Active solid-state devices (e.g. – transistors – solid-state diode – Schottky barrier – To compound semiconductor
Reexamination Certificate
2002-07-26
2003-09-30
Ngô, Ngân V. (Department: 2814)
Active solid-state devices (e.g., transistors, solid-state diode
Schottky barrier
To compound semiconductor
C257S473000, C257S476000, C257S480000, C257S483000, C257S485000
Reexamination Certificate
active
06627967
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to a Schottky barrier diode device made of a compound semiconductor and applied in a high frequency circuit, specifically to a Schottky barrier diode having a planar configuration to achieve a smaller operation region and a smaller overall chip size.
2. Description of the Related Art
The demand for high frequency devices has been rapidly increasing due to the expanding market for portable telephones and digital satellite communication equipment. Many of such devices include field effect transistors (referred to as FET, hereinafter) employing a gallium arsenide (referred to as GaAs, hereinafter) substrate because of its excellent high frequency characteristics. Typical application in this field includes local oscillation FETs for satellite antenna and monolithic microwave integrated circuits (MMIC) in which a plurality of FETs are integrated for wireless broadband. GaAs Schottky barrier diodes are also used in a base station of cellular phone system.
FIG. 1
is a cross-sectional view including an operation region of a conventional Schottky barrier diode. An n+epitaxial layer
22
(a silicon impurity concentration of about 5×10
18
cm
−3
) having a thickness of about 6 &mgr;m is formed on an n+ GaAs substrate
21
. An n epitaxial layer
23
(a silicon impurity concentration of about 1.3×10
17
cm
−3
) having a thickness of about 350 nm is formed on the n+ epitaxial layer
22
. This n epitaxial layer provides as an operation region.
An ohmic electrode
28
makes a ohmic contact with the n+ epitaxial layer
22
and is made of a AuGe (gold-germanium alloy)/Ni (nickel)/Au (gold) metal layer disposed as a first wiring layer. A Ti (titanium)/Pt (platinum)/Au metal
32
serves as a second wiring layer, and is divided into wiring on the anode side and wiring on the cathode side. On the anode side, the Ti/Pt/Au metal layer makes a Schottky contact with the n epitaxial layer
23
, and forms a Schottky contact region
31
a
. The portion of the Ti/Pt/Au metal layer on the anode side above the Schottky contact region
31
a
is referred to as a Schottky electrode
31
. An anode electrode
34
is formed on and completely overlaps with the Schottky electrode
31
and its extension. The anode electrode
34
provides an anode bonding pad
34
a
and is formed by Au plating using the Schottky electrode
31
and its extension as a plating electrode. A bonding wire
40
is fixed to the anode bonding pad
34
a
. The Au metal layer serves as a third wiring layer and has a thickness of about 6 &mgr;m. The thick Au layer is necessary for providing stress relief during wire bonding. On the cathode side, the cathode electrode
35
provides a cathode bonding pad and is formed of the Au layer. The Ti/Pt/Au metal layer on the cathode side directly contacts the ohmic electrode
28
. The edge of the Schottky electrode
31
needs to be on a top surface of a polyimide layer
30
to satisfy photolithographic requirements. Accordingly, a portion of the Schottky electrode
31
, near the Schottky region
31
a
, overlaps by about 16 &mgr;m with the polyimide layer
30
formed on the ohmic electrode
28
on the cathode side. The entire substrate and epitaxial layers are at a cathode voltage except the Schottky contact region
31
a
. The polyimide layer
30
insulates the anode electrode
34
from the substrate
22
and the epitaxial layers. The intersection between the anode electrode
34
and the underlying structure and the intersection between the anode bonding pad
34
a
and the underlying structure are, in total, about 3900 &mgr;m
2
, which could provide a large parasitic capacitance to the device if the thickness of the polyimide layer
30
is small. Thus, to have a reasonably small parasitic capacitance, the thickness of the polyimide layer must be as large as 6-7 &mgr;m even though the polyimide film
30
has a relatively low dielectric constant.
