U.S. patent application number 11/669114 was filed with the patent office on 2007-08-02 for gas supply system, substrate processing apparatus and gas supply method.
This patent application is currently assigned to TOKYO ELECTRON LIMITED. Invention is credited to Kenetsu MIZUSAWA.
Application Number | 20070175391 11/669114 |
Document ID | / |
Family ID | 38487038 |
Filed Date | 2007-08-02 |
United States Patent
Application |
20070175391 |
Kind Code |
A1 |
MIZUSAWA; Kenetsu |
August 2, 2007 |
GAS SUPPLY SYSTEM, SUBSTRATE PROCESSING APPARATUS AND GAS SUPPLY
METHOD
Abstract
A gas supply system for supplying a gas into a processing
chamber for processing a substrate to be processed includes: a
processing gas supply unit; a processing gas supply line; a first
and a second processing gas branch line; a branch flow control
unit; an additional gas supply unit; an additional gas supply line;
a first and a second additional gas branch line; a flow path
switching unit; and a control unit. Before processing the substrate
to be processed, the control unit performs a pressure ratio control
on the branch flow control unit while the processing gas supply
unit supplies the processing gas. After the inner pressures of the
first and the second processing gas branch line become stable, the
control unit switches the pressure ratio control to a fixed
pressure control, and then the additional gas supply unit supplies
the additional gas.
Inventors: |
MIZUSAWA; Kenetsu;
(Nirasaki-shi, JP) |
Correspondence
Address: |
OBLON, SPIVAK, MCCLELLAND, MAIER & NEUSTADT, P.C.
1940 DUKE STREET
ALEXANDRIA
VA
22314
US
|
Assignee: |
TOKYO ELECTRON LIMITED
Minato-ku
JP
|
Family ID: |
38487038 |
Appl. No.: |
11/669114 |
Filed: |
January 30, 2007 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
60771441 |
Feb 9, 2006 |
|
|
|
Current U.S.
Class: |
118/689 ;
118/715; 156/345.29 |
Current CPC
Class: |
C23C 16/45561 20130101;
C23C 16/455 20130101; Y10T 137/877 20150401; Y10T 137/0318
20150401 |
Class at
Publication: |
118/689 ;
118/715; 156/345.29 |
International
Class: |
C23C 16/00 20060101
C23C016/00; B05C 11/00 20060101 B05C011/00; H01L 21/306 20060101
H01L021/306 |
Foreign Application Data
Date |
Code |
Application Number |
Jan 31, 2006 |
JP |
2006-021879 |
Claims
1. A gas supply system for supplying a gas into a processing
chamber for processing a substrate to be processed, the system
comprising: a processing gas supply unit for supplying processing
gas for processing the substrate to be processed; a processing gas
supply line for allowing the processing gas from the processing gas
supply unit to flow therein; a first and a second processing gas
branch line branched from the processing gas supply line to be
connected with different portions of the processing chamber; a
branch flow control unit for controlling branch flows of the
processing gas distributed from the processing gas supply line to
the first and the second processing gas branch line based on inner
pressures of the first and the second processing gas branch line,
respectively; an additional gas supply unit for supplying
additional gas; an additional gas supply line for allowing the
additional gas from the additional gas supply unit to flow therein;
a first additional gas branch line branched from the additional gas
supply line to be connected with the first processing gas branch
line at a downstream side of the branch flow control unit; a second
additional gas branch line branched from the additional gas supply
line to be connected with the second processing gas branch line at
a downstream side of the branch flow control unit; a flow path
switching unit for switching a flow path of the additional gas from
the additional gas supply line between the first and the second
additional gas branch line; and a control unit for supplying,
before processing the substrate to be processed, the processing gas
from the processing gas supply unit while performing a pressure
ratio control on the branch flow control unit such that a pressure
ratio between the inner pressures of the first and the second
processing gas branch line is kept at a target pressure ratio, and
then supplying the additional gas from the additional gas supply
unit after the inner pressures of the first and the second
processing gas branch line become stable to be at a first and a
second stable inner pressure, wherein in case of supplying the
additional gas to the second processing gas branch line via the
second additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
first fixed pressure control that controls the branch flows such
that the first stable inner pressure is maintained in the first
processing gas branch line, whereas in case of supplying the
additional gas to the first processing gas branch line via the
first additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
second fixed pressure control that controls the branch flows such
that the second stable inner pressure is maintained in the second
processing gas branch line.
2. The gas supply system of claim 1, wherein, when the inner
pressures of the first and the second processing gas branch line
become stable to be at a third and a fourth stable inner pressure
after supplying the additional gas, the control unit sets a
pressure ratio between the third and the fourth stable inner
pressure as a new target pressure ratio; and switches the fixed
pressure control on the branch flow control unit to another
pressure ratio control that controls the branch flows such that a
pressure ratio between the inner pressures of the first and the
second processing gas branch line is kept at the new target
pressure ratio.
3. The gas supply system of claim 1, wherein the branch flow
control unit has valves for controlling flow rates of the
processing gas flowing through the first and the second processing
gas branch line; and pressure sensors that detect the inner
pressures of the first and the second processing gas branch line,
respectively, wherein a ratio of the flow rates of the processing
gas flowing through the first and the second processing gas branch
line is controlled by controlling the valves based on the inner
pressures detected by the pressure sensors.
4. The gas supply system of claim 1, wherein the processing gas
supply unit has a plurality of gas supply sources to supply to the
processing gas supply line the processing gas obtained by mixing
gases from the gas supply sources at a specific flow rate
ratio.
5. The gas supply system of claim 1, wherein the additional gas
supply unit has a number of gas supply sources to supply to the
additional gas supply line, the additional gas obtained by
selecting a gas from the gas supply sources or by mixing gases
therefrom at a specific gas flow rate ratio.
6. The gas supply system of claim 1, wherein the first processing
gas branch line is arranged to supply the processing gas flowing
therein toward a central region on a surface of the substrate
disposed in the processing chamber; and the second processing gas
branch line is arranged to supply the processing gas flowing
therein toward a peripheral region on the surface of the
substrate.
7. The gas supply system of claim 1, wherein the second processing
gas branch line is configured as plural branch lines branched from
the processing gas supply line, and the additional gas from the
additional gas supply unit is supplied to each of the plural branch
lines.
8. A gas supply system for supplying a gas into a processing
chamber for processing a substrate to be processed, the system
comprising: a processing gas supply unit for supplying processing
gas for processing the substrate to be processed; a processing gas
supply line for allowing the processing gas from the processing gas
supply unit to flow therein; a first and a second processing gas
branch line branched from the processing gas supply line to be
connected with different portions of the processing chamber; a
branch flow control unit for controlling branch flows of the
processing gas distributed from the processing gas supply line to
the first and the second processing gas branch line based on inner
pressures of the first and the second processing gas branch line,
respectively; an additional gas supply unit for supplying
additional gas; an additional gas supply line for allowing the
additional gas from the additional gas supply unit to flow therein;
a first additional gas branch line branched from the additional gas
supply line to be connected with the first processing gas branch
line at a downstream side of the branch flow control unit; a second
additional gas branch line branched from the additional gas supply
line to be connected with the second processing gas branch line at
a downstream side of the branch flow control unit; and an
opening/closing valve, provided on each of either one or both of
the first and the second additional gas branch line, for opening
and closing each of said either one or both of the additional gas
branch lines.
9. A substrate processing apparatus comprising: a processing
chamber for processing a substrate to be processed; a gas supply
system for supplying a gas into the processing chamber; and a
control unit for controlling the gas supply system, wherein the gas
supply system includes: a processing gas supply unit for supplying
processing gas for processing the substrate to be processed; a
processing gas supply line for allowing the processing gas from the
processing gas supply unit to flow therein; a first and a second
processing gas branch line branched from the processing gas supply
line to be connected with different portions of the processing
chamber; a branch flow control unit for controlling branch flows of
the processing gas distributed from the processing gas supply line
to the first and the second processing gas branch line based on
inner pressures of the first and the second processing gas branch
line, respectively; an additional gas supply unit for supplying
additional gas; an additional gas supply line for allowing the
additional gas from the additional gas supply unit to flow therein;
a first additional gas branch line branched from the additional gas
supply line to be connected with the first processing gas branch
line at a downstream side of the branch flow control unit; a second
additional gas branch line branched from the additional gas supply
line to be connected with the second processing gas branch line at
a downstream side of the branch flow control unit; and a flow path
switching unit for switching a flow path of the additional gas from
the additional gas supply line between the first and the second
additional gas branch line, and wherein the control unit supplies,
before processing the substrate to be processed, the processing gas
from the processing gas supply unit while performing a pressure
ratio control on the branch flow control unit such that a pressure
ratio between the inner pressures of the first and the second
processing gas branch line is kept at a target pressure ratio, and
then supplies the additional gas from the additional gas supply
unit after the inner pressures of the first and the second
processing gas branch line become stable to be at a first and a
second stable inner pressure, wherein in case of supplying the
additional gas to the second processing gas branch line via the
second additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
first fixed pressure control that controls the branch flows such
that the first stable inner pressure is maintained in the first
processing gas branch line, whereas in case of supplying the
additional gas to the first processing gas branch line via the
first additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
second fixed pressure control that controls the branch flows such
that the second stable inner pressure is maintained in the second
processing gas branch line.
