or the special coating material which is arranged on the anode evaporates fen. The anodic plasma leads to one at the same time intensive ionization of the vaporized material. For It is creating sufficient energy concentration as an anode coating material wired formed, with only the tip of the wire as Anode works.

This essentially becomes the cathode mat rial and the anode material evaporates. This solution can very quickly lead to the formation of melting drops, that can drain in an undesirable manner.

DE 40 42 337 C1 specifies a solution in which that too evaporating coating material in one on anodic Potential crucible is held. The solution looks a separate arrangement of the cathode and the anode in front. The vacuum arc has an arcuate path and the electrons flow essentially counter to that Direction of evaporation of the evaporated material on this. This has an adverse effect on the energy potential and thus the speed of the vaporized and ionized Particles. The constructive solution requires one relatively large space requirement within the vacuum chamber.

The invention has for its object a device and a method for anodic material evaporation of the Specify the type mentioned above, which with low techni high evaporation rate, a high degree of ionization and high operation security guaranteed.

The invention solves the problem for the device  those mentioned in the characterizing part of claim 1 Features. Developments of the invention are in the sub claims 2 to 5 marked. The task for that The procedure is described in the defining part of the An mentioned 6 solved features. Further training of the Process inventions are in subclaims 7 to 9 featured.

Essential to the invention is in particular that with the front direction a separation of the vacuum arc discharge in two separate discharge branches with specific tasks and Properties is achieved.

The first branch of discharge, the primary base discharge, lies between the ignition electrode and the cathode. These Vacuum arc discharge in the first discharge branch fired first, is due to a special electri The circuit is self-sustaining and is characterized by the features a cathodic vacuum arc.

The second discharge branch lies between the cathode and the anodic crucible and is characterized by the features of a anodic vacuum arc. The discharge in this second discharge branch can because of the distance ignite the cathode and the anode to each other only if the primary base discharge burns in the first discharge branch. The anodic vacuum arc cannot ignite alone and burn. He needs for his training and offsetting always maintain the charge carriers of the cathodic vacuum arc in the first discharge branch.

The anodic vacuum arc is controlled in a separate circuit with control logic and one Circuit breakers in the manner of an IGBT power level (Insulated Gate Bipolar Transistor). So that's the front partial power regulation of the anodic arc in the Pulse operation possible according to claim 7. The primary Basic discharge is also maintained during the pulse breaks and ensures trouble-free reignition of the anodic vacuum arc after an extinction.  

Essential to the invention is also the compact and axial Arrangement of the cathode and the anode within one electrically and spatially delimited space in the vacuum chamber, whereby means are provided that the vacuum Steer the arc in such a way that a high proportion of the elec tron to the bottom of the anodic crucible Act.

Due to the spatial housing of the cathode, the igniter trode and the anode in a Faraday cage becomes the igniter ability of the device significantly improved. Already Relatively low density discharges between the Ignition electrode and the cathode are sufficient for that Formation of an independent discharge between the Cathode and the anode.

In the case of application of the method according to claim 7 the ignitability of the device is substantially stabilized. It is procedural for vacuum arc discharge pisch that the discharge goes out constantly and again and again must be reignited. This is due to the fact that the Cathode focal spot only a relatively limited discharge can transmit current. Will the discharge current higher, then the cathode focal spot divides into two or more single cathode burners burning simultaneously spot on. This in turn leads to the discharge falling off current below the minimum value and thus to extinguish the discharge. The procedure according to the invention ensures that between the ignition electrode and the cathode or the target always has a sufficient ignition potential is available, the pulsating voltage being the Ignitability improved to a special degree.

The compact arrangement leads to an essential Er increase of the anodically evaporated material proportion the cathodically evaporated material. It is special important if the anodically evaporated material is possible should be deposited with the highest purity.  

Usually the material of the target is on the cathode and the material to be anodically evaporated in the same way be so that no undesired mixed layers are removed be divorced. In some applications, the anodi vapor deposition material and the cathodic target material also be different. The properties of the Targetma terials can often be added with alloys, e.g. B. Zinc, cadmium, manganese, silver or other metals Improve higher vapor pressure. Also additives that the Increase ionization rate, e.g. B. Cer can be used will.

