U.S. patent application number 10/170925 was filed with the patent office on 2003-12-18 for plasma method and apparatus for processing a substrate.
Invention is credited to Chua, Thai Cheng, Cruse, James P., Holland, John, Kraus, Philip Allan.
Application Number | 20030232513 10/170925 |
Document ID | / |
Family ID | 29711042 |
Filed Date | 2003-12-18 |
United States Patent
Application |
20030232513 |
Kind Code |
A1 |
Kraus, Philip Allan ; et
al. |
December 18, 2003 |
PLASMA METHOD AND APPARATUS FOR PROCESSING A SUBSTRATE
Abstract
According to one aspect of the invention, a method is provided
of processing a substrate, including locating the substrate in a
processing chamber, creating a nitrogen plasma in the chamber, the
plasma having an ion density of at least 10.sup.10 cm.sup.-3, and a
potential of less than 20 V, and exposing a layer on the substrate
to the plasma to incorporate nitrogen of the plasma into the
layer.
Inventors: |
Kraus, Philip Allan; (San
Jose, CA) ; Chua, Thai Cheng; (San Jose, CA) ;
Holland, John; (San Jose, CA) ; Cruse, James P.;
(Capitola, CA) |
Correspondence
Address: |
APPLIED MATERIALS, INC.
2881 SCOTT BLVD. M/S 2061
SANTA CLARA
CA
95050
US
|
Family ID: |
29711042 |
Appl. No.: |
10/170925 |
Filed: |
June 12, 2002 |
Current U.S.
Class: |
438/787 ;
156/345.48; 257/E21.268; 257/E21.293; 257/E21.576; 438/792 |
Current CPC
Class: |
H01J 37/321 20130101;
H01L 21/3185 20130101; H01L 21/0234 20130101; H01L 21/3144
20130101; H01L 21/02332 20130101 |
Class at
Publication: |
438/787 ;
438/792; 156/345.48 |
International
Class: |
H01L 021/306; H01L
021/31; H01L 021/469 |
Claims
What is claimed:
1. A method of processing a substrate, comprising: creating a
nitrogen-containing plasma in the chamber, the plasma having an ion
density of at least 10.sup.10 cm.sup.-3 and a plasma potential of
less than 20 V; and exposing a layer on the substrate to the plasma
to incorporate nitrogen of the plasma into the layer on the
substrate.
2. The method of claim 1, wherein the plasma has an electron
temperature of less than 2 eV.
3. The method of claim 1, wherein the layer is silicon dioxide.
4. The method of claim 1, wherein RF current is provided to a coil
located externally adjacent to a dielectric wall of the chamber,
the coil creating an RF field in the chamber, the RF field creating
the plasma.
5. The method of claim 4, wherein an electrode is positioned
between the coil and the dielectric wall, the electrode being
grounded.
6. The method of claim 5, wherein the electrode reduces the plasma
potential to less than 10 V.
7. The method of claim 6, wherein the wall is dome-shaped, the coil
spirals around an axis through the wall, and the electrode has an
opening therein.
8. The method of claim 7, wherein the opening is within the
perimeter described by the coil.
9. The method of claim 4, wherein the amplitude of the RF current
is varied between high and low states.
10. The method of claim 9, wherein effective RF power applied to
the coil is between 100 and 3000 W.
11. The method of claim 10, wherein a pressure in the chamber is at
least 5 mT, RF power is at least 1000 W, and ion density is at
least 5.times.10.sup.10 cm.sup.-3.
12. The method of claim 11, wherein the pressure is at least 40 mT
and the plasma voltage is less than 10 V.
13. The method of claim 9, wherein the RF current is pulsed at a
duty cycle of between 10 and 90%.
14. The method of claim 9, wherein the RF current is pulsed at a
frequency between 1 kHz and 100 kHz.
15. A method of processing a substrate, comprising: locating the
substrate in a plasma-processing chamber; flowing a
nitrogen-containing gas into the chamber; providing RF current to a
coil to generate an RF field in the chamber, the RF field creating
a nitrogen-containing RF plasma out of the gas, the amplitude of
the RF current being varied between high and low states; and
incorporating nitrogen from the plasma into a layer formed on the
substrate.
16. The method of claim 15, wherein the composition of the
nitrogen-containing plasma is varied by pulsing of the RF
current.