10. The substrate processing apparatus of claim 9, wherein, when
the inner pressures of the first and the second processing gas
branch line become stable to be at a third and a fourth stable
inner pressure after supplying the additional gas, the control unit
sets a pressure ratio between the third and the fourth stable inner
pressure as a new target pressure ratio; switches the fixed
pressure control on the branch flow control unit to another
pressure ratio control that controls the branch flows such that a
pressure ratio between the inner pressures of the first and the
second processing gas branch line is kept at the new target
pressure ratio; and then starts a processing of the substrate to be
processed.
11. A gas supply method for use with a gas supply system for
supplying a gas into a processing chamber for processing a
substrate to be processed, wherein the gas supply system includes a
processing gas supply unit for supplying processing gas for
processing the substrate to be processed; a processing gas supply
line for allowing the processing gas from the processing gas supply
unit to flow therein; a first and a second processing gas branch
line branched from the processing gas supply line to be connected
with different portions of the processing chamber; a branch flow
control unit for controlling branch flows of the processing gas
distributed from the processing gas supply line to the first and
the second processing gas branch line based on inner pressures of
the first and the second processing gas branch line, respectively;
an additional gas supply unit for supplying additional gas; an
additional gas supply line for allowing the additional gas from the
additional gas supply unit to flow therein; a first additional gas
branch line branched from the additional gas supply line to be
connected with the first processing gas branch line at a downstream
side of the branch flow control unit; a second additional gas
branch line branched from the additional gas supply line to be
connected with the second processing gas branch line at a
downstream side of the branch flow control unit; and a flow path
switching unit for switching a flow path of the additional gas from
the additional gas supply line between the first and the second
additional gas branch line, the method comprising the steps of:
supplying, before processing the substrate to be processed, the
processing gas from the processing gas supply unit while performing
a pressure ratio control on the branch flow control unit such that
a pressure ratio between the inner pressures of the first and the
second processing gas branch line is kept at a target pressure
ratio; and supplying the additional gas from the additional gas
supply unit after the inner pressures of the first and the second
processing gas branch line become stable to be at a first and a
second stable inner pressure, wherein in case of supplying the
additional gas to the second processing gas branch line via the
second additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
first fixed pressure control that controls the branch flows such
that the first stable inner pressure is maintained in the first
processing gas branch line, whereas in case of supplying the
additional gas to the first processing gas branch line via the
first additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
second fixed pressure control that controls the branch flows such
that the second stable inner pressure is maintained in the second
processing gas branch line.
12. The gas supply method of claim 11, further comprising the steps
of: setting, when the inner pressures of the first and the second
processing gas branch line become stable to be at a third and a
fourth stable inner pressure after supplying the additional gas, a
pressure ratio between the third and the fourth stable inner
pressure as a new target pressure ratio; and switching the fixed
pressure control on the branch flow control unit to another
pressure ratio control that controls the branch flows such that a
pressure ratio between the inner pressures of the first and the
second processing gas branch line is kept at the new target
pressure ratio.
Description
FIELD OF THE INVENTION
[0001] The present invention relates to a gas supply system for
supplying a gas into a processing chamber, a substrate processing
apparatus and a gas supply method.
BACKGROUND OF THE INVENTION
[0002] A substrate processing apparatus is configured to perform
specific processes such as a film forming process, an etching
process and the like on a substrate to be processed (hereinafter,
simply referred to as "substrate") such as a semiconductor wafer, a
liquid crystal substrate or the like.
[0003] As for such a substrate processing apparatus, there has been
known a plasma processing apparatus, for example. The plasma
processing apparatus includes, inside a processing chamber, a lower
electrode serving also as a mounting table for mounting thereon a
substrate and an upper electrode serving also as a shower head for
injecting a gas toward the substrate. Such a parallel plate type
plasma processing apparatus is configured to perform specific
processes such as a film forming process, an etching process and
the like with the use of a plasma generated by applying a high
frequency power between both electrodes while supplying a specific
gas through the shower head onto the substrate in the processing
chamber.
[0004] In performing on the substrate specific processes such as a
film forming process, an etching process and the like, there has
been demanded to improve in-surface uniformity in processing the
substrate by making processing characteristics (e.g., an etching
rate, an etching selectivity, a film forming rate and the like)
uniform in a surface of the substrate.
[0005] In such a view, in Japanese Patent Laid-open Application
Nos. H8-158072 and H9-45624, there have been proposed techniques
for supplying a processing gas of optional composition at an
optional flow rate to plural portions on a substrate surface via
gas supply lines individually connected with a plurality of gas
chambers formed by dividing the inside of the shower head. In
accordance with such techniques, the in-surface uniformity in
etching the substrate can be improved by locally adjusting a gas
concentration on the substrate surface.
[0006] A gas used for an actual substrate processing is obtained by
mixing plural types of gases, e.g., a processing gas directly
participating in a substrate processing, a gas for controlling a
deposition of reaction products generated in the substrate
processing, a carrier gas such as an inactive gas or the like, and
the like. The types of gases are appropriately selected depending
on target materials on the substrate or processing conditions.
Therefore, there arises a need to perform a flow rate control by
using a mass flow controller provided on each of the gas supply
lines respectively connected with the gas chambers in the shower
head, as disclosed in Japanese Patent Laid-open Application No.
H9-45624.
[0007] However, in such a conventional configuration, although the
gases supplied to plural portions on a substrate surface include
common gases, each of the gases supplied from the gas chambers has
its own gas supply system and, also, flow rates thereof are
individually controlled. Accordingly, a line configuration and a
flow rate control in each of the lines become complicated, which
results in requiring a large space for the lines and an increased
burden of control.
[0008] Further, even if the gases can be supplied from plural
portions in the processing chamber by a simple control operation,
when a flow rate ratio (distribution ratio) of the processing gases
supplied from the plural portions changes due to a pressure
variation, for example, during the introduction of the gases, the
desired in-surface uniformity cannot be achieved. Hence, it is
important to control the gas supply such that the process is
prevented from being influenced by effects from the pressure
variation and the like.
SUMMARY OF THE INVENTION
[0009] It is, therefore, an object of the present invention to
provide a gas supply system and the like, capable of achieving a
desired in-surface uniformity by supplying gases from plural
portions in a processing chamber with a simple line configuration
and a simple control operation.
[0010] In accordance with one aspect of the invention, there is
provided a gas supply system for supplying a gas into a processing
chamber for processing a substrate to be processed, the system
including:
[0011] a processing gas supply unit for supplying processing gas
for processing the substrate to be processed;
[0012] a processing gas supply line for allowing the processing gas
from the processing gas supply unit to flow therein;
[0013] a first and a second processing gas branch line branched
from the processing gas supply line to be connected with different
portions of the processing chamber;
[0014] a branch flow control unit for controlling branch flows of
the processing gas distributed from the processing gas supply line
to the first and the second processing gas branch line based on
inner pressures of the first and the second processing gas branch
line, respectively;
[0015] an additional gas supply unit for supplying additional
gas;
[0016] an additional gas supply line for allowing the additional
gas from the additional gas supply unit to flow therein;
[0017] a first additional gas branch line branched from the
additional gas supply line to be connected with the first
processing gas branch line at a downstream side of the branch flow
control unit;
[0018] a second additional gas branch line branched from the
additional gas supply line to be connected with the second
processing gas branch line at a downstream side of the branch flow
control unit;
[0019] a flow path switching unit for switching a flow path of the
additional gas from the additional gas supply line between the
first and the second additional gas branch line; and
[0020] a control unit for supplying, before processing the
substrate to be processed, the processing gas from the processing
gas supply unit while performing a pressure ratio control on the
branch flow control unit such that a pressure ratio between the
inner pressures of the first and the second processing gas branch
line is kept at a target pressure ratio, and then supplying the
additional gas from the additional gas supply unit after the inner
pressures of the first and the second processing gas branch line
become stable to be at a first and a second stable inner pressure,
wherein in case of supplying the additional gas to the second
processing gas branch line via the second additional gas branch
line, the additional gas is supplied from the additional gas supply
unit after the control unit switches the pressure ratio control on
the branch flow control unit to a first fixed pressure control that
controls the branch flows such that the first stable inner pressure
is maintained in the first processing gas branch line, whereas in
case of supplying the additional gas to the first processing gas
branch line via the first additional gas branch line, the
additional gas is supplied from the additional gas supply unit
after the control unit switches the pressure ratio control on the
branch flow control unit to a second fixed pressure control that
controls the branch flows such that the second stable inner
pressure is maintained in the second processing gas branch
line.
