Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2001-10-12
2003-01-07
Niebling, John F. (Department: 2812)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S675000, C438S676000, C438S680000
Reexamination Certificate
active
06503824
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to forming conductive layers on insulators by physical vapor deposition (PVD).
FIG. 1
illustrates a conventional physical vapor deposition chamber
110
used to deposit conductive layers on a semiconductor wafer
120
in the process of fabrication of integrated circuits. The wafer is placed on a pedestal
130
at the bottom of the chamber. A target
140
is mounted at the top of the chamber and biased by a DC bias source
150
. Argon or some other plasma forming gas is flown into chamber
110
and is ionized by an electrical field that can be created by the potential difference between wafer
120
and target
140
, or by a separate coil
160
. Due to the target bias created by source
150
, the argon ions accelerate towards target
140
and dislodge molecules from the target. These sputtered molecules settle on wafer
120
. (In a “reactive” physical vapor deposition, the sputtered molecules can undergo a chemical reaction before settling on the wafer; for example titanium molecules may react with nitrogen to form titanium nitride which is then deposited on the wafer.)
Some of the sputtered molecules settle on the walls of the chamber and not on the wafer. To increase the number of the molecules settling on the wafer, the molecules are ionized, and the wafer is biased to attract the ionized molecules (these ions are shown at
140
i
). In particular, in
FIG. 1
, coil
160
densifies the argon plasma in chamber
110
, and this high density plasma causes at least some of the sputtered molecules to become ionized. (The plasma can eventually be sustained by ions
140
i
; the argon flow into the chamber can be turned off.) The wafer is biased by an AC or DC bias source
170
to attract the ions
140
i
. The bias from source
170
can be applied to the wafer or, alternatively, to pedestal
130
whose top surface can be made from an insulating material. This technique (ionizing the molecules sputtered from the target) is known as ionized physical vapor deposition (I-PVD) or ionized metal plasma deposition (IMP). An example IMP chamber
110
is a magnetron sputtering chamber of type Vectra available from Applied Materials of Santa Clara, Calif. as part of a system of type ENDURA®. The Vectra chamber is operated with bias source
170
providing an RF bias (13.56 MHz) applied to pedestal
130
having an insulating top surface, with bias source
150
providing a DC bias, and with coil
160
carrying an RF current (13.56 MHz).
Ionized PVD has particular advantages for contact fabrication.
FIG. 2
illustrates a typical contact structure that can be fabricated in wafer
120
. Conductive layer
210
is part of a semiconductor substrate (e.g. monocrystalline silicon), or is formed over a semiconductor substrate. Insulator
220
(e.g. silicon dioxide) is formed over layer
210
. Contact opening
224
in insulator
220
exposes the layer
210
. A conductive layer
230
is deposited by I-PVD over insulator
220
and into opening
224
. Layer
230
can provide an interconnect contacting the layer
210
through opening
224
. Layer
230
can also provide as an adhesion or barrier layer separating an overlying conductive layer (not shown) from layer
210
. For example, layer
230
can be a titanium or titanium nitride layer separating an overlying aluminum or tungsten layer from silicon or metal layer
210
.
Ionized PVD is a good method for fabrication of layer
230
because the wafer bias causes the ions
140
i
to travel in a direction normal to the wafer. Deposition into deep openings
224
is therefore facilitated. Also, good sidewall coverage is achieved in the opening due to re-sputtering of layer
230
. More particularly, as illustrated in
FIG. 2
, ions
140
i
may dislodge previously deposited molecules
230
a from layer
230
. Some of the dislodged molecules
230
a
settle on the sidewalls and the bottom of opening
224
, improving the sidewall and bottom coverage. In addition, for some materials
230
, a significant portion of the dislodged molecules
230
a
comes from the top edges
224
E of opening
224
. Consequently, it is more difficult for the deposited material to form overhangs at the top edges of the opening, and hence deposition into the opening is further facilitated. See “Handbook of Semiconductor Manufacturing Technology” (edited by Yoshio Nishi et al., 2000), pages 409-410, incorporated herein by reference.
SUMMARY
The inventor has observed that at the beginning of the deposition, when insulator
220
is exposed, ions
140
i
can dislodge the insulator molecules, and the insulator molecules can settle on layer
210
. This undesirably increases the contact resistance.
According to one embodiment of the present invention, the wafer bias at the beginning of the deposition is set to zero. After some period (a few seconds in some embodiments), the wafer bias is increased. At this time, insulator
220
has been at least partially covered by material
230
, so dislodging of the insulator molecules is unlikely.
In some embodiments, the wafer bias at the beginning of the deposition is not zero but is lower than at a later stage of the deposition.
Another technique that may reduce the possibility of the “insulator re-sputtering” (dislodging of the insulator molecules) is reducing the power in coil
160
at the beginning of the deposition, or reducing the target bias generated by source
150
. Other embodiments are within the scope of the invention, as defined by the appended claims.
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Chin, Barry L. et al., “Barrier and Seed Technologies for Sub-0-10 &mgr;m Copper Chips” May 2001, Cahners Semiconductor International, pp. 1-7.
“Handbook of Semiconductor Manufacturing Technology” (edited by Yoshio Nishi et al., 2000), pp. 409-410.
Gurley Lynne A.
Mosel Vitelic Inc.
Niebling John F.
Parsons James E.
Shenker Michael
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