17. A method of processing a substrate, comprising: locating the
substrate in a plasma-processing chamber; flowing a gas into the
chamber; providing RF current to a coil located externally adjacent
to a dielectric wall of the chamber, an electrode plate being
located between the coil and the dielectric wall and being at a
voltage below 20 V, the RF field creating an RF plasma out of the
gas; and incorporating nitrogen ions of the plasma into a layer on
the substrate.
18. The method of claim 17, wherein the electrode plate is
grounded.
19. The method of claim 17, wherein the ions are nitrogen ions.
20. The method of claim 17, wherein a pressure in the chamber is at
least 5 mT, RF power applied to the coil is at least 1000 W, a
potential of the plasma is less than 20 V, and ion density is at
least 5.times.10.sup.10 cm.sup.-3.
21. The method of claim 20, wherein the pressure is at least 40 mT,
and the potential of the plasma is less than 10 V.
22. A plasma reactor, comprising: a chamber, having an opening to
transfer a substrate into an internal volume of the chamber; a
substrate holder in the chamber for holding the substrate; an RF
coil externally and adjacent to a nonconductive wall of the
chamber; and an electrode plate between the wall and the RF coil,
the electrode plate being at a voltage below 20 V when RF current
is provided to the RF coil.
23. The plasma reactor of claim 22, wherein the electrode plate is
grounded.
24. The plasma reactor of claim 23, wherein the electrode plate is
grounded through the chamber.
25. The plasma reactor of claim 24, wherein the wall is made of
quartz.
26. The plasma reactor of claim 23, wherein the electrode plate is
peripherally grounded.
27. The plasma reactor of claim 26, wherein the wall has a dome
shape and the electrode plate has a dome shape positioned over the
dome shape of the wall.
28. The plasma reactor of claim 27, wherein the electrode plate has
a plurality of fingers, each contacting a conductive portion of the
chamber.
29. A plasma reactor, comprising: a chamber, having an opening to
transfer a substrate into an internal volume of the chamber; a
substrate holder in the chamber for holding the substrate; an RF
coil externally and adjacent to a nonconductive wall of the
chamber; and an RF source connected to the RF coil, the RF source
being capable of automatically varying an amplitude of RF current
provided to the RF coil.
Description
BACKGROUND OF THE INVENTION
[0001] 1). Field of the Invention
[0002] This invention relates to a plasma reactor and a method of
processing a substrate by creating a plasma.
[0003] 2). Discussion of Related Art
[0004] The manufacture of integrated circuits involves the
manufacture of field effect transistors in and on silicon or other
semiconductor substrates. The manufacture of a field effect
transistor includes the formation of a gate dielectric layer. The
dielectric layer is typically grown by exposing silicon of the
substrate to oxygen, thereby forming silicon dioxide gate
dielectric layers.
[0005] As logic devices have become smaller, it has become
advantageous to include nitrogen into the silicon dioxide gate
dielectric layers. Nitrogen is often incorporated by creating a
plasma of nitrogen ions within a chamber and implanting the
nitrogen ions into the gate dielectric layer. The plasma is
typically created utilizing a radio frequency (RF) source, with
either an electrode plate (capacitative coupling) or a coil
(inductive coupling). The RF source creates an RF field within a
gas in the chamber, and this coupling creates the plasma.
[0006] Independent of the type of RF source (plate or coil), there
can be significant capacitative coupling from the source to the
plasma, which creates a relatively large plasma potential, on the
order of tens of volts. Such a large plasma potential may cause
excessive bombardment of the silicon dioxide layer with nitrogen
ions, which can cause damage to the silicon dioxide layer and even
incorporation of nitrogen into the underlying silicon. Damage to
the silicon dioxide layer or incorporation of nitrogen into the
underlying silicon diminishes the advantages of nitrogen
incorporation.
SUMMARY OF THE INVENTION
[0007] According to one aspect of the invention, a method is
provided of processing a substrate, including locating the
substrate in a processing chamber, creating a nitrogen plasma in
the chamber, the plasma having an ion density of at least 10.sup.10
cm.sup.-3, and a potential of less than 20 V, and exposing a layer
on the substrate to the plasma to incorporate nitrogen from the
plasma into the layer.