[0021] In accordance with another aspect of the invention, there is
provided a substrate processing apparatus including:
[0022] a processing chamber for processing a substrate to be
processed;
[0023] a gas supply system for supplying a gas into the processing
chamber; and
[0024] a control unit for controlling the gas supply system,
wherein the gas supply system includes: [0025] a processing gas
supply unit for supplying processing gas for processing the
substrate to be processed; [0026] a processing gas supply line for
allowing the processing gas from the processing gas supply unit to
flow therein; [0027] a first and a second processing gas branch
line branched from the processing gas supply line to be connected
with different portions of the processing chamber; [0028] a branch
flow control unit for controlling branch flows of the processing
gas distributed from the processing gas supply line to the first
and the second processing gas branch line based on inner pressures
of the first and the second processing gas branch line,
respectively; [0029] an additional gas supply unit for supplying
additional gas; [0030] an additional gas supply line for allowing
the additional gas from the additional gas supply unit to flow
therein; [0031] a first additional gas branch line branched from
the additional gas supply line to be connected with the first
processing gas branch line at a downstream side of the branch flow
control unit; [0032] a second additional gas branch line branched
from the additional gas supply line to be connected with the second
processing gas branch line at a downstream side of the branch flow
control unit; and [0033] a flow path switching unit for switching a
flow path of the additional gas from the additional gas supply line
between the first and the second additional gas branch line,
and
[0034] wherein the control unit supplies, before processing the
substrate to be processed, the processing gas from the processing
gas supply unit while performing a pressure ratio control on the
branch flow control unit such that a pressure ratio between the
inner pressures of the first and the second processing gas branch
line is kept at a target pressure ratio, and then supplies the
additional gas from the additional gas supply unit after the inner
pressures of the first and the second processing gas branch line
become stable to be at a first and a second stable inner pressure,
wherein in case of supplying the additional gas to the second
processing gas branch line via the second additional gas branch
line, the additional gas is supplied from the additional gas supply
unit after the control unit switches the pressure ratio control on
the branch flow control unit to a first fixed pressure control that
controls the branch flows such that the first stable inner pressure
is maintained in the first processing gas branch line, whereas in
case of supplying the additional gas to the first processing gas
branch line via the first additional gas branch line, the
additional gas is supplied from the additional gas supply unit
after the control unit switches the pressure ratio control on the
branch flow control unit to a second fixed pressure control that
controls the branch flows such that the second stable inner
pressure is maintained in the second processing gas branch
line.
[0035] In accordance with still another aspect of the invention,
there is provided a gas supply method for use with a gas supply
system for supplying a gas into a processing chamber for processing
a substrate to be processed, wherein the gas supply system includes
a processing gas supply unit for supplying processing gas for
processing the substrate to be processed; a processing gas supply
line for allowing the processing gas from the processing gas supply
unit to flow therein; a first and a second processing gas branch
line branched from the processing gas supply line to be connected
with different portions of the processing chamber; a branch flow
control unit for controlling branch flows of the processing gas
distributed from the processing gas supply line to the first and
the second processing gas branch line based on inner pressures of
the first and the second processing gas branch line, respectively;
an additional gas supply unit for supplying additional gas; an
additional gas supply line for allowing the additional gas from the
additional gas supply unit to flow therein; a first additional gas
branch line branched from the additional gas supply line to be
connected with the first processing gas branch line at a downstream
side of the branch flow control unit; a second additional gas
branch line branched from the additional gas supply line to be
connected with the second processing gas branch line at a
downstream side of the branch flow control unit; and a flow path
switching unit for switching a flow path of the additional gas from
the additional gas supply line between the first and the second
additional gas branch line, the method including the steps of:
[0036] supplying, before processing the substrate to be processed,
the processing gas from the processing gas supply unit while
performing a pressure ratio control on the branch flow control unit
such that a pressure ratio between the inner pressures of the first
and the second processing gas branch line is kept at a target
pressure ratio; and
[0037] supplying the additional gas from the additional gas supply
unit after the inner pressures of the first and the second
processing gas branch line become stable to be at a first and a
second stable inner pressure, wherein in case of supplying the
additional gas to the second processing gas branch line via the
second additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
first fixed pressure control that controls the branch flows such
that the first stable inner pressure is maintained in the first
processing gas branch line, whereas in case of supplying the
additional gas to the first processing gas branch line via the
first additional gas branch line, the additional gas is supplied
from the additional gas supply unit after the control unit switches
the pressure ratio control on the branch flow control unit to a
second fixed pressure control that controls the branch flows such
that the second stable inner pressure is maintained in the second
processing gas branch line.
[0038] In accordance with such aspects of the present invention,
the processing gas from the processing gas supply unit is
distributed into the first and the second branch line. The
processing gas distributed into any one of the processing gas
branch lines is supplied to the processing chamber as it is from
the processing gas supply unit, whereas the processing gas
distributed into the other processing gas branch line is added with
the additional gas and then supplied to the processing chamber with
adjusted gas components and flow rates. Accordingly, the processing
gas having components common to each of the processing gas branch
lines can be supplied from a common processing gas supply unit to
each of the processing gas branch lines and, also, the gas
components or the flow rates of the processing gas flowing in the
latter branch line can be adjusted by adding thereto the additional
gas on demand. Therefore, it is possible to minimize the number of
lines, which leads to a simple line configuration and a simple flow
rate control.
[0039] Since the branch flow control of the branch flow control
unit is switched from the pressure ratio control to the fixed
pressure control before supplying the additional gas, even if the
inner pressure of the latter processing gas branch line (e.g., the
second branch line) is changed due to the supply of the additional
gas, a part of the processing gas required to flow toward the
latter processing gas branch line can be prevented from flowing
toward the former processing gas branch line. Accordingly, the
ratio of the flow rates (distribution amounts) of the processing
gas distributed into the processing gas branch lines can be
prevented from being changed while supplying the additional gas. As
a result, the processing gas distributed at a target flow rate
ratio can be supplied to other regions on the surface of the
substrate, which leads to a desired in-surface uniformity.
[0040] Preferably, when the inner pressures of the first and the
second processing gas branch line become stable to be at a third
and a fourth stable inner pressure after supplying the additional
gas, the control unit sets a pressure ratio between the third and
the fourth stable inner pressure as a new target pressure ratio;
and switches the fixed pressure control on the branch flow control
unit to another pressure ratio control that controls the branch
flows such that a pressure ratio between the inner pressures of the
first and the second processing gas branch line is kept at the new
target pressure ratio. By switching the branch flow control of the
branch flow control unit from the fixed pressure control to the
pressure ratio control, the pressure ratio between the first and
the second processing gas branch line can be prevented from being
changed during a following processing of the substrate. This is
because when the conductance of the gas injection openings is
changed, the inner pressures of the first and the second processing
gas branch line are also changed. Accordingly, even when the
conductance of the gas injection openings is temporally changed, it
is possible to avoid a change of the ratio of the flow rates of the
processing gas flowing through the first and the second processing
gas branch line.
[0041] Preferably, the branch flow control unit has valves for
controlling flow rates of the processing gas flowing through the
first and the second processing gas branch line; and pressure
sensors that detect the inner pressures of the first and the second
processing gas branch line, respectively, wherein a ratio of the
flow rates of the processing gas flowing through the first and the
second processing gas branch line is controlled by controlling the
valves based on the inner pressures detected by the pressure
sensors.