With the help of a perma attached below the target Magnets can change the ionization rate of the cathodic Bow set and the uniformity of the target hetero sion can be improved. This magnetic field effect is from the high-performance sputtering devices (Mag netron cathode atomizer) known. On the target of the cathodic vacuum arc becomes another Exploited effect. The spatial distribution of the cathode-firing spots can be in a defined zone of the target be directed that have no optical connection to the steam has outlet opening. The practically always on the Katho The droplets that arise are already in intercepted within the device according to the invention and held back. Essentially, layer deposition occurs only neutral and ionized vapor particles from the anodic crucible.

The advantageous ener is also of particular importance effect of the invention. The one with the central one Plasma stream flowing to the bottom of the crucible Trons lead to intense heating and evaporation the evaporation material in the crucible, without the energy of the already vaporized particles influence. The concentric plasma flow works against this essentially solely on the steam of the already evaporated material above the crucible and leads for its intensive ionization. The shares of  centric and concentric plasma flow by the arrangement, size and division of the openings in the aperture between the cathode and the anode.

Further details of the invention are set out in the following Embodiment described in more detail.

The accompanying drawing shows a device according to the invention within a vacuum chamber 1, not shown in detail. The device consists essentially of the cathode 2 with the target 3 formed thereon as a wearing part and the anode holder 4 with the crucible 5 held thereon in an electrically conductive and heat-insulating manner. The material 6 to be evaporated is located in the crucible 5 . The arrangement of the crucible 5 and the target 3 on the same vertical axis 7 is essential to the invention. The cathode 2 and the anode holder 4 are water-cooled in a known manner. The anode holder 4 is umman with a shield 27 arranged insulated.

To ignite the vacuum arc discharge between the target 3 and the crucible 5 , an ignition electrode 8 is seen before. This is jacket-shaped with a small distance, which is realized via the insulating ring 9 , around the target 3 . Together with the aperture 10 , they form a precisely defined area of the positive counterelectrode of the cathodic vacuum arc. Functionally, the ignition electrode 8 could also be made lower. In the example, the ignition electrode 8 also serves as a carrier for the diaphragm 10 . The aperture 10 has the task of splitting the original plasma stream into a central plasma stream 21 and a concentric plasma stream 22 . For this purpose, the screen 10 has a central opening 11 through which the central plasma stream 21 is formed, and a plurality of annularly arranged openings 12 through which the concentric plasma stream 22 is formed.

The bundling and alignment of the central Plasmastro mes 21 on the crucible 5 , advantageously supports a self-constant vacuum arc discharge between the target 3 and the anodic crucible 5th

The individual parts of the device described are surrounded in the example by a shield 13 which is axially closed at the bottom and has a cover 14 at the top. An opening 15 is arranged in the cover 14 above the crucible 5 for the exit of the evaporated and partially ionized material. Apart from the opening 15 , the shield 13 is essentially gas-tight. With the beginning of atomization and evaporation of the target 3, this causes the formation of a pressure stage with a substantially higher internal pressure than generally within the vacuum chamber 1 . This significantly improves the burning behavior of the vacuum arc discharge. The shield 13 is held insulated from the other individual parts of the device. Via a current circuit on the base plate, the shield 13 is connected to a switching element 25 and thus optionally connected to the positive pole of the controllable current source 18 . To coat insulating substrates, as will be described in more detail below, a current source 17 is also present in the example. The plasma within the shield 13 assumes the potential of the applied voltage.

The negative pole of the current source 18 is connected to the ground potential of the vacuum chamber 1 . The substrate holders 23 with the substrates and an acceleration grid 16 are also located at the ground potential. The acceleration grid 16 is part of a closed metallic Faraday cage, which surrounds the device according to the invention as a whole in a circle and has a distance of a few centimeters from the cover 14 . Within the Faraday cage with the accelerator grid 16 is still a steam orifice 26th

The power supply for the cathode 2 with the target 3 and the anodic crucible 5 takes place via the current source 19 . The ignition electrode 8 is integrated into this circuit via a low-resistance Lastwi resistor 20 . The shielding 27 of the anode holder 4 is at the potential of the ignition electrode 8 .

