DE102008023027A1 - Electrode arrangement for plasma-supported, magnetically-guided deposition or removal of thin layers on/from substrate surface in vacuum, has insulated element arranged in intermediate space between bases of backplate electrode and screen - Google Patents

Abstract

The arrangement has an electrically insulated element (3) arranged in an intermediate space between bases (11, 21) of a backplate electrode i.e. anode box (1), and a dark field screen (2). The dark field screen is provided with a side wall (22) surrounding an outer side of the backplate electrode. The bases of the backplate electrode and the dark field screen, and side walls (12, 22) of the backplate electrode and the dark field screen are arranged at distance from each other. The insulated element consists of ceramic paper, ceramic fibrous web or ceramic casting material.

Description

The The invention relates to an electrode arrangement for magnetic-field-guided plasma-assisted processes, for example, the deposition of thin layers on the surface a substrate or the removal of thin layers from the surface of a Substrate in a vacuum.

In the processes considered here are to be treated between Substrate and a counter electrode ignited a plasma whose positive charge carriers through the so-called sputtering effect (dusting, that is by ion bombardment induced strike out of atoms from the solid surface) upper layers of a surface (Coating material or contaminants of the substrate) ablate. Depending on the method, the counter electrode opposite to the substrate cathode or Be anode. In the deposition of thin layers on the surface of a Substrate becomes the one to be atomized Provided material in the form of so-called targets and based on (relative) Cathode potential placed while the substrate is at (relative) anode potential. In contrast, lies thinner on removal Layers from the surface a substrate, the substrate on (relative) cathode potential, where the plasma is between the substrate and one on (relative) Anode potential electrode (often as an anode plate or Anode box executed) formed. In support of the Plasma formation as well as for targeted amplification of the movement in the plasma contained charge carriers (Ions) on the ablated surface (target during coating or substrate during removal) is on the side facing away from the plasma Side of this surface a magnetic device is provided which influences the movement of the charge carriers and to increase the charge carrier density leads.

Around undesirable To prevent discharges where the back of the counter electrode also atomized or / and contamination of the sputtered layer is caused, you use a grounded shield, which before the atomization too enclosing parts. This so-called dark field shield must be so close to the shielded parts lie that their distance is less than the necessary for burning the discharge Length of the Dark room in front of the counter electrode.

Problematic It is that between the counter electrode and the dark field shield discharges may occur, which endanger the process. These are usually caused by metallic baubles, for example consists of ablated particles of the target or of the substrate, in the space between the counter electrode and the dark field shield have arrived. To such disturbances to prevent the running process, becomes an electrode assembly proposed with a counter electrode and a dark field shield, at the between the counter electrode and the dark field shield an electrically insulating element is arranged.

If the counter electrode is an anode box with a bottom and the bottom enclosing sidewalls, can be further provided that the dark field shield a the outside of the anode box enclosing Shielding box with a bottom and the bottom enclosing side walls, the floors of anode box and shielding box as well as the side walls of Anodenkasten and shielding box are spaced from each other.

In this case, the electrically insulating element can extend over the entire surface at least between the bottoms of the anode box and the shielding box. In this way it is prevented that in the intermediate space passing tinsel leads to a discharge between the two floors, especially when the anode box is disposed within the process plant with upward opening. The electrically insulating element may be embodied as an insert or so that it fills the entire space between the bottoms of the anode box and the shielding box:
It can further be provided that the electrically insulating element extends over the entire surface between the bottoms and side walls of the anode box and the shielding box. Again, the electrically insulating element may be an insert whose thickness is less than the distance between the side walls and the floors or be designed so that it fills the entire space between the anode box and the shield box.

The electrically insulating element can be made of ceramic paper or ceramic fleece be made. These materials are based on ceramic fibers different length and can like ordinary paper or textile fleece cut and folded. This fiber material is extremely resistant to Aging, is temperature shock resistant and has a low thermal conductivity and a high tear resistance and reversible shape fidelity. It is resistant in reducing and oxidizing Gas atmospheres, against most chemicals and solvents, as well as against many Molten metals, for Operating temperatures up to 1260 ° C-1650 ° C suitable and available in different thicknesses.

Another possibility is to manufacture the electrically insulating element of a ceramic casting material, the material and Weight savings can be foamed. Such casting compounds are usually supplied from two components, powder and binder, and cure chemically.

suitable Basic materials for the electrically insulating element are, for example, aluminum oxide, aluminum silicate; Zirconia, boron nitride, silicon dioxide.

following the described electrode arrangement using exemplary embodiments and associated Drawings closer explained. Show

1 an electrode assembly for dry etching, and

2 a device for magnetic field-guided plasma-assisted treatment of substrates in a vacuum.

