APPARATUS FOR CHEMICALLY ETCHING A WORKPIECE

Abstract

Apparatus for chemically etching a workpiece includes a chamber for receiving a process gas and having a pumping port for extracting exhaust gases, and a workpiece support located in the chamber upstream of the pumping port. The chamber further includes a sub-chamber located upstream of the pumping port and downstream of the workpiece support, and the sub-chamber includes a window and an excitation source, adjacent the window, for creating a plasma in a sample of the exhaust gases to create an optical emission which can be monitored through the window.

Description

BACKGROUND

This invention relates to apparatus and methods for chemically etching a workpiece using a process gas.

It has been known for many decades that when plasma etching a workpiece, it is possible to detect the point at which an etch has cut through a first layer and reached the underlying layer by the change in the optical emission resulting from the change in the exhaust or reaction products being generated and then being ionised by the plasma. Endpoints can also be detected by changes in consumption of etch gas, which can also be detected optically. Initially these emissions were monitored by skilled technicians. Subsequently the process was automated using optical end point detectors.

Endpoint processes based on the first part approach can only work where there is a plasma being generated and the exhaust and reaction products enter the plasma. There have been, accordingly, a number of proposal, such as that described in U.S. Pat. No. 4,857,136, in which the exhaust products from the turbo pump are ionised and the resultant optical emissions monitored. Experience has shown that arrangements of this sort can have a sluggish response and repeatedly is difficult to achieve due to limitations in local conditions.

SUMMARY

From one aspect the invention consists in apparatus for chemically etching a workpiece using a process gas, the apparatus including a chamber for receiving a process gas and having a pumping port for extracting exhaust gases; and a workpiece support located in the chamber upstream of the pumping port characterised in that the chamber further includes a sub-chamber located upstream of the pumping port and downstream of the workpiece support and in that the sub-chamber includes a window and an excitation source, adjacent the window, for creating a plasma in a sample of the exhaust gases to create an optical emission which can be monitored through the window.

The sub-chamber may include an extension or dead end in which the window is formed and the excitation source may include a coil located around the extension or dead end. The window is preferably close to the pumping port and may, for example, be opposite the pumping port. This enables the window to be adjacent to the exhaust stream.

The apparatus may further include a detector for monitoring the optical emission visible through the window and may further include a control for determining a process end point from the detected optical emission.

The apparatus may further include a source for supplying ionised process gas. Additionally or alternatively it may include a plasma source for creating a plasma in the chamber.

The invention also includes a method of etching using the apparatus defined above wherein the pressure in the chamber during etching is between about 1 to 500 mTor.

Although the invention has been described above it is to be understood it includes any inventive combination of the features set out above or in the following description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may be performed in various ways and a specific embodiment will now be described, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a photograph of part of an etch apparatus;

FIG. 2 is a schematic sectional view through the apparatus of FIG. 1; and

FIG. 3 is a graph of the output of a detector showing the traces for different configurations.

DETAILED DESCRIPTION OF EMBODIMENTS

An etching apparatus is generally indicated at 10 and has a chamber 11, in which is located a workpiece support 12, which is conveniently in the form of a electrostatic chunk, and a source of ionised process gas generally indicated at 13. In a typical prior art arrangement such an apparatus would have a pumping port located at 14, which would be connected to a turbo pump. In the applicants arrangement a sub-chamber 15 is attached to the opening 14 and carries a pumping port 16 which is connected to a turbo pump 17.

The sub-chamber 15 is also provided with an extension or dead end 18 that has a window 19 formed in its closed end. A coil 20 surrounds the extension 18 and is connected to a RF source 21 so that a local plasma can be struck within the extension 18.

A detector 22 is located outside the window 19 to monitor the optical emissions from the localised plasma 23 and it feeds it output signals to a control/processor 24, which produces an output signal 25 that can be used to control the process within the chamber 11 and may be displayed at 26 if manual control is desired.

FIG. 3 is a plot of such an output signal for three different experimental arrangements. The process being run was a relatively high pressure plasma etch process and the optical emission relating to a particular etch process in the chamber itself; downstream of the turbo pump and with the apparatus shown in FIG. 2.

As can be seen from FIG. 3 there was no detectable change in the signal within the chamber because in the high pressure situation very little reaction product reaches the plasma. (It should be noted that the graph is of relative intensity not actual intensity).

In the foreline (i.e. downstream of the turbo pump) it takes a little while before the relative intensity reaches 100% and then the drop off in intensity is relatively slow and flat. As the intensity initially rises from below 100%, it is quite difficult to set up the equipment to be sure of detecting an end point until the relative intensity has dropped back down again below this starting position. As can be seen from the graph, this in itself could lead to a delay of some 10 seconds before an end point could be established and the relatively small change means that the system is more susceptible to errors and therefore it may not be possible to be certain of determining an end point until up to 20 seconds later, in terms of the process being utilised in the experiment. In contrast the solid line trace starts at a relative intensity of 100% and drops off very much more sharply allowing accurate and quick end point detection and therefore reduces the risk of undered over-etching. The sensitivity is importantly better because of clearer, larger signal being generated and so even endpoints, which create relatively small changes in the exhaust gas, can be detected. For example, these may result from small exposed open areas.

It will also be appreciated that the system can be used even when the main process does not utilise a plasma and the improved response means that the system can be used with shorter etch processes.

The detector 22 can be any suitable configuration. It could for example be a simple filter in a wide band optical detector, one or more narrow band detectors, such as manual or automatic mono-chromators, a full spectrometer, such as a CCD (Camera Optical Emissions) Spectrometer.

The window 19 clearly must be transparent to the optical transmission of interest. If the apparatus is very specifically configured, it could even constitute the necessary filter.

The apparatus not only allows good and quick end point detection. It could be used for other testing processes such as gas quality assessment, leak checking and window clouding measurements.

Claims

1. Apparatus for chemically etching a workpiece using a process gas, the apparatus including a chamber for receiving the process gas and having a pumping port for extracting exhaust gases; and a workpiece support located in the chamber upstream of the pumping port characterised in that the chamber further includes a sub-chamber located upstream of the pumping port and downstream of the workpiece support and in that the sub-chamber includes a window and an excitation source, adjacent the window, for creating a plasma in a sample of the exhaust gases to create an optical emission which can be monitored through the window.

2. Apparatus as claimed in claim 1 wherein the sub-chamber includes an extension or dead end in which the window is formed and the excitation source includes a coil or capacitor away located around the extension or dead end.

3. Apparatus as claimed in claim 1 wherein the window is generally opposite the pumping port.

4. Apparatus as claimed in claim 2 wherein the window is generally opposite the pumping port.

5. Apparatus as claimed in claim 1 further including a detector for monitoring the optical emission visible through the window.

6. Apparatus as claimed in claim 5 further including a control for determining a process end point from the detected optical emission.

7. Apparatus as claimed in claim 2 further including a detector for monitoring the optical emission visible through the window.

8. Apparatus as claimed in claim 7 further including a control for determining a process end point from the detected optical emission.

9. Apparatus as claimed in claim 1 further including a source for supplying ionised process gas.

10. Apparatus as claimed in claim 2 further including a source for supplying ionised process gas.

11. Apparatus as claimed in claim 5 further including a source for supplying ionised process gas.

12. Apparatus as claimed in claim 7 further including a source for supplying ionised process gas.