The device described above is subsequently with the Method according to the invention described in function.

When starting up for the first time, it is necessary to create a conductive connection between the target 3 and the ignition electrode 8 . This can e.g. B. by means of a thin wire or a conductive layer on the insulating ring 9 . If a corresponding voltage is applied between the cathode 2 with the target 3 and the anode holder 4 with the crucible 5 , the ignition electrode 8 is connected via the upstream load resistor 20 to the positive pole of the current source 19 . The low-resistance load resistor stood 20 causes a voltage drop in the ignition electrode 8 compared to the anode potential by about 10 volts and limits the direct current to about 25 A. Using claim 7, the base current from the current source 19 via the switching element 24 with steep, high-frequency positive pulses of short duration are superimposed, which arise when a memory inductance is discharged with a fast-switching MOSFET power transistor and an IGBT power stage. The high peak voltage of the “needle-shaped” pulses favors the skipping of an initial discharge over the distance between the cathode 2 or the cathode potential of the target 3 and a nearby edge of the ignition electrode 8 . The conductive connection at the first ignition via the insulating ring 9 , which is only a few tenths of a mm wide, is explosively vaporized and ionized by the initial discharge. The emitted particles leave an ionized trace, on which a powerful vacuum arc discharge spreads even under high vacuum conditions. This process is repeated for all subsequent ignitions, since the insulating ring 9 is always coated on its end face with each subsequent start-up with a thin electrically conductive layer made of the material evaporated from the target 3 when the device was last operated. Even in the event of a short circuit, the deposit between the ignition electrode 8 and the cathode 2 or the target 3 is vaporized in the same way by the short-circuit current.

With the ignition, a primary base discharge in the form of a cathodic vacuum arc is formed in the area between the ignition electrode 8 and the target 3 . This concentrated primary base discharge is sufficient for reliable ignition of an independent anodic vacuum arc between the anodic crucible 5 and the target 3 . The geometric design of the device leads to the fact that the free electrons and the ionized particles, which originate exclusively from the material vaporized and sputtered by the target 3 , as a cen tric plasma stream 21 through the opening 11 and as a con centric plasma stream 22 through the openings 12 emerge in the aperture 10 in the direction of the anodic crucible 5 . In particular, the bundled plasma stream 21 flows against the outer wall of the anodic crucible 5 , which is heated by the electron beam bombardment and thus also the material 6 present in the crucible 5 , which is the coating material, melts and evaporates.

The shield 27 , which in the example is at the potential of the ignition electrode 8 , prevents the anodic vacuum arc from burning directly against the anode holder 4 .

The vapor cloud above the crucible 5 is highly ionized under the action of the plasma, in particular the concentric plasma stream 22 . The degree of ionization of each material depends on its specific properties and external influences such as voltage, frequency, particle density (vapor pressure).

The positively charged ions of the material 6 flow back against the electron current to the cathode 2 and upon impact on the surface of the target 3 they trigger an avalanche of electrons and secondary ions. In the current branch between the cathode 2 and the ignition electrode 8 , the discharge current is reduced by about a third, because charge carriers made of the material 6 also participate in the vacuum arc discharge. A low-loss pulse width control is selected to control the up to 200 A high vacuum arc discharge currents. A typical IGBT power stage operating at 10 kHz generates current pulses which are stored in an air gap choke. Due to the discharge characteristic of the choke, a sawtooth-shaped modulation of the anode current arises. The comparisons of different pulse frequencies showed an increase in the degree of ionization with the pulse frequency. A synchronous but time-shifted pulse control via the IGBT power level is advantageous for a parallel operation of several evaporators in one coating chamber.

Depending on the current coating task, a positive acceleration voltage from the current source 18 is applied to the shield 13 via the switching element 25 . This potential is transferred to the plasma within the shield 13 . The space between the cover 14 and the acceleration grid 16 is filled with a thin plasma. The positive metal ions are extracted by the at ground potential accelerator grid 16 from the grid boundary layer of the plasma and accelerated when flying through the accelerator grid 16th The high speed remains in a vacuum until it is deposited on the substrate and has an advantageous effect on the layer formation.