[0042] Preferably, the processing gas supply unit has a plurality
of gas supply sources to supply to the processing gas supply line
the processing gas obtained by mixing gases from the gas supply
sources at a specific flow rate ratio. Preferably, the additional
gas supply unit has a number of gas supply sources to supply to the
additional gas supply line, the additional gas obtained by
selecting a gas from the gas supply sources or by mixing gases
therefrom at a specific gas flow rate ratio. Accordingly, the
processing gas having components common to each of the processing
gas branch lines can be supplied from a processing gas supply unit
to each of the processing gas branch lines and, also, the gas
components or the flow rates of the processing gas flowing in the
latter branch line can be adjusted by adding thereto the additional
gas on demand. Therefore, the number of lines can be minimized,
which leads to a simple line configuration and a simple flow rate
control.
[0043] Preferably, the first processing gas branch line is arranged
to supply the processing gas flowing therein toward a central
region on a surface of the substrate disposed in the processing
chamber; and the second processing gas branch line is arranged to
supply the processing gas flowing therein toward a peripheral
region on the surface of the substrate. Accordingly, it is possible
to improve uniformity in processing the central region and the
peripheral region of the substrate to be processed.
[0044] Preferably, the second processing gas branch line is
configured as plural branch lines branched from the processing gas
supply line, and the additional gas from the additional gas supply
unit is supplied to each of the plural branch lines. In this way,
the processing gas can be supplied to plural portions of the
peripheral region of the wafer, so that it is possible to more
precisely control the uniformity in processing the peripheral
region of the wafer.
[0045] In accordance with still another aspect of the present
invention, there is provided a gas supply system for supplying a
gas into a processing chamber for processing a substrate to be
processed, the system including:
[0046] a processing gas supply unit for supplying processing gas
for processing the substrate to be processed;
[0047] a processing gas supply line for allowing the processing gas
from the processing gas supply unit to flow therein;
[0048] a first and a second processing gas branch line branched
from the processing gas supply line to be connected with different
portions of the processing chamber;
[0049] a branch flow control unit for controlling branch flows of
the processing gas distributed from the processing gas supply line
to the first and the second processing gas branch line based on
inner pressures of the first and the second processing gas branch
line, respectively;
[0050] an additional gas supply unit for supplying additional
gas;
[0051] an additional gas supply line for allowing the additional
gas from the additional gas supply unit to flow therein;
[0052] a first additional gas branch line branched from the
additional gas supply line to be connected with the first
processing gas branch line at a downstream side of the branch flow
control unit;
[0053] a second additional gas branch line branched from the
additional gas supply line to be connected with the second
processing gas branch line at a downstream side of the branch flow
control unit; and
[0054] an opening/closing valve, provided on each of either one or
both of the first and the second additional gas branch line, for
opening and closing each of said either one or both of the
additional gas branch lines.
[0055] In accordance with the present invention, the flow path for
allowing the additional gas from the additional gas supply line to
flow therein can be switched by controlling the opening/closing
valves. Moreover, the additional gas can be supplied from the first
and the second additional gas branch line to the first and the
second processing gas branch line by providing opening/closing
valves on the first and the second additional gas branch line.
BRIEF DESCRIPTION OF THE DRAWINGS
[0056] The above and other objects and features of the present
invention will become apparent from the following description of
embodiments, given in conjunction with the accompanying drawings,
in which:
[0057] FIG. 1 is a cross sectional view showing a configuration
example of a substrate processing apparatus in accordance with an
embodiment of the present invention;
[0058] FIG. 2 offers a block diagram illustrating a configuration
example of a controller shown in FIG. 1;
[0059] FIG. 3 provides a block diagram describing a configuration
example of a gas supply system in accordance with the embodiment of
the present invention;
[0060] FIG. 4 presents a flowchart of an exemplary processing of
the substrate processing apparatus in accordance with the
embodiment of the present invention; and
[0061] FIGS. 5A and 5B represent a flowchart of another exemplary
processing of the substrate processing apparatus in accordance with
the embodiment of the present invention.
DETAILED DESCRIPTION OF THE EMBODIMENT
[0062] Hereinafter, embodiments of the present invention will be
described in detail with reference to the accompanying drawings.
Like reference numerals will be given to like parts having
substantially the same functions, and redundant description thereof
will be omitted in the specification and the accompanying
drawings.
[0063] (Configuration Example of Substrate Processing
Apparatus)
[0064] First of all, a substrate processing apparatus in accordance
with an embodiment of the present invention will be described with
reference to FIG. 1. FIG. 1 is a cross sectional view showing a
schematic configuration of the substrate processing apparatus in
accordance with the embodiment of the present invention. Herein,
the substrate processing apparatus is configured as a parallel
plate type plasma etching apparatus.
[0065] Such a substrate processing apparatus 100 includes a
processing chamber 110 formed of a substantially cylindrical
processing vessel. The processing vessel is made of aluminum alloy,
for example, and is electrically grounded. Further, an inner wall
surface of the processing vessel is coated with an alumina film or
an yttrium oxide film.
[0066] Disposed inside the processing chamber 110 is a susceptor
116 forming a lower electrode serving also as a mounting table for
mounting thereon a wafer W as a substrate. To be specific, the
susceptor 116 is supported on a cylindrical susceptor support 114
which is provided at a substantially central portion of an inner
bottom surface of the processing chamber 110 with an insulating
plate 112 disposed therebetween. The susceptor 116 is made of
aluminum alloy, for example.
[0067] Provided on the susceptor 116 is an electrostatic chuck 118
for supporting the wafer W. The electrostatic chuck 118 has therein
an electrode 120 that is electrically connected with a DC power
supply 122. Accordingly, the electrostatic chuck 118 can attract
and hold thereon the wafer W with the Coulomb force generated by a
DC voltage applied from the DC power supply 122 to the electrode
120.
[0068] Moreover, a focus ring 124 is provided on top of the
substrate 116 to surround the electrostatic chuck 118. Further, a
cylindrical inner wall member 126 made of quartz, for example, is
attached to outer peripheral surfaces of the susceptor 116 and the
susceptor support 114.
[0069] A ring-shaped coolant chamber 128 is formed inside the
susceptor support 114 to communicate with a chiller unit (not
shown), for example, installed outside the processing chamber 110
via lines 130a and 130b. A coolant (liquid coolant or cooling
water) is supplied to the coolant chamber 128 to be circulated
therein via the lines 130a and 130b, so that a temperature of the
wafer W on the susceptor 116 can be controlled.
[0070] A gas supply line 132 is provided through a top surface of
the electrostatic chuck 118 via the susceptor 116 and the susceptor
support 114. Accordingly, a thermally conductive gas (backside gas)
such as He gas or the like can be supplied between the wafer W and
the electrostatic chuck 118 through the gas supply line 132.
[0071] Provided above the susceptor 116 is an upper electrode 134
facing in parallel with the susceptor 116 forming the lower
electrode. A plasma generation space PS is formed between the
susceptor 116 and the upper electrode 134.
[0072] The upper electrode 134 includes a circular plate-shaped
inner upper electrode 138 and a ring-shaped outer upper electrode
136 surrounding an outer portion of the inner upper electrode 138.
A ring-shaped dielectric material 142 is interposed between the
outer upper electrode 136 and the inner upper electrode 138.
Airtightly interposed between the outer upper electrode 136 and an
inner peripheral wall of the processing chamber 110 is a
ring-shaped insulating shielding member 144 made of alumina, for
example.
[0073] A first high frequency power supply 154 is electrically
connected with the outer upper electrode 136 via a power feeder
152, a connector 150, an upper power supply rod 148 and a matching
unit 146. The first high frequency power supply 154 can output a
high frequency voltage having a frequency of 40 MHz or higher
(e.g., 60 MHz).
[0074] The power feeder 152 is formed in a substantially
cylindrical shape having an open bottom, for example, and has a
lower portion connected with the outer upper electrode 136. A lower
portion of the upper power supply rod 148 is electrically connected
with an upper central portion of the power feeder 152 through the
connector 150. An upper portion of the upper power supply rod 148
is connected with an output side of the matching unit 146. The
matching unit 146 is connected with the first high frequency power
supply 154 and thus can match an internal impedance of the first
high frequency power supply 154 to a load impedance.
[0075] An exterior of the power feeder 152 is covered with a
cylindrical ground conductor 111 having a sidewall of a diameter
substantially same as that of the processing chamber 110. A lower
portion of the ground conductor 111 is connected with an upper
portion of the sidewall of the processing chamber 110. The
aforementioned upper power supply rod 148 penetrates through an
upper central portion of the ground conductor 111. An insulation
member 156 is interposed at a contact portion between the ground
conductor 111 and the upper power supply rod 148.
