Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode
Reexamination Certificate
2001-03-15
2003-09-09
Pham, Long (Department: 2814)
Active solid-state devices (e.g., transistors, solid-state diode
Field effect device
Having insulated electrode
C257S408000, C257S413000, C257S653000, C257S763000
Reexamination Certificate
active
06617624
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to generally to metal elements with a protective layer during the processing of integrated circuit components, and more particularly to the passivated metal layers in gate stacks during source/drain reoxidation.
BACKGROUND OF THE INVENTION
A general metal-oxide-semiconductor field-effect transistor (MOSFET) comprises a conductive electrode material formed over a gate dielectric (e.g., silicon oxide), which in turn overlies a semiconductor substrate (e.g., single-crystal semiconductor substrate). The electrode typically includes doped polysilicon, which entails many advantages as a gate electrode, and the underlying gate dielectric of today's commercial integrated circuits is typically a silicon dioxide layer grown out of the substrate.
The gate electrode material may also function as an interconnect. For example, dynamic random access memory (DRAM) word lines may be etched from a polysilicon layer deposited for the gates (often referred to in the industry as “poly-1”). Unfortunately, polysilicon resistivity is considerably higher than that of aluminum or other metals. Additionally, efforts to increase circuit density by scaling down device dimensions lead to polysilicon lines of decreasing width, leaving a small cross-sectional line area through which to conduct current. High polysilicon resistivity combined with small line width results in a high overall interconnect resistance, entailing greater power consumption, long propagation delays and slower access speeds. As integrated circuits are scaled down, access speed becomes a critical issue, so methods of reducing gate/interconnect resistivity are required.
In pursuit of lower overall gate resistance, highly conductive layers (e.g. metal, metal silicide, and/or metal nitride) have been implemented over the gate polysilicon, thus lowering the overall resistivity of the interconnect lines while retaining the gate integrity provided by polysilicon. For example, a layer of tungsten silicide or tungsten nitride may overlie the polysilicon, and another metal layer such as tungsten may overlie the silicide or nitride layer to further boost conductivity. Alternatively, a metal layer may also be deposited directly over the polysilicon, without the intervening metal silicide, depending upon stress and adhesion factors.
FIG. 1
illustrates a typical gate stack
10
, comprising a metal layer
12
(e.g., tungsten), a metallic interlayer
14
(e.g., tungsten silicide), and a doped polysilicon layer
16
, all overlying a gate oxide
18
which has been grown out of a silicon substrate
20
. The interlayer
14
can comprise a metal silicide or metal nitride layer, or can be omitted altogether. An insulating cap layer (not shown) can also be formed at this stage.
After the layers that make up the gate stack
10
have been formed, gate structures are patterned in accordance with an integrated circuit design (e.g. a dynamic random access memory, or DRAM, array).
FIG. 2
illustrates the result of patterning. After a resist mask
24
is formed by standard photolithographic processes, the stack
10
must then be etched through, thus producing a gate electrode
26
formed of the patterned polysilicon
28
, silicide
30
and metal
32
straps, as shown. In general, plasma etches are utilized to create vertical profiles for the gate structures
26
, although the particulars may vary depending upon the stack materials. The polysilicon layer
16
(FIG.
1
), which is etched last of the stack materials, is usually etched by fluorine- or chlorine-based plasmas.
In either case, the plasma etch tends to cause considerable damage to the gate oxide
18
immediately subjacent the polysilicon layer
16
(FIG.
1
). Such damage may result regardless of efforts to optimize etch selectivity and optical end point measurement techniques.
FIG. 3
illustrates a closer view of the gate electrode
26
and physical damage (thinning) resulting from gate oxide
18
exposure to the plasma etch. It should be understood that damage to the chemical integrity of the gate oxide
18
also takes place as a result of photon-assisted and other damage during the ion bombardment generally utilized for anisotropic etching. The etch damage may also extend to the underlying silicon substrate.
A high quality gate insulator is required for reliable operation of the MOSFET device and of the circuit employing the MOSFET. Susceptibility to hot carrier effects and consequent charge trapping, high defect densities, silicon-oxide interface states, pinholes and oxide thinning can all cause punchthrough or tunneling current leakage. In turn, junction leakage results in increased threshold voltage and unreliable circuit operation. Damage to the gate oxide
18
caused by plasma etching may induce many of these problems, particularly at or near corners
35
of the gate
26
. Aside from the illustrated physical thinning, plasma etching tends to damage oxide bonds, creating charge trap sites. Such structural damage extends laterally under the gate corners
35
as well as over adjacent source/drain regions. This damage must be repaired to improve the quality and life expectancy of the gate oxide
18
. One common manner of repair is by a source/drain reoxidation step, a high temperature step performed in an oxygen environment.
Referring to
FIG. 4
, this reoxidation can involve wet oxidation at temperatures above 900° C. for a relatively long period (e.g., up to 30 minutes). During this process, the oxide under the gate corners
35
is thickened and corners
35
of the polysilicon gate
28
are rounded. Small bird's beak structures
40
at the thickened corners reduce lateral electric field strength in active areas adjacent the gate
28
, thereby reducing hot electron injection through the reoxidized gate oxide
38
during transistor operation.
Unfortunately, conditions during source/drain reoxidation also result in oxidation of exposed gate materials. Thus, for the illustrated example, a layer of tungsten oxide (WO
x
)
42
readily forms around tungsten metal straps
32
. Similarly, oxides
44
such as tungsten oxide (WO
x
) and silicon dioxide (SiO
2
) grow out of the metallic interlayer strap
30
.
The longer the reoxidation process and the higher the temperature, the more metal, metal nitride and/or silicide are consumed. The oxides
42
,
44
formed in consumption of the metal in straps
30
,
32
are insulating and so unable to contribute to word line conductivity. Thus, overall resistance can be radically increased by the source/drain reoxidation. Some metals, such as tungsten, are so readily oxidized that overall resistance is increased beyond tolerable levels, rendering such metals impractical for use in gate materials.
Accordingly, a need exists for gate fabrication processes and structures which permit low overall resistance at the gate level while maintaining high quality gate oxide composition.
SUMMARY OF THE INVENTION
In accordance with one aspect of the invention, a low resistance gate stack for an integrated circuit transistor comprises a metal layer having a first width. The gate stack further comprises a metal nitride over surfaces of the metal layer being less than about 20 Å. The gate stack further comprises a doped polysilicon layer underlying the metal layer, the doped polysilicon layer having a second width. In the illustrated embodiment, the metal layer comprises tungsten.
In accordance with another aspect of the invention, a gate electrode stack is in an atmosphere comprising an oxidant during a source/drain reoxidation process. The gate electrode stack comprises a metal layer with at least one surface simultaneously exposed to the oxidant and a passivating species. The passivating species is adsorbed on the surface of the metal layer, whereby the passivating species inhibits diffusion of the oxidant into the gate electrode stack.
REFERENCES:
patent: 4081510 (1978-03-01), Kato et al.
patent: 4621277 (1986-11-01), Ito et al.
patent: 4784973 (1988-11-01), Stevens et al.
patent: 4818715 (1989-04-01), Chao
pate
Knobbe Martens Olson & Bear LLP
Micro)n Technology, Inc.
Pham Long
Rao Shrinivas H.
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