[0008] According to another aspect of the invention, a method of
processing a substrate is provided, wherein the substrate is
located in a plasma processing chamber, a nitrogen-containing gas
flows into the chamber, an RF current is provided through a coil to
generate an RF field in the chamber, the RF field creating a
nitrogen-containing RF plasma out of the gas, the RF current being
pulsed, and incorporating nitrogen ions and excited neutrals from
the plasma into a gate dielectric layer formed on the
substrate.
[0009] According to a further aspect of the invention, a plasma
reactor is provided, including a chamber having an opening to
transfer a substrate into an internal volume of the chamber, a
substrate holder in the chamber for holding the substrate, an RF
coil externally and adjacent to a wall of the chamber, and a
grounded electrode plate between the wall and the RF coil.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] The invention is further described by way of examples with
reference to the accompanying drawings, wherein:
[0011] FIG. 1 is a perspective view of a plasma reactor according
to an embodiment of the invention;
[0012] FIG. 2 is a cross-sectional side view of upper components of
the plasma reactor;
[0013] FIG. 3 is a cross-sectional side view illustrating nitrogen
ion incorporation into a silicon dioxide gate dielectric layer;
[0014] FIG. 4 is a graph illustrating plasma potential as a
function of pressure for various RF source powers and electrode
plate configuration as measured with a Langmuir probe;
[0015] FIG. 5 is a graph illustrating the floating voltages as a
function of pressure for the electrode plate configuration as
measured with a Langmuir probe;
[0016] FIG. 6 is a graph illustrating electron density as a
function of pressure for the electrode plate configuration as
measured with a Langmuir probe;
[0017] FIG. 7 is a graph illustrating ion density as a function of
pressure for the electrode plate configuration as measured with a
Langmuir probe;
[0018] FIG. 8 is a graph illustrating electron temperature as a
function of pressure for the electrode plate configuration as
measured with a Langmuir probe;
[0019] FIG. 9 is a bottom view of laminate, including an electrode
plate, according to an embodiment of the invention.
[0020] FIG. 10 is a cross-sectional side view illustrating the
laminate in an installed position;
[0021] FIG. 11 is a graph illustrating pulsing of RF power to an RF
coil with a 30% duty cycle;
[0022] FIG. 12 is a graph similar to FIG. 11 at a 50% duty
cycle;
[0023] FIG. 13 is a graph illustrating thickness change before and
after nitrogen plasma treatment with pulsed RF power, and provides
a measure of incorporated nitrogen;
[0024] FIG. 14 is a graph illustrating thickness change for
different samples processed at different continuous RF power
settings;
[0025] FIG. 15 is a graph illustrating thickness change as a
function of RF source peak power for two pulsing frequencies;
[0026] FIG. 16 is a graph illustrating thickness change as a
function of duty cycles for two pulsing frequencies;
[0027] FIG. 17 is a graph illustrating optical emissions spectra
for 500 W peak power at various pulsing frequencies and duty
cycles; and
[0028] FIG. 18 illustrates optical emission spectra for a 50% duty
cycle at various pulsing frequencies and peak powers.
DETAILED DESCRIPTION OF THE INVENTION
[0029] FIGS. 1 and 2 illustrate a plasma reactor 10, according to
an embodiment of the invention, including a chamber 12, a substrate
holder 14, an RF coil 16, and an electrode plate 18. The electrode
plate 18 is connected through a body of the chamber 12 to ground
20. By grounding the electrode plate 18, a capacitive coupling
between the RF coil 16 and a plasma 22 in an internal volume 24 of
the chamber 12 is eliminated. The elimination of the capacitive
couple reduces the potential of the plasma 22 without dramatically
altering other properties of the plasma 22, such as ion density and
electron density. The inductive coupling from the RF coil 16 is not
eliminated, and this coupling creates and maintains the plasma
22.
[0030] Referring specifically to FIG. 1, the plasma reactor 10
further includes a lower transfer chamber 26 and a transfer
mechanism 28. The chamber 12 is positioned on top of the transfer
chamber 26. An internal volume 30 of the transfer chamber 26 is
placed in communication with the internal volume 24 of the chamber
12 through a circular opening 32 in a base of the chamber 12. The
substrate holder 14 is secured on top of the transfer mechanism 28,
and the transfer mechanism 28 can be used to elevate or lower the
substrate holder 14.