[0076] The inner upper electrode 138 forms a shower head for
injecting a specific gas on the wafer W mounted on the susceptor
116. Further, the inner upper electrode 138 includes a circular
electrode plate 160 having a plurality of gas injection openings
160a and an electrode support 162 for attachably and detachably
supporting a top surface of the electrode plate 160. The electrode
support 162 is formed in a circular plate shape having a diameter
substantially same as that of the electrode plate 160.
[0077] The electrode support 162 forms therein a buffer chamber 163
of a circular plate-shaped space. An annular partition wall member
164 provided in the buffer chamber 163 partitions the buffer
chamber 163 into an inner and an outer buffer chamber, i.e., a
first buffer chamber 163a formed of a circular plate-shaped space
and a second buffer chamber 163b formed of a ring-shaped space
surrounding the first buffer chamber 163a. The annular partition
wall member 164 is formed of an O-ring, for example.
[0078] The first and the second buffer chamber 163a and 163b are
configured to respectively face a central region (central portion)
of the wafer W on the susceptor 116 and a peripheral region (edge
portion) thereof surrounding the central region.
[0079] The gas injection openings 160a communicate with bottom
surfaces of the buffer chambers 163a and 163b, thereby allowing a
specific gas to be injected through the first and the second buffer
chamber 163a and 163b to the central and the edge portion of the
wafer W, respectively. A gas supply system 200 is configured to
supply the specific gas to each of the buffer chambers 163a and
163b.
[0080] As shown in FIG. 1, a lower power feeder 170 is electrically
connected with a top surface of the electrode support 162. The
lower power feeder 170 is connected with the upper power supply rod
148 via the connector 150. A variable condenser 172 is provided in
the lower power feeder 170. By adjusting an electrostatic
capacitance of the variable condenser 172, it is possible to adjust
a comparative ratio between an intensity of an electric field
formed right under the outer upper electrode 136 and that of an
electric field formed right under the inner upper electrode 138,
the electric fields being formed by the high frequency voltage
applied from the first high frequency power supply 154.
[0081] A gas exhaust port 174 is formed at a bottom portion of the
processing chamber 110 and connected via a gas exhaust line 176
with a gas exhaust unit 178 having a vacuum pump and the like. By
exhausting an inside of the processing chamber 110 with the use of
the gas exhaust unit 178, the inside of the processing chamber 110
can be depressurized to a desired vacuum level.
[0082] A second high frequency power supply 182 is electrically
connected with the susceptor 116 via a matching unit 180. The
second high frequency power supply 182 can output a high frequency
voltage having a frequency between 2 MHz and 20 MHz, e.g., a
frequency of 2 MHz.
[0083] A low pass filter 184 is electrically connected with the
inner upper electrode 138 of the upper electrode 134. The low pass
filter 184 blocks the high frequency power from the first high
frequency power supply 154 and passes the high frequency from the
second high frequency power supply 182 to the ground. Meanwhile, a
high pass filter 186 is electrically connected with the susceptor
116 forming the lower electrode. The high pass filter 186 passes
the high frequency power from the first high frequency power supply
154 to the ground.
[0084] (Gas Supply System)
[0085] Hereinafter, the gas supply system 200 will be described
with reference to FIG. 1. Referring to FIG. 1, there is shown an
example in which the processing gas is divided into a first
processing gas (processing gas for the central portion) to be
supplied toward the central portion of the wafer W and a second
processing gas (processing gas for the edge portion) to be supplied
toward the edge portion of the wafer W. However, there may be
provided another example in which the processing gas is divided
into more than three types without being limited to the
aforementioned two types.
[0086] As shown in FIG. 1, the gas supply system 200 includes a
processing gas supply unit 210 for supplying processing gas for
performing on a wafer a specific process such as a film formation
process, an etching process or the like and an additional gas
supply unit 220 for supplying specific additional gas.
[0087] The processing gas supply unit 210 is connected with a
processing gas supply line 252 forming a processing gas feed
passage. The processing gas supply line 252 is provided with an
opening/closing valve 262 for opening and closing the processing
gas supply line 252. Further, the processing gas supply line 252 is
branched into a first processing gas branch line 254 forming a
first processing gas branch path (hereinafter, referred to as
"first branch line 254") and a second processing gas branch line
256 forming a second processing gas branch path (hereinafter,
referred to as "second branch line 256").
[0088] The first and the second processing gas branch line 254 and
256 are respectively connected with different portions of the upper
electrode 134 in the processing chamber 110, e.g., with the first
and the second buffer chamber 163a and 163b of the inner upper
electrode 138. Further, the first and the second processing gas
branch line 254 and 256 may be branched at a position inside or
outside a branch flow control unit 230 to be described later.
[0089] The gas supply system 200 includes the branch flow control
unit (e.g., flow splitter) 230 for controlling respective branch
flows of the first and the second processing gas flowing in the
first and the second processing gas branch line 254 and 256 based
on respective inner pressures of the first and the second branch
line 254 and 256.
[0090] The additional gas supply unit 220 is connected with an
additional gas supply line 272 forming an additional gas feed
passage. The additional gas supply line 272 is provided with an
opening/closing valve 282 for opening and closing the additional
gas supply line 272. The additional gas supply line 272 is branched
into a first additional gas branch line 274 forming a first
additional gas branch path (hereinafter, referred to as "first
branch line 274") and a second additional gas branch line 276
forming a second additional gas branch path (hereinafter, referred
to as "second branch line 276").
[0091] The first and the second additional gas branch line 274 and
276 are respectively connected with the first and the second
processing gas branch line 254 and 256 at positions in a downstream
side of the branch flow control unit 230. The first additional gas
branch line 274 is provided with an opening/closing valve 284 for
opening and closing the first additional gas branch line 274. The
second additional gas branch line 276 is provided with an
opening/closing valve 286 for opening and closing the second
additional gas branch line 276. By controlling the opening/closing
valves 284 and 286, the additional gas from the additional gas
supply unit 220 can be selectively supplied either to the first
branch line 274 or to the second branch line 276. The
opening/closing valves 284 and 286 form a flow path switching unit
for switching the additional gas branch paths.
[0092] The gas supply system 200 distributes the processing gas
from the processing gas supply unit 210 into the first and the
second processing gas branch line 254 and 256 while controlling
branch flows thereof with the use of the branch flow control unit
230. The first processing gas flowing in the first branch line 254
is supplied toward the central portion of the wafer W via the first
buffer chamber 163a, whereas the second processing gas flowing in
the second branch line 256 is supplied toward the edge portion of
the wafer W via the second buffer chamber 163b.
[0093] In case the additional gas is supplied to the second
processing gas branch line 256, the supply of the additional gas
from the additional gas supply unit 220 is initiated by opening the
opening/closing valve 286 of the second additional gas branch line
276 while closing the opening/closing valve 284 of the first
additional gas branch line 274. Accordingly, the additional gas
flows toward the second processing gas branch line 256 via the
additional gas supply line 272 and the second additional gas branch
line 276 and thus are mixed with the second processing gas. Then,
the additional gas is supplied, together with the second processing
gas, toward the edge portion of the wafer W via the second buffer
chamber 163b.
[0094] On the other hand, in case the additional gas is supplied to
the first processing gas branch line 254, the supply of the
additional gas from the additional gas supply unit 220 is initiated
by opening the opening/closing valve 284 of the first additional
gas branch line 274 while closing the opening/closing valve 286 of
the second additional gas branch line 276. Accordingly, the
additional gas flows toward the first processing gas branch line
254 via the additional gas supply line 272 and the first additional
gas branch line 274 and thus is mixed with the first processing
gas. Then, the additional gas is supplied, together with the first
processing gas, toward the central portion of the wafer W via the
first buffer chamber 163a. A specific configuration example of the
gas supply system 200 will be described later.
[0095] The substrate processing apparatus 100 is connected with a
controller 300 for controlling each unit thereof. The controller
300 is configured to control the DC power supply 122, the first
high frequency power supply 154, the second high frequency power
supply 182 and the like in addition to the gas supply system 200
including the processing gas supply unit 210, the additional gas
supply unit 220, the branch flow control unit 230 and the like.
[0096] (Configuration Example of Controller)
[0097] Hereinafter, the configuration example of the controller 300
will be described with reference to FIG. 2. FIG. 2 provides a block
diagram showing a configuration example of the controller 300. As
shown in FIG. 2, the controller 300 includes a CPU (central
processing unit) 310 forming a controller main body; a RAM (random
access memory) 320 having a memory area used for various data
processing performed by the CPU 310; a display unit 330 formed of a
liquid crystal display and the like for displaying an operation
screen, a selection screen and the like; an operation unit 340
containing a touch panel and the like for allowing an operator to
input or edit various data such as process recipes and the like and
to output various data such as the process recipes or process logs
to a specific storage medium; a storage unit 350; and an interface
360.
