Ferroelectric capacitor with electrode formed in separate...

Active solid-state devices (e.g. – transistors – solid-state diode – Field effect device – Having insulated electrode

Reexamination Certificate

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C257S295000, C438S003000

Reexamination Certificate

active

06825515

ABSTRACT:

The present application is based on Japanese priority application No.11-304628 filed on Oct. 26, 1999, the entire contents of which are hereby incorporated by reference.
BACKGROUND OF THE INVENTION
The present invention generally relates to semiconductor devices and more particularly to a ferroelectric capacitor, a semiconductor device having such a ferroelectric capacitor, and a fabrication process thereof.
Conventionally, EPROMs and flash memory devices are used extensively as a non-volatile semiconductor memory device that retains information even when electric power is turned off. These EPROMs and flash memory devices have a floating gate electrode and a tunneling insulation film cooperating therewith for retaining information. Particularly, a flash memory device has a simple construction in that only a single memory cell transistor is included in a single memory cell similarly to the case of a DRAM, and is thus suitable for constructing a large-scale integrated circuit.
In a flash memory device, in which writing or erasing of information is achieved by way of hot-electron injection or removal to and from the floating gate electrode via the tunneling insulation film, it is necessary to use a high voltage at the time of writing or erasing operation. Thus, it is inevitable that a large electric field is applied to the tunneling insulation film, while such a large electric field induces deterioration of the tunneling insulation film and limits the lifetime of the flash memory device. Further, in view of the fact that writing of information is achieved by way of injection of hot electrons, it takes a considerable time for writing information in flash memory devices. While a flash memory device is capable of storing multi-value information by controlling the amount of the electric charges injected into the floating gate electrode, such a possibility of multi-value storage of information also indicates the necessity of careful control of the electric charge injection by taking into account the degree of deterioration of the tunneling insulation film. Otherwise, erroneous operation will be caused.
A ferroelectric random access memory device is a semiconductor memory device having a ferroelectric capacitor that uses a ferroelectric film as the capacitor insulation film and stores information in the ferroelectric film in the form of spontaneous polarization of the ferroelectric film. In a ferroelectric random access memory device, writing or erasing of information is achieved by inverting the direction of the foregoing spontaneous polarization of the ferroelectric capacitor insulation film. Such an inversion of the polarization is achieved only by way of application of electric voltage and injection of electric current is not necessary. Thus, a ferroelectric random access memory device provides the advantageous features of very fast speed of writing operation and small power consumption. Further, in view of the fact that the polarization of the ferroelectric capacitor is limited either to a positive direction or a negative direction, there arises no problem of excessive erasing as in the case of a flash memory device.
FIG. 1
shows the construction of a conventional memory cell of a conventional ferroelectric random access memory device.
Referring to
FIG. 1
, the memory cell has a so called 2T/2C construction that uses two transfer gate transistors T
1
and T
2
and two ferroelectric capacitors C
1
and C
2
for storing one-bit information. In the construction of
FIG. 1
, the memory cell achieves a complementary operation in which information “1” is stored in one of the capacitors and information “0” is stored in the other capacitor.
In more detail, the transfer gate transistors T
1
and T
2
are turned on by selecting a word line WL, and the information “1” or “0” is written into the capacitor C
1
from a bit line BIT connected to the transistor T
1
. Simultaneously, the complementary information “0”, or “1” is written into the capacitor C
2
from a complementary bit line /BIT. Thereby, the ferroelectric capacitor insulation films of the capacitors C
1
and C
2
store the written information in the form of spontaneous polarization.
In the reading mode operation of the memory cell, the word line WL is selected again and the transistors T
1
and T
2
are turned on. Further, the voltage difference appearing across the bit lines BIT and /BIT as a result of the respective polarizations of the ferroelectric capacitors C
1
and C
2
is detected by a sense amplifier S/A.
Generally, a ferroelectric material having a perovskite crystal structure such as PZT having a composition (Pb,Zr)TiO
3
or PLZT having a composition (Pb, Zr) (Ti,La)O
3
is used for the ferroelectric capacitor insulation film in the capacitors C
1
and C
2
. Alternatively, a Bi compound having a layered structure such as SrBi
2
Ta
2
O
9
designated as SBT or a compound represented as SrBi
2
(Ta,Nb)
2
O
9
designated as SBTN may be used for the ferroelectric capacitor insulation film.
When forming such a ferroelectric capacitor, it is generally practiced to deposit the ferroelectric film by a sol-gel process or sputtering process in the form of amorphous phase. The amorphous film thus formed is then subjected to a crystallization process by applying a high-temperature annealing process for a very short time. Without crystallization, the film does not provide the desired ferroelectric polarization.
In such a crystallizing process, there is a tendency that the PZT or PLZT film undergoes oxygen defect formation. Thus, in order to avoid the oxygen defect formation and to avoid deterioration of the ferroelectric property, it is practiced to carry out the crystallization process-in an oxidizing atmosphere. Thereby, in order to avoid the unwanted problem of oxidation of the lower electrode of the ferroelectric capacitor, there is a proposal to carry out the crystallization process first in an inert atmosphere and then in an oxidizing atmosphere.
After the foregoing crystallization and oxygen compensation process, the upper electrode of the ferroelectric capacitor is formed on the ferroelectric film thus processed. Conventionally, such a formation of the upper electrode has been achieved by sputtering a refractory metal film such as a Pt film or an Ir film. As the sputtering process of the Pt film or Ir film is conducted in a non-oxidizing atmosphere, there has been a problem that the oxygen defects are formed again in the ferroelectric film with the deposition of the upper electrode.
In relation to the problem of oxygen-defect formation at the time of deposition of the upper electrode, there has been a proposal to use a conductive oxide film such as an IrO
2
film for the upper electrode of the ferroelectric capacitor. By using such a conductive oxide film for the upper electrode, the problem of oxygen-defect formation in the ferroelectric capacitor insulation film at the time of deposition of the upper electrode is successfully avoided by conducting the deposition of the upper electrode in an oxidizing atmosphere, and the problem of increase of the resistance of the upper electrode caused by the oxidation is also avoided as a result of use of oxide for the electrode.
Meanwhile, it has been known that the process of forming an IrO
2
electrode film tends to induce the problem of abnormal growth of the IrO
2
crystals leading to the formation of giant IrO
2
crystals. Such giant IrO
2
crystals act as defect in the IrO
2
electrode and cause a decrease of yield of production of the semiconductor device. Further, electric properties of the ferroelectric capacitor are deteriorated by the existence of such giant IrO
2
crystals.
SUMMARY OF THE INVENTION
Accordingly, it is a general object of the present invention to provide a novel and useful ferroelectric capacitor and a semiconductor device having such a ferroelectric capacitor wherein the foregoing problems are eliminated.
Another and more specific object of the present invention is to provide a ferroelectric capacitor having an upper electrode formed of a conductive oxide whe

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