[0031] In use, the transfer mechanism 28 is operated so that the
substrate holder 14 is lowered into the internal volume 30 of the
transfer chamber 26. A wafer substrate, positioned on a blade
attached to a robot arm, is then transferred through a slit-valve
opening in a wall of the transfer chamber 26 into the internal
volume 30. The transfer mechanism 28 is then operated to elevate
the substrate holder 14 so that the substrate holder 14 contacts a
lower surface of the wafer substrate and elevates the wafer
substrate off the blade. The blade is then removed from the
transfer chamber 26, whereafter the transfer mechanism 28 is again
operated to elevate the substrate holder 14 into the opening 32.
The wafer substrate, located on the substrate holder 14, then has
an upper surface which is exposed to the internal volume 24 of the
chamber 12.
[0032] The chamber 12 includes primarily a conductive body 36 and a
dielectric dielectric quartz upper wall 38. The conductive body 36
forms a lower portion of the chamber 12, and the upper wall 38
forms an upper portion of the chamber 12. The conductive body 36
and the upper wall 38 jointly define the internal volume 24.
[0033] Four gas nozzle ports 40 are formed through the conductive
body 36 into the internal volume 24. The gas nozzle ports 40 are
positioned at 90.degree. intervals around the substrate holder 14.
The conductive body 36 also defines a vacuum pumping channel 42 on
one side thereof. The gas nozzle ports 40 are connected through
valves to a gas manifold, and the vacuum pumping channel 42 is
connected to a pump. When the pump is operated, gases are extracted
from the internal volume 24 through the vacuum pumping channel 42
to reduce a pressure within the internal volume 24. The valves can
be operated to allow gases from the manifold through the valves and
the gas nozzle ports 40 into the internal volume 24.
[0034] Referring more specifically to FIG. 2, the upper wall 38 has
a dome shape, and the electrode plate 18 has a dome shape that
conforms to an outer surface of the upper wall 38. The electrode
plate 18 is in fact located directly on the upper wall 38. The
electrode plate 18 defines a circular opening 44 over a center of
the upper wall 38. The upper wall 38 and the electrode plate 18 are
symmetrical around a vertical axis 46.
[0035] The coil 16 spirals around the vertical axis 46 and the
opening 44. The coil 16 is positioned on and conforms to the dome
shape of the electrode plate 18. One end of the coil 16 is
connected to an RF source 50, and an opposing end of the coil 16 is
connected to ground 52.
[0036] Reference is now made to FIGS. 2 and 3 in combination. An
epitaxial silicon layer 54 is formed on an upper surface of a wafer
substrate before the wafer substrate is inserted into the plasma
reactor 10 positioned on an upper surface of the substrate holder
14. A thin silicon dioxide layer 58 is grown on the silicon layer
54, also before the wafer substrate is inserted into the plasma
reactor 10. The silicon dioxide layer 58 is on the order of a few
angstroms (e.g., 40 .ANG.) thick, and is later used as a gate
dielectric layer in a finally manufactured transistor. The purpose
of inserting the wafer substrate into the plasma reactor 10 is to
incorporate nitrogen (N) into the silicon dioxide layer 58 for
purposes of modifying or improving its dielectric properties. The
plasma 22 of nitrogen ions (N.sub.2.sup.+) is created within the
internal volume 24. The nitrogen ions have energies defined by the
properties of the plasma which leads to their being incorporated
into the silicon dioxide layer 58.
[0037] The plasma is created by first reducing the pressure within
the internal volume 24 to a predetermined level. A
nitrogen-containing gas is then introduced into the internal volume
24. The nitrogen-containing gas may, for example, be pure nitrogen
(N.sub.2), a mixture of nitrogen and helium gases (N.sub.2/He), a
mixture of nitrogen and neon gases (N.sub.2/Ne), or a mixture of
nitrogen and argon gases (N.sub.2/Ar). For purposes of further
discussion, examples are given where the gas is pure nitrogen
gas.
[0038] The RF source 50 is then operated to provide RF current to
the coil 16 at a frequency of 13.56 MHz. The RF coil 16 generates
an RF field which is spread by the electrode plate 18 across the
upper wall 38. The circular opening 44 permits the RF field to
enter through the upper wall 38 into the internal volume 24. The RF
field then couples with the nitrogen gas in the internal volume 24.