[0098] The storage unit 350 stores therein, e.g., processing
programs for performing various processes of the substrate
processing apparatus 100, information (data) required for executing
the processing programs and the like. Such a storage unit 350
includes, e.g., a memory, an HDD (hard disk drive) and the like.
The CPU 310 reads the program data and the like on demand and
executes various processing programs. For example, the CPU 310
controls the gas supply system 200 to perform a gas supply process
for supplying a specific gas into the processing chamber 110 before
processing the wafer.
[0099] The interface 360 is connected with each unit controlled by
the CPU 310, such as the branch flow control unit 230, the
processing gas supply unit 210, the additional gas supply unit 220
and the like. The interface 360 includes a plurality of I/O ports
and the like, for example.
[0100] The CPU 310, the RAM 320, the display unit 330, the
operation unit 340, the storage unit 350, and the interface 360 are
connected with each other by bus lines such as a control bus, a
data bus and the like.
[0101] (Specific Configuration Example of Gas Supply System)
[0102] The following is a detailed description on a configuration
example of each unit of the gas supply system 200. FIG. 3 is a
block diagram illustrating a specific configuration example of the
gas supply system 200. As shown in FIG. 3, the processing gas
supply unit 210 includes a gas box accommodating therein a
plurality of (e.g., three) gas supply sources 212a, 212b and 212c.
Lines of the gas supply sources 212a to 212c are connected with the
processing gas supply line 252 where gases from the gas supply
sources 212a to 212c are joined. Provided on the lines of the gas
supply sources 212a to 212c are mass flow controllers 214a to 214c
for adjusting respective flow rates of the gases therefrom. The
gases from the gas supply sources 212a to 212c of the processing
gas supply unit 210 are mixed at a preset flow rate ratio. Next,
the mixed gas flows along the processing gas supply line 252 and
then is distributed into the first and the second branch line 254
and 256.
[0103] As shown in FIG. 3, the gas supply source 212a airtightly
seals therein, e.g., a C.sub.XF.sub.Y gas (a fluorocarbon-based
fluorine compound such as CF.sub.4, C.sub.4F.sub.6, C.sub.4F.sub.8,
C.sub.5F.sub.8 or the like) as an etching gas; the gas supply
source 212b airtightly seals therein, e.g., an O.sub.2 gas as a gas
for controlling a deposition of CF-based reaction products; and the
gas supply source 212c airtightly seals therein, e.g., an Ar gas as
a rare gas serving as a carrier gas. The number of gas supply
sources of the processing gas supply unit 210 may be one, two or
more than four without being limited to the example shown in FIG.
3.
[0104] As exemplarily shown in FIG. 3, the additional gas supply
unit 220 includes a gas box accommodating therein a plurality of
(e.g., two) gas supply sources 222a and 222b. Lines of the gas
supply sources 222a and 222b are connected with the additional gas
supply line 272 where gases from the gas supply sources 222a and
222b are joined. Provided on the lines of the gas supply sources
222a and 222b are mass flow controllers 224a and 224b for adjusting
respective flow rates of the gases therefrom. One of the gases from
the gas supply sources 222a and 222b of the additional gas supply
unit 220 is selected or both of them are mixed at a preset flow
rate ratio. Next, the selected or the mixed gas flows along the
additional gas supply line 272 and then is supplied either to the
first processing gas branch line 254 or to the second processing
gas branch line 256 at a downstream side of the branch flow control
unit 230.
[0105] The gas supply source 222a airtightly seals therein a
C.sub.XF.sub.Y gas capable of facilitating an etching, for example.
The gas supply source 222b airtightly seals therein an O.sub.2 gas
capable of controlling a deposition of CF-based reaction products,
for example. The number of gas supply sources of the additional gas
supply unit 220 may be one or more than three without being limited
to the example shown in FIG. 3.
[0106] The branch flow control unit 230 includes a pressure control
unit 232 for controlling an inner pressure of the first processing
gas branch line 254 and a pressure control unit 234 for controlling
an inner pressure of the second processing gas branch line 256. To
be specific, the pressure control unit 232 has a pressure sensor
232a for detecting an inner pressure of the first processing gas
branch line 254 and a valve 232b for controlling an open-close
degree of the first processing gas branch line 254. The pressure
controller 234 has a pressure sensor 234a for detecting an inner
pressure of the second processing gas branch line 256 and a valve
234b for controlling an open-close degree of the second processing
gas branch line 256.
[0107] The pressure control units 232 and 234 are connected with a
pressure controller 240 for controlling, in accordance with
instructions from the controller 300, open-close degrees of the
valves 232b and 234b based on the pressures detected by the
pressure sensors 232a and 234a, respectively. The controller 300
controls the branch flow control unit 230 by regulating a pressure
ratio, for example. In such a case, the pressure controller 240
controls respective open-close degrees of the valves 232b and 234b
to achieve a target flow rate ratio between the first and the
second processing gas in accordance with instructions from the
controller 300, i.e., a target pressure ratio between the inner
pressures of the first and the second processing gas branch line
254 and 256. The pressure controller 240 may be built in the branch
flow control unit 230, as a control board, or may be provided
separately from the branch flow control unit 230. Further, the
pressure controller 240 may be provided inside the controller
300.
[0108] In such a substrate processing apparatus 100, before an
etching process and the like are performed on the wafer, the gas
supply system 200 supplies a specific gas into the processing
chamber 110. To be specific, the supply of the processing gas from
the processing gas supply unit 210 is initiated and, then, the
branch flow control unit 230 is pressure-ratio-controlled. After
the pressure ratio between the inner pressures of the first and the
second processing gas branch line 254 and 256 is regulated to be
kept at the target pressure ratio, the additional gas from the
additional gas supply unit 220 is supplied either to the first
processing gas branch line 254 or to the second processing gas
branch line 256.
[0109] However, problems can develop when the additional gas is
supplied either to the first processing gas branch line 254 or to
the second processing gas branch line 256 while the branch flow
control unit 230 being pressure-ratio-controlled. For example, in
case the additional gas is supplied to the second processing gas
branch line 256, the inner pressure of the second branch line 256
becomes higher than that of the first branch line 254 and,
accordingly, the pressure ratio therebetween is changed. In order
to regain the target pressure ratio, the branch flow control unit
230 automatically controls to adjust respective open-close degrees
of the valves 232b and 234b and, thus, the flow rate of the first
processing gas may be increased from the value set before the
supply of the additional gas. As a result, the flow rate ratio
between the first and the second processing gas is changed by
supplying the additional gas.
[0110] To that end, the additional gas is supplied after fixing the
valves 232b and 234b of the branch flow control unit 230 in a state
where the respective inner pressures of the first and the second
processing gas branch line 254 and 256 are stable by regulating a
pressure ratio therebetween to be kept at a target pressure ratio.
In such a case, even if the additional gas is supplied, the valves
232b and 234b are not automatically driven, so that it is possible
to prevent the change of the flow rate ratio between the first and
the second processing gas.
[0111] Since, however, the supply of the additional gas increases
the inner pressure of the second processing gas branch line 256, if
the valves 232b and 234b of the branch flow control unit 230 are
fixed as described above, it makes difficult for the processing gas
flow toward the second processing branch line 256 and it rather
makes easy for them flow toward the first branch line 254.
Consequently, even if the valves 232b and 234b of the branch flow
control unit 230 are fixed, the flow rate ratio between the first
and the second processing gas is changed by supplying the
additional gas.
[0112] The same problems can develop when the additional gas is
supplied to the first processing gas branch line 254. In other
words, since the supply of the additional gas increases the inner
pressure of the first processing gas branch line 254, if the valves
232b and 234b of the branch flow control unit 230 are fixed as
described above, it is difficult for the processing gas to flow
toward the first branch line 254 and easy for them to flow toward
the second branch line 256. Thus, the flow rate ratio of the first
and the second processing gas is changed by supplying the
additional gas.
[0113] In order to solve the aforementioned problems, in the gas
supply process of the present invention, before the additional gas
is supplied, a branch flow control of the branch flow control unit
230 is switched from a pressure ratio control for maintaining at a
target pressure ratio inner pressures of the first and the second
processing gas branch line 254 and 256 to a fixed pressure control
for fixedly maintaining an inner pressure of any one of the first
and the second processing gas branch line 254 and 256.
