Background of the Invention There have been several integration challenges such as inter-metal dielectrics and passivation to be resolved for realizing commercial ferroelectric random access memory (FeRAM). These problems are mostly due to damage from contaminants, particularly hydrogen damage generated during, for example, back-end processing of IMD, passivation, forming a gas anneal and plasma-TEOS deposition. The hydrogen ions and electrons, impregnated during, for example, the plasma-enhanced chemical vapor deposition (PECVD) process using SiH4-based gas chemistry, diffuse into the ferroelectric layers such as PZT or SBT and then pin ferroelectric domains. Moreover, in the worst case, the ferroelectric, as well as certain electrode materials such as SRO (SrRu03) will decompose due to the H2 attack. Both mechanisms lead to considerable degradation of ferroelectric performance of the FeRAM's capacitor. There are many reports of previous efforts attempting to solve the hydrogen-induced problem. One of the efforts involves the insertion of a proper barrier, for example Al203, directly over the capacitor. However, these efforts have had limited success due to incomplete encapsulation. The barrier does not protect the bottom of the capacitor.

FIGURES 1-3 show a conventional process for encapsulating ferroelectric capacitors.

FIGURE 1 shows a wafer 1 following prior art processing steps. A top electrode (TE) 6 is covered with a TEOS (Tetraethyl Orthosilicate) hardmask 2 and mask resist strip patterning is performed using halogen or CO-based chemistry to etch materials such as Iridium, Platinum, Iridium Oxide or various conductive oxide films. A portion of an underlying ferroelectric layer 8 (for example, PZT, SBT, or BLT) is also etched. A FE capacitor 5 is formed from

the top electrode 6, ferroelectric layer 8 and a bottom electrode (BE) 3 as shown in the magnified view of the figure.

A Ti glue-layer 7 serves to adhere the bottom electrode 3 to the substructure of the FE capacitor 5. The substructure includes a top TEOS layer 15 covering a top nitride layer 9. Between the Ti glue-layer 7 and the bottom electrode 3 can be layers of Ir (Iridium), Ir02 (Iridium Oxide) or other materials.

A poly silicon contact plug 13 passes through the wafer 1 to form an electrical connection between an active region and the bottom electrode 3.

Another TEOS hardmask 4 is deposited in preparation for a second etching step. During the second etching step, the ferroelectric layer 8 is further etched along with the bottom electrode 3. There is a slight over-etch through the top TEOS layer 15 along with any intermediate materials such as the layers of Ir (Iridium) and Ir02 (Iridium Oxide). FIGURE 2 shows the wafer 1 following this conventional patterning of the bottom electrode 3.

FIGURE 3 shows the prior art insertion of a barrier layer 19, for example Al203, over the ferroelectric capacitor 5 after the etching steps.

Summary of the Invention The present invention provides a ferroelectric capacitor encapsulation method for preventing hydrogen damage to the electrodes and ferroelectric material of the capacitor.

In general terms, the invention is a method for encapsulating a capacitor comprising etching a bottom electrode of a capacitor to expose an underlying wafer surface. Next an undercut is etched between the capacitor and the wafer surface. The undercut is then refilled with a barrier layer to reduce the diffusion of hydrogen from the surface of the wafer into the capacitor.

Brief Description of the Figures Further preferred features of the invention will now be described for the sake of example only with reference to the following figures, in which: FIGURE 1 shows a prior-art FeRAM capacitor.

FIGURE 2 shows the capacitor after being etched using a conventional process.

FIGURE 3 shows the prior art insertion of a barrier layer over the capacitor.

FIGURE 4 shows the capacitor of Fig. 1 following the undercut etch of the present invention.

FIGURE 5 shows the capacitor of Fig. 4 following encapsulation of the capacitor with a barrier layer.

FIGURE 6 shows the method steps for fabricating the capacitor of Fig. 5.

Detailed Description of the Embodiments The present invention includes an advanced single-step encapsulation of a ferroelectric capacitor using a well defined Ti-undercut which is subsequently refilled with ALD AtzOs.

The process of the present invention is described beginning with the patterned top electrode 6 and etching into the ferroelectric layer 8 as illustrated and previously described with respect to FIGURE 1 and illustrated by step 101 in FIGURE 6.

Following patterning of the top electrode 6, the bottom electrode is etched using the conventional process with a slight over etch into the underlying top TEOS layer 15 as illustrated in FIGURE 4. Additionally, in the present invention, unlike the prior art, a Ti undercut 17 is created using a fluorine rich chemistry in combination with high temperature (>300C) and low bias power to a chuck securing the wafer 1. Low bias power is used in order to decrease the physical component of the etching step by ensuring lower acceleration of plasma ions. At this step fences (the residues from the etching process typically on the sidewalls) are removed and a well defined Ti-undercut 17 between the bottom electrode 3 and the poly silicone plug 13 is formed. The etching stops at the plug 13 due to the plug's different material composition.

This etch and undercut step is illustrated as step 103 in FIGURE 6.

After etching the undercut, encapsulation with ALD (Atomic Layer Deposition) Al203 technology is used to refill the undercut and cover the capacitor with the barrier layer 19, including a large part of the bottom side, in a single step illustrated by FIGURE 5 and the step 105 in FIGURE 6. This Al203 cover around the capacitor substantially blocks a diffusion path for hydrogen through the underlying TEOS layer. The Ti directly above the poly silicone plug 13 is typically not replaced entirely with Al203 because the result would be to interrupt the electrical connection between the capacitor and active region.

Although the invention has been described above using particular embodiments, many variations are possible within the scope of the claims, as will be clear to a skilled reader.