The RF field initially excites a small number of free electrons.
The free electrons then collide with other atoms to release more
electrons from these atoms. The process is continued until a
steady-state condition is achieved, where the plasma 22 has a
steady amount of free electrons and free ions, a steady electron
temperature, and a constant voltage relative to ground. A
"reservoir" of ions is so created within the internal volume 24,
and the voltage potential of the plasma 22 assists in incorporating
ions from this reservoir into the silicon dioxide layer 58. The
potential of the substrate and the substrate holder 14 floats
freely during the entire process, but there is a difference in the
voltage of the plasma 22 and that of the substrate holder 14, the
difference driving the incorporation of the ions.
[0039] Without grounding the electrode plate 18, the RF coil 16
couples capacitively to the plasma 22. Such a capacitive couple
between the RF coil 16 and the plasma 22 increases the voltage of
the plasma 22. Conversely, by grounding the electrode plate 18, the
capacitive coupling is substantially reduced, and the voltage of
the plasma 22 is reduced. The plasma potential and the electron
temperature are reduced, but ion density remains relatively high.
To prevent excessive incorporation of nitrogen through the
SiO.sub.2 and into the silicon substrate, plasma potential is
preferably less than 10 V. Electron temperatures are preferably
near or less than 2 eV. Ion density is preferably at least
10.sup.10 cm.sup.-3.
[0040] FIG. 4 illustrates experimental results utilizing no
electrode plate, a regular ungrounded electrode plate, and a
grounded electrode plate, respectively. In each case, experimental
results were obtained when applying 300 W, 500 W, and 900 W of
power to the RF coil 16. Larger blocks or triangles indicate larger
power magnitudes. At a given power provided to the RF coil 16, the
plasma voltage (Vp) is the smallest for a grounded electrode plate,
higher for an ungrounded electrode plate, and even higher when
there is no electrode plate. In other examples, effective RF power
supplied to the RF coil 16 may be between 160 and 3000 W.
Potentials below 10 V are not achievable without the grounded
electrode plate. What should also be noted is that the potentials
do not substantially increase with an increase in power provided to
the RF coil. Even very large power magnitudes above 1000 W (e.g.,
1400 W), crease plasma voltages below 20 V at pressures above 5
milliTorr (mT), and plasma voltages below 10 V at pressures above
40 mT.
[0041] FIG. 5 illustrates the floating voltage of the plasma for
the condition of FIG. 4. The potential at which the wafer resides
is at or near Vf. Again, it can be seen that the substrate voltage
(Vs) is the smallest for a grounded electrode plate, higher for an
ungrounded electrode plate, and even higher when there is no
electrode plate.
[0042] FIGS. 6 and 7 illustrate electron density and ion density,
respectively. For a given magnitude of power applied to the RF coil
16, there is very little difference between the electron density
(or the ion density), when using a grounded electrode plate and
when using an ungrounded electrode plate. Although not slow, ion
densities above 50.times.10.sup.9 are achievable when RF power
above 1000 W is provided to the RF coil.
[0043] FIG. 8 illustrates electron temperature. It can be seen that
at lower pressures there is relatively little difference in
electron temperatures when using a grounded, ungrounded, or no
electrode plate. However, at higher pressures, typically above 40
mT, it can be seen that electron temperature is much higher where
an ungrounded electrode plate is used, or when no electrode plate
is used, than when a grounded electrode plate is used.
[0044] Referring to FIGS. 9 and 10, the electrode plate 18 is
laminated between two dielectric sheets 60 and 62. The electrode
plate 18 and the dielectric sheets 60 and 62 are formed in strips
64 that, when folded toward one another, collectively define a dome
shape. The dielectric sheet 60 is positioned at the top between the
electrode plate 18 and the RF coil 16. The dielectric sheet 62 is
located between the electrode plate 18 and the upper wall 38. Ends
of the electrode plate are not covered by the dielectric sheet 62,
to leave exposed lands 66. The exposed lands 66 contact a
conductive portion of the conductive body 36, to ground the
electrode plate 18 to the conductive body 36. The lands 66 are
disposed on a perimeter of the electrode plate 18, so that the
electrode plate 18 is peripherally grounded. Peripheral grounding
of the electrode plate 18 ensures that the entire electrode plate
18 is as close to zero volts as possible.