Specifically, in case the additional gas is supplied to the first
processing gas branch line 254, the supply of the additional gas is
initiated after switching the branch flow control mode to a control
mode for fixedly maintaining an inner pressure of the second
processing branch line 256. Further, in case the additional gas is
supplied to the second processing gas branch line 256, the supply
of the additional gas is initiated after switching the branch flow
control mode to a control mode for fixedly maintaining an inner
pressure of the first processing gas branch line 254.
[0114] Accordingly, the inner pressure of any one of the branch
lines (e.g., the first processing gas branch line 254) is fixedly
maintained despite the supply of the additional gas. Therefore,
even if the inner pressure of the other branch line (e.g., the
second processing gas branch line 256) is changed, the processing
gas can flow toward the latter branch line (e.g., the second
processing gas branch line 256) without flowing toward the former
branch line (e.g., the first processing gas branch line 254). As a
result, the flow rate ratio between the first and the second
processing gas can be prevented from being changed by supplying the
additional gas to any one of the branch lines 254 and 256.
[0115] (Specific Example of Gas Supply Process)
[0116] The following is a description on a specific example of a
gas supply process in accordance with an embodiment of the present
invention. FIG. 4 presents a flowchart showing specific exemplary
processes of a substrate processing apparatus, including the gas
supply process in accordance with this embodiment. First of all,
the controller 300 controls, in a step S110, the processing gas
supply unit 210 to supply processing gas by opening the
opening/closing valve 262. Accordingly, preset gases are supplied
from the processing gas supply unit 210 to the processing gas
supply line 252 at respective specific flow rates. To be specific,
the C.sub.XF.sub.Y gas, the O.sub.2 gas and the Ar gas, for
example, from the gas supply sources 212a to 212c are supplied at
respective specific flow rates and then mixed at a preset mixing
ratio. Thus generated gaseous mixture flows as a processing gas
along the processing gas supply line 252.
[0117] Next, the controller 300 controls, in a step S120, the
branch flow control unit 230 to control branch flows of the
processing gas by regulating a pressure ratio. To be specific, when
the controller 300 issues instructions for a pressure ratio
control, the branch flow control unit 230 adjusts, based on the
pressures detected by the pressure sensors 232a and 234a,
respective open-close degrees of the valves 232b and 234b by
controlling the pressure controller 240, thereby regulating to be
kept at a target pressure ratio the pressure ratio between the
first and the second processing gas branch line 254 and 256.
Accordingly, a flow rate ratio between the first and the second
processing gas is determined, the first and the second processing
gas being supplied to the first and the second chamber 163a and
163b via the first and the second processing gas branch line 254
and 256, respectively.
[0118] Thereafter, in a step S130, it is determined whether the
respective inner pressures of the first and the second processing
gas branch line 254 and 256 are stable or not. If it is determined
that the respective inner pressures thereof are stable, it is
determined in a step S140 whether the additional gas is supplied to
the first processing gas branch line 254 or to the second
processing gas branch line 256. To be specific, it is determined
whether or not the additional gas is supplied to the second
processing gas branch line 256, for example.
[0119] If it is determined in the step S140 that the additional gas
is supplied to the second processing branch line 256, the
controller 300 controls, in a step S150, the branch flow control
unit 230 to adjust branch flows of the processing gas by fixedly
maintaining an inner pressure of the first processing gas branch
line 254.
[0120] To be specific, when the controller 300 issues instructions
for a fixed pressure control of the inner pressure of the first
processing gas branch line 254, the branch flow control unit 230
adjusts, based on the pressures detected by the pressure sensors
232a and 234a, respective open-close degrees of the valves 232b and
234b by controlling the pressure controller 240, thereby fixedly
maintaining the inner pressure of the first processing gas branch
line 254. At least at this time, the second buffer chamber 163b is
supplied with a gaseous mixture having the same gas components as
those supplied in the first buffer chamber 163a (the gaseous
mixture capable of performing the same etching process).
[0121] Next, in a step S160, an additional gas is supplied via the
second additional gas branch line 276 by controlling the
opening/closing valves 284 and 286. To be specific, the supply of
the additional gas from the additional gas supply unit 220 is
initiated by opening the opening/closing valve 282 while closing
the opening/closing valve 284 of the first additional gas branch
line 274 and opening the opening/closing valve 286 of the second
additional gas branch line 276. Accordingly, preset additional gas
is supplied from the additional gas supply unit 220 to the second
processing gas branch line 256 at respective specific flow
rates.
[0122] At this time, a C.sub.XF.sub.Y gas (e.g., CF.sub.4 gas)
capable of facilitating the etching is supplied at a specific flow
rate from the additional gas supply unit 220a to the second buffer
chamber 163b via the second branch line 256. Accordingly, the
second buffer chamber 163b is supplied with the processing gas
containing a large amount of CF.sub.4 gas compared with that
contained in processing gas supplied to the first buffer chamber
163a. In this way, the gas components and the flow rate of the
processing gas to be supplied to the second buffer chamber 163b are
determined.
[0123] On the other hand, in case it is determined in the step S140
that the additional gas is supplied to the first processing gas
branch line 254, the controller 300 controls, in a step S170, the
branch flow control unit 230 to adjust branch flows of the
processing gas by fixedly maintaining an inner pressure of the
second processing gas branch line 256.
[0124] To be specific, when the controller 300 issues instructions
for a fixed pressure control of the inner pressure of the second
processing gas branch line 256, the branch flow control unit 230
adjusts, based on the pressures detected by the pressure sensors
232a and 234a, respective open-close degrees of the valves 232b and
234b by controlling the pressure controller 240, thereby fixedly
maintaining the inner pressure of the second processing gas branch
line 256.
[0125] Next, in a step S180, an additional gas is supplied via the
first additional gas branch line 274 by controlling the
opening/closing valves 284 and 286. To be specific, the supply of
the additional gas from the additional gas supply unit 220 is
initiated by opening the opening/closing valve 282 while closing
the opening/closing valve 286 of the second additional gas branch
line 276 and opening the opening/closing valve 284 of the first
additional gas branch line 274. Accordingly, preset additional gas
is supplied from the additional gas supply unit 220 to the first
processing gas branch line 254 at respective specific flow
rates.
[0126] Thereafter, in a step S190, it is determined whether the
inner pressures of the first and the second branch line 254 and 256
are stable or not. If it is determined in the step S190 that the
respective inner pressures thereof are stable, the wafer is
processed in a step S300.
[0127] In case the additional gas is supplied to the second
processing gas branch line 256 by the aforementioned gas supply
process, in the substrate processing apparatus 100, the gaseous
mixture of the processing gas is supplied from the first buffer
chamber 163a to a vicinity of the central region of the wafer W on
the susceptor 116 under the depressurized atmosphere and, also, the
gaseous mixture of the processing gas and the additional gas (e.g.,
the gaseous mixture containing a large amount of CF.sub.4 gas) is
supplied from the second buffer chamber 163b to the peripheral
region (edge portion) of the wafer W. Accordingly, etching
characteristics on the peripheral region (edge portion) of the
wafer W are controlled to be comparatively adjusted with respect to
those on the central region (central portion) of the wafer W, which
results in an in-surface uniformity of etching the wafer W.
[0128] On the other hand, in case the additional gas is supplied to
the first processing gas branch line 254, the gaseous mixture of
the processing gas and the additional gas is supplied from the
first buffer chamber 163a to a vicinity of the central region of
the wafer W on the susceptor 116, whereas the gaseous mixture of
the processing gas is supplied from the second buffer chamber 163b
to the peripheral region (edge portion) of the wafer W.
Accordingly, etching characteristics on the central region (center
portion) of the wafer W are controlled to be comparatively adjusted
with respect to those on the peripheral region (edge portion) of
the wafer W, which results in an in-surface uniformity of etching
the wafer W.
[0129] Referring to the processes shown in FIG. 4, the processing
gas from the processing gas supply unit 210 is distributed into the
first and the second branch line 254 and 256. The processing gas
distributed into any one of the processing gas branch lines (e.g.,
the first branch line 254) is supplied to the processing chamber
110 as it is supplied from the processing gas supply unit 210,
whereas the processing gas distributed into the other processing
gas branch line (e.g., the second branch line 256) is added thereto
with the additional gas and then supplied to the processing chamber
110 with adjusted gas components and flow rates. Accordingly, the
processing gas having components common to the processing gas
branch lines 254 and 256 can be supplied from the processing gas
supply unit 210 to each of the processing gas branch lines 254 and
256 and, also, the gas components or the ratio of the flow rates of
the processing gas flowing in the latter branch line (e.g., the
second branch line 256) can be adjusted by adding thereto the
additional gas on demand.