In the case of non-conductive substrates, e.g. B. made of plastics, the positive emission current (ion current) of an evaporator according to the invention, which can reach currents of 1000 mA, build up a polarized surface charge. As a result, the incoming positively charged vapor particles are repelled electrostatically. The substrate charge does not degrade until the separated layer is continuously conductive and a connection to the ground potential of the substrate holder 23 has been established.

This disadvantageous for the layer formation upper surface charge can be compensated for with an offer of free electrons from the plasma-filled interior (Faraday cage) between the shield 13 with the cover 14 and the acceleration grid 16 .

Such space charge neutralization can be achieved with two push-pull DC voltage sources by reversing the plasma bias. The output voltages of the oppositely polarized current sources 17 and 18 can be assembled, for example, by a fast switching element 25 (MOSFET or IGBT) to a potential with rectangular, negative-positive pulses of adjustable duration and placed on the shield 13 and the cover 14 .

The mutual voltage drop leads in the vicinity of a zero potential for the respective switching of the switching element 25 to the other potential level. The potential of the shield 13 and the cover 14 changes in a corresponding manner and thus also the potential of the plasma. This generates sufficient electrons with negative potential, which are extracted from the plasma space below the grid onto the substrates and compensate for the positive charging on the non-conductive substrate. The duration of the negative rectangular pulses can be set variably.

Experiments have shown that the space charge concentration can be effectively reduced even at a pulse frequency in the range from 20 to 80 kHz (with practical feasibility also higher up to approx. 120 kHz) and a pulse duration ratio of 3 to 1 (+ zu -). The negative output voltage of the current source 17 is adjustable in the range 50 to 200 volts.

In the phase of the ignition of the device, only steam particles escape from the material of the target 3 from the device. This material can either be kept away from the substrate by means of a screen or the material can be deposited on the substrate as a thin adhesive layer. The possible variant is determined from the variety of variants solely by the requirements for the layer to be deposited on the substrate.

With the device according to the invention z. B. rota symmetrical parts from one with carbon fibers Reinforced plastic with a layer that evaporates in the Structure of the layer combination of substrate - 0.2 µm Cr - 0.3 µm CrCu - 0.5 µm Cu. This layer fulfills all requirements for a strong, tight, and electrical tric conductive base layer, which is advantageous below galvanically with a ductile thickness of more than 20 µm Cu layer and a few µm thick Ni layer can be reinforced can. These parts could replace conventional steel parts and can also be easily galvanized with a hard chrome Required thickness coated and by means of high finish grinding can be finished. It should be criticized ken that the deposition of hard chrome layers because of high residual stress is regularly very problematic.

The base layer described was deposited by evaporation of the individual materials chrome and copper from two or more individual evaporators according to the invention within a conventional high vacuum coating investment.

At the beginning of the coating, the aperture 26 is pivoted in the Faradaykä fig with the accelerating grid 16 such that the opening 15 is covered with the substrates relative to the substrate holder 23 . First, the vacuum arc discharge is ignited in the chromium vaporization devices. When evaporation begins, the orifice 26 is pivoted away from the steam flow. The discharge voltage is increased to +1000 V and the 0.2 μm Cr adhesive layer is evaporated at a low discharge current of less than 100 A / evaporator. This process takes approx. 2 minutes. The copper evaporators are then ignited and the acceleration voltage is switched off. With a plasma potential of the vacuum arc of approx. 25 V, the positive ions still reach an energy of approx. 10 eV. With the discharge current increased to approx. 160 A / evaporator (output approx. 4 kW), the Cr evaporators and the Cu evaporators are evaporated simultaneously and the 0.3 μm CrCu alloy layer is deposited. Finally, the Cr evaporation is slowly ended and the 0.5 µm thick layer of pure Cu is deposited.