[0045] The plasma voltage can also be reduced by pulsing the RF
power provided to the RF coil 16. In the examples that are now
provided, the electrode plate 18 was not grounded, although it
should be understood that the electrode plate 18 may be grounded in
addition to pulsing of the RF power provided to the RF coil 16.
[0046] As illustrated in FIGS. 11 and 12, RF power having a
frequency of 13.56 MHz and a predetermined peak power is provided
to the RF coil 16. The RF power may be automatically switched on
and off, i.e., "pulsed." In the examples that are provided, the RF
power is automatically pulsed at a frequency of 10 kHz. In other
examples, the RF power may be pulsed at frequencies between 1 kHz
and 100 kHz. The composition of the nitrogen plasma is continuously
varied by varying the RF current between high and low states. In
FIG. 11, the duty cycle, i.e., the total amount of time that the RF
power is on, is 30%, and in FIG. 12, the duty cycle is 50%. The RF
source 50 is pulsing-enabled, and both the pulsing frequency and
duty cycle are manually adjustable. The effective delivered power
is the peak power times the duty cycle. In other examples, the duty
cycle may be between 10% and 90%. In the given example, the
amplitude of the RF power is continually altered between 0% and
100%, but in another example, the amplitude may, for example, be
altered between 10% and 100%.
[0047] One way to measure incorporation of nitrogen is by measuring
the thickness change ("optical delta") before and after a nitrogen
plasma treatment. A larger thickness change indicates more nitrogen
incorporation. As shown in FIG. 13, the amount of incorporated
nitrogen using continuous power can also be achieved using pulsed
power, with the amount of incorporated nitrogen scaling
approximately with the effective delivered power. The change in
optical thickness is relatively insensitive to pulsing
frequency.
[0048] FIG. 14 illustrates optical delta for samples prepared with
continuous RF source power; the saturation in incorporated nitrogen
with power is observed for both pulsed and continuous power.
[0049] FIGS. 15 and 16 show the same data as in FIG. 13, plotted
against source power and duty cycle, showing the same trends as
FIG. 13.
[0050] In FIGS. 17 and 18, optical emission spectra are captured
with an optical emission spectrometer. As one increases the duty
cycle at fixed-peak RF power (500 W), the spectra approach the 500
W continuous power spectra (top line), as can be seen in FIG. 17.
Pulsing frequency has a small effect on the observed intensity.
FIG. 18 shows that the pulsed RF emission level can be restored to
the continuous-power emission level (top line) by increasing peak
RF power. Again, the emission is relatively insensitive to pulsing
frequency.
[0051] FIGS. 13 to 16 indicate that on-wafer nitrogen incorporation
similar to the incorporation of continuous RF power is possible
with pulsed-RF plasmas. FIGS. 17 and 18 indicate that plasmas of
similar ion density to continuous-RF power plasmas can be achieved
with pulsed-RF power. These data, coupled with the effect of
pulsed-RF power to reduce the electron temperature and plasma
potential relative to continuous power, indicate that the pulsing
of RF power provides a method for incorporation of nitrogen into
gate dielectric oxides at lower energy levels. While incorporating
the same amount of nitrogen in the oxide, nitrogen ions in the
pulsed plasmas are accelerated into the wafer less than ions in the
continuous-power plasmas because of the lower plasma potentials of
the pulsed plasmas. Because of this reduced acceleration, the
nitrogen will not penetrate as far into the oxide and the
underlying silicon.
[0052] The simulation of ion implantation into silicon,
specifically into Si(100), at various ion energies (10 eV to 30
eV), through a thin oxide layer shows less penetration for lower
energy, as can be readily expected. Achieving nitrogen
incorporation in such a low-energy fashion with the pulsed-nitrogen
plasmas may provide for an improved dielectric that will lead
directly to improvements in transistor performance.
[0053] It should be noted that although nitrogen incorporation into
a thin gate silicon dioxide has been described, the described
processes may have applications for nitrogen incorporation in other
gate dielectric materials.
[0054] While certain exemplary embodiments have been described and
shown in the accompanying drawings, it is to be understood that
such embodiments are merely illustrative and not restrictive of the
current invention, and that this invention is not restricted to the
specific constructions and arrangements shown and described since
modifications may occur to those ordinarily skilled in the art.
* * * * *