[0130] Therefore, when the processing gas distributed into the
processing gas branch lines has a large number of common
components, the number of lines is reduced compared with a case
where each of the gas supply sources has its own branch line. By
minimizing the number of lines of the gas supply system 200, the
gas supply system 200 can be configured with a simple line
configuration. Further, since the branch flows of the processing
gas are controlled based on the respective inner pressures of the
processing gas branch lines 254 and 256, the gas can be supplied
from plural portions in the processing chamber 110 with a simple
control operation.
[0131] By simply switching, before supplying the additional gas,
the branch flow control of the branch flow control unit 230 from
the pressure ratio control to the fixed pressure control, even when
a pressure ratio between the first and the second processing gas
branch line 254 and 256 is changed due to the supply of the
additional gas, the branch flow control unit 230 can control the
valves 232b and 234b to fixedly maintain an inner pressure of one
of the processing gas branch lines (e.g., the first branch line
254).
[0132] Therefore, a part of the processing gas required to flow
toward the latter branch line (e.g., the second processing gas
branch line 256) can be prevented from flowing toward the former
branch line (e.g., the first processing gas branch line 254).
Accordingly, it is possible to prevent the ratio of the flow rates
of the processing gas supplied from the branch flow control unit
230 to the processing gas branch lines from being changed due to
supplying the additional gas, which results in realizing the
desired in-surface uniformity.
[0133] Although FIG. 4 shows a case where the wafer is processed
while holding the branch flow control unit 230
fixed-pressure-controlled as switched in the step S150 or S170, the
branch flow control of the branch flow control unit 230 may be
switched back to the pressure ratio control before processing the
wafer.
[0134] For example, while a single wafer is processed or a number
of wafers are consecutively processed, a temperature of the upper
electrode 134 can gradually rise to thereby increase a conductance
of the gas injection openings 160a, which hinders a gas flow.
[0135] In such a case, since inner pressures of the first and the
second processing gas branch line 254 and 256 are to be increased,
if the branch flow control mode of the branch flow control unit 230
remains to be at the fixed pressure control, the valves 232b and
234b are adjusted to fixedly maintain an inner pressure of only one
of the processing gas branch lines (e.g., the first branch line
254). Hence, the amount of the processing gas flowing toward the
other processing gas branch line (e.g., the second branch line 256)
will be gradually increased relative to that of the processing gas
flowing toward the former processing gas branch line (e.g., the
first branch line 254), which leads to a change of the ratio of the
flow rates of the processing gas flowing toward the processing gas
branch lines.
[0136] To this end, the branch flow control can be switched back to
the pressure ratio control before processing the wafer. By
switching the branch flow control of the branch flow control unit
230 from the fixed pressure control to the pressure ratio control,
the pressure ratio between the first and the second processing gas
branch line 254 and 256 can be prevented from being changed. This
is because if the conductance of the gas injection openings 160a is
changed, the respective inner pressures of the first and the second
processing gas branch line 254 and 256 are also changed.
Accordingly, even when the conductance of the gas injection
openings 160a is temporally changed, the ratio of the flow rates of
the processing gas flowing toward the first and the second
processing gas branch line 254 and 256 can be prevented from being
changed.
[0137] To be specific, processes of steps S210 and S220 are added
to be performed before the process of the step S300 as shown in
FIGS. 5A and 5B. Referring to the processes shown in FIGS. 5A and
5B, if it is determined in the step S190 that the respective inner
pressures of the first and the second processing gas branch line
254 and 256 are stable, the controller 300 switches, in the step
S210, the branch flow control of the branch flow control unit 230
to the pressure ratio control. Specifically, a pressure ratio
obtained when the respective inner pressures of the first and the
second processing gas branch line 254 and 256 are stable is set to
be as a new target pressure ratio. Then, the branch flow control of
the branch flow control unit 230 is switched to the pressure ratio
control in which respective branch flows are controlled to regulate
the pressure ratio between the inner pressures of the first and the
second processing gas branch line 254 and 256 to be kept at the new
target pressure ratio. If additional gas is supplied to any one of
the processing gas branch lines, an inner pressure of the
corresponding processing gas branch line is changed. Therefore, the
pressure ratio needs to be controlled by taking such a pressure
change into consideration. Accordingly, the branch flow control
unit 230 can adjust the respective branch flows of the first and
the second processing gas without changing a flow rate ratio
therebetween. For such reasons, the pressure ratio obtained when
the respective inner pressures of the first and the second
processing gas branch line 254 and 256 are stable is set to be as a
new target pressure ratio.
[0138] Next, it is checked in the step S220 whether or not the
respective inner pressures of the first and the second processing
gas branch line 254 and 256 are stable. If it is determined in the
step S220 that the inner pressures thereof are stable, the wafer is
processed in the step S300.
[0139] Referring to the processes shown in FIGS. 5A and 5B, even
when the conductance of the gas injection openings 160a of the
upper electrode 134 is changed during the processing of the wafer,
the processing of the wafer can be performed while preventing a
variation of the flow rate ratio between the first and the second
processing gas.
[0140] The second processing gas branch line 256 of the
aforementioned embodiment may be configured as a plurality of
branch lines branched from the processing gas supply line 252 so
that the additional gas from the additional gas supply unit 220 can
be respectively supplied to the second branch lines. In such a
case, the processing gas can be supplied separately to plural
portions of the peripheral region of the wafer, so that it is
possible to more precisely control the uniformity of processing the
peripheral region of the wafer.
[0141] Although the aforementioned embodiment describes a case
where the processing gas supplied from the gas supply system 200 is
injected from an upper portion of the processing chamber 110 toward
the wafer W, there may be provided, without being limited thereto,
another case where the processing gas is injected from, e.g., a
side surface of a plasma generation space PS in the processing
chamber 110, other portions of the processing chamber 110. In such
a case, since specific processing gas can be supplied from an upper
portion and a side portion of the plasma generation space PS, it is
possible to control a gas concentration in the plasma generation
space PS, which leads to an improved in-surface uniformity in
processing the wafer.
[0142] Further, the aforementioned embodiment describes a case
where a flow path for allowing the additional gas from the
additional gas supply line 272 to flow is switched by opening and
closing the opening/closing valves 284 and 286 respectively
provided on the first and the second additional gas branch line 274
and 276. However, there may be provided, without being limited
thereto, another case where a flow path for allowing the additional
gas from the additional gas supply line 272 to flow is switched by
opening and closing another opening/closing valve provided as an
example of a flow path switching unit on any one of the first and
the second additional gas branch line 274 and 276.
[0143] In the aforementioned embodiment, the opening/closing valves
284 and 286 are respectively provided on the first and the second
additional gas branch line 274 and 276, so that the additional gas
can be supplied from the first and the second additional gas branch
line 274 and 276 to the first and the second processing gas branch
line 254 and 256, respectively. In such a case, each of the first
and the second additional gas branch line 274 and 276 may be
provided with a flow rate control unit such as a mass flow
controller or the like. Accordingly, it is possible to precisely
control respective flow rates of the additional gas flowing toward
the first and the second additional gas branch line 274 and
276.
[0144] The aforementioned embodiment describes a case in which
pressure control units control branch flows of the processing gas
flowing toward the processing gas branch lines. However, there may
be provided, without being limited thereto, another case in which
mass flow controllers control the branch flows of the processing
gas flowing toward the processing gas branch lines. Further,
although the present invention is applied to a plasma etching
apparatus as a substrate processing apparatus in the aforementioned
embodiment, the present invention may be applied to another
substrate processing apparatus where a processing gas is supplied,
e.g., a film forming apparatus such as a plasma CVD apparatus, a
sputtering apparatus, a thermal oxidation apparatus or the like.
Moreover, the present invention may be applied to a MEMS (micro
electro mechanical system) manufacturing apparatus or another
substrate processing apparatus for processing as a target substrate
an FPD (flat-panel display), a photomask reticle or the like, other
than a wafer.
[0145] The present invention may be applied to a gas supply system
for supplying processing gas to a processing chamber, a substrate
processing apparatus and a gas supply method.
[0146] As described above, the present invention can provide the
gas supply system and the like, capable of achieving desired
in-surface uniformity by supplying gas from plural portions in the
processing chamber with a simple line configuration and a simple
control operation.
[0147] While the invention has been shown and described with
respect to the embodiments, it will be understood by those skilled
in the art that various changes and modification may be made
without departing from the scope of the invention as defined in the
following claims.
* * * * *