In 1 is an anode box 1 shown used for dry etching a substrate. The anode box 1 has a floor 11 and the floor 11 enclosing sidewalls 12 as well as a connection 13 to a power supply 15 on. The outside of the anode box 1 is from a shield box 2 which also covers a floor 21 as well as the ground 21 enclosing sidewalls 22 having. In the ground 21 of the shielding box 2 an opening is provided through which an insulation tube 14 from the ground 11 of the anode box 1 to the back of the shielding box 2 leads. Through the insulation pipe 14 is the connection line 13 from the power supply 15 to the ground 11 of the anode box 1 guided. The shield box 2 is grounded.

On the ground 21 of the shielding box 2 is an electrically insulating element 3 arranged, which is designed as a deposit of ceramic paper. The electrically insulating element 3 extends over the entire surface of the soil 21 of the shielding box 2 and prevents so in the space between anode box 1 and shielding box 2 tinsel leading to a discharge between the two floors 11 . 21 leads.

2 shows a section of a device 4 for vacuum treatment of a substrate 5 , In the exemplary embodiment, the substrate 5 a metal band whose surface is inside the device 4 should be cleaned by dry etching.

This is the substrate 5 on a transport device 41 through the device 4 emotional. Above the substrate 5 an electrode assembly is provided which includes an anode box 1 as well as the anode box 1 enclosing shielding box 2 includes, which are arranged at a distance from each other. In the space between the substrate 5 and the anode box 1 For the implementation of the process, a plasma-forming gas is introduced.

The shield box 2 and the substrate 5 are grounded and the anode box 1 is at a positive high voltage potential, so that the anode box 1 as the anode and the substrate 5 as the cathode of the plasma discharge 6 acts. Below the substrate 5 is a magnetic device 42 arranged to promote the formation of the plasma discharge and the positive ions of the plasma-forming gas contained therein to the anode box 1 facing surface of the substrate 5 directs.

The space between the anode box 1 and the shield box 2 is completely by an electrically insulating element 3 filled, which consists of a foamed ceramic potting compound. This will cause discharges between the anode box 1 and the earthed shield box acting like a cathode due to the existing potential difference 2 effectively prevented.

1

Counter electrode, anode box

11

ground

12

Side wall

13

connecting line

14

insulating tube

15

power supply

2

Dark field shielding, shielding box

21

ground

22

Side wall

3

electrical insulating element

4

contraption for vacuum treatment

41

transport means

42

magnetic device

5

substratum

6

plasma discharge

Claims (10)

Electrode arrangement with a counterelectrode ( 1 ) and a dark field shield ( 2 ), in which between the counter electrode ( 1 ) and the dark field shield ( 2 ) an electrically insulating element ( 3 ) is arranged. Electrode arrangement according to Claim 1, characterized in that the counterelectrode ( 1 ) an anode box with a bottom ( 11 ) and the ground ( 11 ) enclosing side walls ( 12 ) and the dark field shield ( 2 ) the outside of the anode box ( 1 ) enclosing Abschir with a bottom ( 21 ) and the ground ( 21 ) enclosing side walls ( 22 ), the soils ( 11 . 21 ) of anode box ( 1 ) and shielding box ( 2 ) as well as the side walls ( 12 . 22 ) of anode box ( 1 ) and shielding box ( 2 ) are spaced from each other. Electrode arrangement according to claim 2, characterized in that the electrically insulating element ( 3 ) over the entire surface at least between the floors ( 11 . 21 ) of the anode box ( 1 ) and the shielding box ( 2 ). Electrode arrangement according to claim 2 or 3, characterized in that the electrically insulating element ( 3 ) the entire space between the floors ( 11 . 21 ) of the anode box ( 1 ) and the shielding box ( 2 ). Electrode arrangement according to one of claims 2 to 4, characterized in that the electrically insulating element ( 3 ) over the entire surface between the floors ( 11 . 21 ) and side walls ( 12 . 22 ) of the anode box ( 1 ) and the shielding box ( 2 ). Electrode arrangement according to one of claims 2 to 5, characterized in that the electrically insulating element ( 3 ) the entire space between the anode box ( 1 ) and the shielding box ( 2 ). Electrode arrangement according to one of claims 1 to 6, characterized in that the electrically insulating element ( 3 ) is made of ceramic paper or ceramic fleece. Electrode arrangement according to one of claims 1 to 6, characterized in that the electrically insulating element ( 3 ) is made of a ceramic casting material. Electrode arrangement according to Claim 8, characterized that the ceramic casting compound is foamed. Electrode arrangement according to one of claims 1 to 9, characterized in that the electrically insulating element ( 3 ) consists predominantly of one or more of the following substances: aluminum oxide, aluminum silicate, zirconium oxide, boron nitride, silicon dioxide.