The n epitaxial layer
23
of the lower impurity concentration (1.3×10
17
cm
3
) is necessary for assuring a Schottky contact region
31
a
with good Schottky characteristics and a high breakdown strength (10V). The ohmic electrode
28
is formed directly on the n+ epitaxial layer
22
for reducing the resistance at the contact. For this reason, a mesa etching process is necessary for exposing the top surface of the n+ epitaxial layer
22
. The n+ GaAs substrate
21
underneath the n+ epitaxial layer
22
also has a high impurity concentration, and has a backside electrode made of the AuGe/Ni/Au metal layer for an external contact from the backside.
FIG. 2
is a schematic top view of the conventional Schottky barrier diode having the operation region shown in FIG.
1
. The Schottky contact region
31
a
formed in the n epitaxial layer
23
occupies a central portion of the device. The diameter of this region
31
a
is about 10 &mgr;m. A Schottky contact hole
29
is formed in the center of the Schottky contact region
31
a
. The Ti/Pt/Au metal layer of the second wiring layer is in direct contact with the n epitaxial layer
23
through the contact hole
29
. The ohmic electrode
28
of the first wiring layer surrounds the circular Schottky contact region
31
a
, and occupies almost a half of the top surface of the device.
The Au metal layer of the third wiring layer provides the bonding pads. On the anode side, the anode bonding pad
34
a
has a minimum area allowed for one bonding wire
40
. On the cathode side, the cathode bonding pad
35
a
is large enough to provide bonding of multiple wires
40
, which is required for reducing the inductance generated at bonding wires. The cathode bonding pad
35
a
and the cathode electrode
35
are formed directly on the ohmic electrode
8
disposed on the n+ epitaxial layer without the intervening polyimide layer
30
. The area of the anode bonding pad
34
a
is about 40×60 &mgr;m
2
and the area for the cathode bonding pad is about 240×70 &mgr;m
2
.
However, the mesa etching, which is required to expose the n+ epitaxial layer
22
through the n epitaxial layer
23
for the direct contact with the ohmic electrode
28
, is not stable enough to provide accurate patterning of the device. For example, the wet etching process used in the mesa etching may remove the oxide film
25
around the contact hole
29
, leading to formation of mesa with an irregular shape. Such an irregular mesa structure may cause adverse effects on the Schottky barrier diode, especially the characteristics of the Schottky contact region
31
a.
Furthermore, the polyimide layer
30
has a thickness as large as 6-7 &mgr;m to reduce the parasitic capacitance generated between the Schottky electrode
31
and the underlying structures (the epitaxial layers
22
,
23
and the substrate
21
) at the cathode voltage. To form a step coverage of this thick polyimide layer
30
with the electrodes
31
,
34
,
35
, the edges of the polyimide layer
30
near the Schottky contact region
31
a
must have a tapered cross-section, as shown in FIG.
1
. Such a tapered structure gives rise to a variation of the tapering angle, typically between 30 and 45 degrees. To accommodate this variation, a long separation between the Schottky contact region
31
a
and the ohmic electrode
28
is required. This separation leads to a large resistance and, thus, poor high frequency characteristics. The device shown in
FIG. 1
has a separation of about 7 &mgr;m.
It should also be noted that the large area (2400 &mgr;m
2
) of the anode bonding pad
34
a
further contributes to the increase of the parasitic capacitance of the diode device. Furthermore, the polyimide layer
30
and the thick Au layer are made of expensive materials and their use inevitably increases the production cost.
SUMMARY OF THE INVENTION
The invention provides a Schottky barrier diode including a substrate made of a compound semiconductor and an epitaxially grown layer disposed on the substrate. The Schottky contact region of the device is a part of t
Asano Tetsuro
Hirata Koichi
Ishihara Hidetoshi
Murai Shigeyuki
Nakajima Yoshibumi
Morrison & Foerster / LLP
Ngo Ngan V.
Sanyo Electric Co,. Ltd.
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