Method for growing semiconductor film and method for...

Details Method for growing semiconductor film and method for... Method for growing semiconductor film and method for...

2000-03-10

2001-10-23

Kunemund, Robert (Department: 1765)

Single-crystal, oriented-crystal, and epitaxy growth processes;

Forming from vapor or gaseous state

With a step of measuring, testing, or sensing

C117S089000, C117S093000, C117S102000, C117S105000

Reexamination Certificate

active

06306211

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates to a method for growing a semiconductor film on a substrate using gases and also relates to a method for fabricating a semiconductor device using the film growing method.
Recently, new semiconductor or semi-insulating materials have been researched and developed vigorously to realize a semiconductor device with special functions, e.g., specially enhanced radio frequency, emission or voltage-breakdown characteristics. For example, silicon carbide (SiC) is a semiconductor, which is harder, is less likely to be eroded with chemicals and has a wider band gap compared to silicon (Si), and is expected to be applicable to next-generation power electronic devices, radio frequency devices and devices operating at elevated temperatures. However, SiC has a polycrystalline structure, in which not only crystal grains with the same crystal structure and different crystallographic orientations but also crystal grains with various crystal structures coexist. Specifically, crystal grains of SiC include 3C SiC crystal grains with a cubic crystal structure and 6H SiC crystal grains with a hexagonal crystal structure.
Thus, a method for avoiding the formation of such a polycrystalline structure and thereby growing a single crystal SiC film with excellent crystallinity was proposed in Japanese Laid-Open Publication No. 62-36813, for example.
FIG. 16
schematically illustrates a structure of a known vertical SiC crystal grower. As shown in
FIG. 16
, the crystal grower includes chamber
100
, susceptor
101
, support shaft
114
, quartz tube
115
and coil
103
. The susceptor
101
is made of carbon and provides mechanical support for a substrate
102
. The support shaft
114
is provided to support the susceptor
101
thereon. The coil
103
is wound around the quartz tube
115
for inductively heating the susceptor
101
with radio frequency current. The quartz tube
115
is so constructed as to allow cooling water to flow therethrough. The crystal grower is also provided with a gas supply system
107
, in which cylinders of various gases to be supplied into the chamber
100
are disposed, and a gas exhaust system
111
, in which a vacuum pump for exhausting these gases from the chamber
100
is disposed. The gas supply system
107
and the chamber
100
are connected together via source gas, diluting gas and additive gas supply pipes
104
,
105
and
106
for supplying the source gases, a diluting gas such as hydrogen gas and an additive gas like a doping gas, respectively. The source gas supply pipe
104
is combined with the diluting gas supply pipe
105
at a midway point and then the combined pipe is connected to the chamber
100
. At respective sites of the source gas and diluting gas supply pipes
104
and
105
before these pipes are combined, flow meters
108
and
109
are provided to regulate the flow rates of the gases supplied therethrough. Another flow meter
110
is provided for the additive gas supply pipe
106
to regulate the flow rate of the gas passing therethrough. The gas exhaust system
111
and the chamber
100
are connected together via an exhaust pipe
112
, which is provided with a pressure regulating valve
113
for controlling the pressure inside the chamber
100
.
Hereinafter, it will be exemplified how to grow a single crystal SiC film epitaxially on the substrate
102
of silicon or SiC by a CVD process.
First, suppose a single crystal SiC film is to be formed on a silicon substrate. In such a case, hydrocarbon (e.g., propane) and hydrogen gases are introduced from above and into the chamber
100
and the pressure inside the chamber
100
is regulated at atmospheric pressure or less. Radio frequency power is applied to the coil
103
, thereby heating the substrate
102
up to about 1200° C. at the surface thereof. As a result, the surface of the substrate
102
is carbonized to grow a very thin SiC film thereon. Thereafter, the flow rate of the hydrocarbon gas supplied is reduced and a gas containing silicon (e.g., silane gas) is introduced into the chamber
100
, thereby growing a cubic SiC film on the surface of the substrate
102
.
Next, suppose an SiC substrate is used as the substrate
102
. In such a case, a substrate having its principal surface slightly tilted from a (0001) plane (C-plane) by several degrees in the [11-20] direction (such a surface will be called an “off-axis (0001) plane”) is often used. This is because 6H SiC single crystals can be grown on the off-axis (0001) plane, whereas 3C SiC twin crystals are usually grown on the exactly (0001)-oriented plane. By using an SiC substrate with the off-axis (0001) principal surface, an SiC film can be grown on the substrate
102
even without performing any carbonization process thereon if the temperature inside the chamber is set to 1500° C. or more. In adding a dopant to the SiC film, a doping gas is introduced through the additive gas supply pipe
106
into the upper part of the chamber
100
. For example, when an n-type doped layer should be formed, nitrogen may be introduced. In such a case, the flow rate of the doping gas is controlled at a desired concentration using the flow meter
110
. And when the SiC film is formed by this crystal growing process, the supply of respective gases through the pipes
104
,
105
and
106
and the application of radio frequency power to the coil
103
are both stopped, thereby cooling down the substrate
102
.
A horizontal crystal grower, in which the quartz tube
115
of the chamber
100
is placed to have its axis extend horizontally, is also used. The crystal grower includes the same main members as those of the vertical crystal grower shown in FIG.
16
. But in the horizontal crystal grower, various gases are supplied through one of the side faces of the chamber.
The prior art crystal film forming method, however, suffer the following shortcomings.
Firstly, if a MESFET, for example, is formed using a semi-insulating substrate of SiC that has been formed by the above method, then the MESFET cannot always realize expected radio frequency characteristics or performance. Specifically, in a MESFET formed to have a GaAs film grown epitaxially on the substrate by the conventional technique, as the gate length thereof is shortened to cope with increase in operating frequency of the device, the transconductance thereof decreases. This is probably because an increased amount of current leaks from a heavily doped channel layer into a non-doped underlying layer due to a less sharp dopant concentration profile in a transition region between the non-doped and channel layers. Thus, according to a suggested technique, the decrease in transconductance is suppressed by reducing the leakage current using a steeply rising dopant concentration profile that has been created in the channel layer through implantation of a dopant of the opposite conductivity type into the underlying layer.
Such defects involved with that non-sharp dopant concentration profile are noticeable in an SiC crystal film, too. We also found similar defects in crystal films made of various materials other than SiC and GaAs.
Secondly, if an SiC crystal film is grown homoepitaxially on an SiC substrate with the off-axis (0001) principal surface, then large level differences are often formed. FIG.
6
(
a
) illustrates the surface of an SiC crystal film formed by the conventional method. In FIG.
6
(
a
), a surface state near a micro-pipe, which often appears on an SiC substrate, is shown to indicate the heights of the level differences. As shown in FIG.
6
(
a
), a great number of level differences with a width of several hundreds nanometers and a height of several tens nanometers are formed on the surface of the SiC crystal film and the planarity of the SiC crystal film is not so good. We found that those level differences are observable particularly noticeably in a crystal film that has grown homo- or heteroepitaxially on a substrate having its principal surface slightly tilted from a densest plane like a C-plane.
That is to say, we notic

Affiliated with

Also associated with

Rating

Method for growing semiconductor film and method for... does not yet have a rating. At this time, there are no reviews or comments for this patent.

If you have personal experience with Method for growing semiconductor film and method for..., we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Method for growing semiconductor film and method for... will most certainly appreciate the feedback.

Rate now

Comments { 0 }

Profile ID: LFUS-PAI-O-2572391