Reference list

1 vacuum chamber
2 cathode
3 target
4 anode holder
5 crucibles (anodic)
6 material to be evaporated
7 axis
8 ignition electrode
9 insulating ring
10 aperture
11 opening (centric)
12 openings (several arranged in a ring)
13 shielding
14 cover
15 opening
16 acceleration grille
17 current source (negative acceleration voltage)
18 current source (positive acceleration voltage)
19 power source (vacuum arc)
20 load resistance
21 plasma flow (centric)
22 plasma flow (concentric)
23 substrate holder
24 switching element
25 switching element
26 steam shield
27 shielding

Claims (10)

1. Device for anodic evaporation of a material from an anodic crucible by means of a vacuum arc discharge, consisting of an anode holder, on which the crucible is held in an electrically conductive and heat-insulating manner, a cathode and an ignition electrode for ignition and maintenance of the vacuum electric arc discharge, the Plasma flow from the cathode focal spots acts both on the outer wall of the anodic crucible and on the vapor of the material evaporated therefrom, characterized in that the crucible ( 5 ) is essentially vertical and the axis ( 7 ) of the cathode ( 2 ) is arranged such that the ignition electrode ( 8 ) surrounds the cathode ( 2 ) in the form of a jacket and that between the ignition electrode ( 8 ) and the cathode ( 2 ) on the one hand and the anodic crucible ( 5 ) on the other hand one at the potential of the ignition electrode ( 8 ) lying diaphragm ( 10 ) with openings ( 11 , 12 ) is present. 2. Apparatus according to claim 1, characterized in that the diaphragm ( 10 ) has openings ( 11 , 12 ), which are preferably arranged centrically and / or concentrically, such that the plasma stream emanating from the cathode ( 2 ) into a central one Plasma stream ( 21 ) and a substantially concentric plasma stream ( 22 ) is divided, the central plasma stream ( 21 ) on the bottom of the anodic crucible ( 5 ) and the concentric plasma stream ( 22 ) concentrically flows around the anodic crucible ( 5 ) . 3. Apparatus according to claim 1, characterized in that at least the space in the area between the Katho de ( 2 ) and the anodic crucible ( 5 ) is enclosed by an electrically insulated shield ( 13 ) which acts as a Faraday cage. 4. The device according to claim 3, characterized in that the entire space around the cathode ( 2 ), the Zündelek electrode ( 8 ) with the diaphragm ( 10 ) and the anodic tie gel ( 5 ) from a substantially gas-tight shield ( 13th ) is enclosed, above the anodic crucible ( 5 ) has a cover ( 14 ) which has an opening ( 15 ) for the exit of the vaporized and at least partially ionized material ( 6 ). 5. Device according to one of the preceding claims, characterized in that between the steam outlet from the opening ( 15 ) and the substrate holder ( 23 ) there is a vapor-permeable acceleration grid ( 16 ) which is at ground potential. 6. Method for anodic evaporation of a material from a crucible lying at anodic potential by means of a vacuum arc discharge between a cathode and the anodic crucible, a cathodic vacuum arc only being ignited to ignite the vacuum arc discharge between an ignition electrode and the cathode, on the basis of this between the cathode and the anodic crucible forms an anodic vacuum arc, characterized in that, in order to maintain the anodic vacuum arc discharge, the ignition electrode ( 8 ) is constantly subjected to a positive potential which is lower than the potential of the anodic crucible ( 5 ) and higher than the quenching voltage of the vacuum arc discharge. 7. The method according to claim 6, characterized in that the anode potential from a DC voltage potential and a superimposed, high-frequency pulsating chip voltage is formed, the pulsating voltage has a pulse frequency between 20 kHz and 80 kHz.   8. The method according to claim 6 or 7, characterized in that for the extraction and acceleration of the ions to an acceleration grid ( 16 ) between the anodic crucible ( 5 ) and the substrates to be coated, an acceleration voltage between 200 to 2000 V is applied. 9. The method according to claim 6 or 7, characterized in that in order to influence the space charge, in particular re to avoid undesirable surface charges on the substrates to be coated, to an acceleration grid ( 16 ) around the cathode ( 2 ), the Zündelek electrode ( 8th ) and the anodic crucible ( 5 ) a static positive or negative potential or an alternating positive and negative potential is applied. 10. The method according to claim 7, characterized in that with parallel operation of several anodic The pulsie evaporates in a coating chamber voltage controlled synchronously but with a time delay becomes.