Adhesive bonding and miscellaneous chemical manufacture – Differential fluid etching apparatus – With radio frequency antenna or inductive coil gas...
Reexamination Certificate
2002-03-29
2004-01-27
Alejandro-Mulero, Luz (Department: 1763)
Adhesive bonding and miscellaneous chemical manufacture
Differential fluid etching apparatus
With radio frequency antenna or inductive coil gas...
C156S345490, C156S345330, C118S7230IR, C118S715000
Reexamination Certificate
active
06682630
ABSTRACT:
TECHNICAL FIELD AND RELATED ART
The present invention relates generally to apparatus and their use for surface treatments using plasma assisted processing and more particularly, but not exclusively, for the treatment of large flat substrates.
Such treatments can include etching, deposition, cleaning, passivation and ion implantation.
The new requirements for the plasma processing of large substrates become more and more critical for plasma sources available on the market. The success of the plasma assisted processing depends on the scalability of these plasma sources.
To fulfill these requirements, new plasma sources must be envisaged to process large substrates with plasma features like the generation of high densities of reactive species with low and controllable energy over a wide pressure range, and with an excellent homogeneity throughout the substrate.
Plasma processing generally uses a vacuum chamber connected to a gas inlet and a pumping device for controlling the gas flows and pressure. Electrical energy is applied to the vacuum chamber to accelerate the free electrons in the gases to the energy of ionization of the gas molecules, which thereby creates plasma. Ionization phenomena free some electrons which can also be accelerated to the ionization energy.
The added energy of the free electrons in the gas is generally accomplished by an electric field, a varying magnetic field, or both.
One traditional method used in plasma processing to generate plasma is by a technique known as Capacitively Coupled Plasma. The plasma results from the application of an AC voltage between two electrodes creating an electric field which accelerate the free electrons. Generally, one of the two electrodes is the substrate holder. The applied energy generated by the AC voltage applied between the two electrodes controls at the same time the flux and kinetic energy of the ions. Because the two parameters are coupled, this process is difficult to optimize.
Another plasma source used in plasma processing is based on the Electron Cyclotron Resonance (ECR). In this process, microwave power is applied to the gas together with a constant magnetic field which transforms the electron paths into a circular path. The intensity of the magnetic field is such that the frequency of gyration of the electron is the same as the frequency of the electric field, which leads to a resonance effect increasing the efficiency of electron acceleration. This type of excitation mode can provide a plasma with high ion flux and low ion energy. The ion energy can be controlled by applying an independent bias to the substrate. However, such an apparatus is complex and expensive. Moreover, it is still too limited as regards the plasma expected processing expected features, in particular for scaling up and homogeneity of the plasma source.
A new generation of plasma source has been developed during the last years which give good promise. These are known as Inductively Coupled Plasmas (ICPs), such as described e.g. in U.S. Pat. Nos. 4,948,458 and 5,277,751. The plasma is created by a varying magnetic field generated by a spiral planar coil. The electrons are accelerated in a circular path parallel to the coil plane and the insulating window of the plasma chamber. This configuration provides a high density plasma with low kinetic energy, but has an inherent problem of homogeneity at the center and at the boundary of the coil when the size of the apparatus is increased. This problem limits the scability of the process.
U.S. Pat. No. 5,435,881 presents an apparatus for generating a suitably low pressure planar plasma. This apparatus comprises a two-by-two or a larger array of alternating magnetic poles (multipoles). The advantages cited in this patent are the possibility to generate a large plasma by adding more varying magnetic poles, therefore having very small area on non uniform plasma.
However, such a design creates a dependency between the spacing of the two-by-two magnetic poles and the excitation frequency as well as the in-use operation pressure. This spacing depends on the mean free path of the electrons which decreases when the pressure increases. Accordingly, when a high operating pressure is necessary for process requirements, the spacing between the two-by-two poles must be drastically decreased. This becomes critical from a technical point of view. The process also requires different multipole distributions for different process pressures, which decreases its flexibility and applicability to industrial applications.
In all these prior art apparatus, there is a problem of gas distribution uniformity in the chamber center. The gas distribution is usually made using a ring located in the side wall of the plasma chamber, which results in a lack of gas distribution uniformity at the chamber center. This non-uniformity is even more acute when the plasma chamber dimension increases. Moreover the gas distribution means are usually made of metallic material, which perturbs the magnetic field inside the chamber, and thus the plasma density.
Document EP-776 645 apparently discloses a plasma reactor or plasma chamber in which a uniform gas distribution is achieved across a wafer surface by injecting gas through a center gas feed silicon or semiconductor ceiling.
This device is schematically illustrated on
FIG. 1
, and comprises a plasma chamber
2
, covered by a semiconductor ceiling
6
through which gas injection tubes
12
,
14
are drilled. Tube
14
in turn is connected to a center gas feed pipe
16
.
An overhead inductive coil antenna
4
is held in an insulating antenna holder
8
connected to a plasma source power generator through an impedance match circuit
10
.
In this device, a voltage of about 2000 to 3000 volts is usually applied to the coil antenna. A correspondingly very high electric field can thus be induced in the dielectric window constituted by the semiconductor ceiling
6
. Such a capacitive coupling is very detrimental.
This document further suggests choosing either a dielectric or semiconductor, as a material for the top ceiling. However, dielectric or semiconductor material results in a plasma being created in tubes
12
,
14
, because of this capacitive coupling, which is gas consuming and can damage the semiconductor ceiling.
SUMMARY OF THE INVENTION
The invention concerns an apparatus for generating a time-varying magnetic field in a plasma processing chamber to create or sustain a plasma within the chamber by inductive coupling, characterised in that it comprises:
a magnetic core presenting a pole face structure or a unipolar pole face structure
an inductor means associated with the magnetic core, for generating a substantially uniformly distributed time-varying magnetic field throughout the pole face or unipolar pole face structure,
means for injecting gas into said chamber and through said magnetic core.
Since the means for injecting gas into the plasma chamber are located or inserted through said magnetic core, a uniform or controlled gas distribution is achieved in a plasma processing chamber having such an apparatus for generating a time-varying magnetic field, without any perturbation of the magnetic field.
Furthermore, the magnetic core electrostatically isolates the means for gas injection from the inductor means. In other words, the magnetic core plays the role of an electrostatic screen between the means for gas injection and the inductor means, thus eliminating the risk of capacitive coupling. The risk of plasma induction in the gas injecting means themselves is reduced.
According to one embodiment of the invention, said means for injecting gas into said chamber form a showerhead-like gas injection.
For example, they advantageously comprise a plurality of injection pipes distributed through the magnetic core. These injection pipes are made of stainless steel material, or of an insulating material.
An advantage of this embodiment is that the number of injection pipes can be adapted without perturbing the magnetic field. In other words, the number of pipes does not influence the magne
Colpo Pascal
Rossi François
Alejandro-Mulero Luz
Bacon & Thomas PLLC
European Community (EC)
LandOfFree
Uniform gas distribution in large area plasma source does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Uniform gas distribution in large area plasma source, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Uniform gas distribution in large area plasma source will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3210277