1. Field of the Invention
The present invention generally relates to a composite epitaxial layer structure and a method for forming the composite epitaxial layer structure. In particular, the present invention is directed to a composite epitaxial layer structure including a doped epitaxial layer and a non-doped epitaxial layer and a method for forming the composite epitaxial layer structure to ensure a stable electric property of a gate channel.
2. Description of the Prior Art
In the process for manufacturing semiconductor elements, it is always a growing challenge for persons in the art to overcome, not only to constantly decrease the critical dimension but also to maintain the performance of the semiconductor elements. One of the challenges is to maintain the carriers, i.e. electrons and electron holes, to have sufficient carrier mobility. It is already known that the carrier mobility in the gate channel of a MOS, such as a P-MOS or an N-MOS, can be adjusted as long as a suitable stress is applied. One of the methods is to grow a strained P-type, such as SiGe:B, or an N-type, such as SiGe:As, doped epitaxial layer in recessed source/drain regions by means of a selective area epitaxial fashion.
Such approach is quite effective. On one hand a strained channel is constructed under the influence of an increased gate channel stress to increase the carrier mobility. On the other hand, the electric resistance of the source and the drain is also collaterally decreased. As to a circumstance of higher gate channel stress, a recessed source and drain of a particular shape will do. Although the recessed source and drain of a particular shape may further increase the stress on the gate channel, some adverse consequence, such as a short channel effect, happens when the dopant, such as B, in the doped epitaxial layer back diffuses into the gate channel.
In view of this, a novel method to form a composite epitaxial layer structure is still needed not only to block the back-diffusing of the dopant in the doped epitaxial layer but also to provide a sufficient gate channel stress.
The present invention as a result proposes a novel method to forma composite epitaxial layer structure. The composite epitaxial layer structure made by the method of the present invention is not only able to block the back-diffusing of the dopant in the doped epitaxial layer, but also able to provide a sufficient gate channel stress. Accordingly, the composite epitaxial layer structure made by the method of the present invention is a total solution to fundamentally provide a sufficient gate channel stress.
The present invention in a first aspect proposes a semiconductor structure. The semiconductor structure of the present invention includes a substrate, agate structure, a source and a drain, a non-doped epitaxial layer and a doped epitaxial layer. The gate structure is disposed on the substrate. The source and the drain are respectively disposed in the substrate and adjacent to the gate structure. At least one of the source and the drain includes a recess disposed in the substrate. The non-doped epitaxial layer is disposed on the inner surface of the recess and substantially consists of Si and an epitaxial material. The non-doped epitaxial layer has a sidewall and a bottom which together cover the inner surface. The bottom thickness is not greater than 120% of the sidewall thickness. The doped epitaxial layer includes Si, the epitaxial material and a dopant and fills the recess. The doped epitaxial layer does not contact the substrate at all due to the segregation of the non-doped epitaxial layer. In one embodiment of the present invention, the doping concentration of the doped epitaxial layer is at least 100 times greater than that of the non-doped epitaxial layer.
The present invention in a second aspect proposes a method for forming a semiconductor structure. First, a substrate is provided. Second, agate structure is formed on the substrate. Next, a plurality of recesses are form in the substrate and adjacent to the gate structure. Then, a non-doped epitaxial layer is formed on the inner surface of the recesses. The non-doped epitaxial layer substantially consists of Si and an epitaxial material and is free of a dopant. The non-doped epitaxial layer has a sidewall and a bottom and the bottom thickness is not greater than 120% of the sidewall thickness. Later, a doped epitaxial layer including Si, the epitaxial material and the dopant is formed and fills the recess. In one embodiment of the present invention, the ratio of the bottom thickness to the sidewall thickness may be between 0.83 and 1.20.
The present invention in a third aspect proposes a method for forming a semiconductor structure. First, a substrate is provided. Second, a plurality of recesses are formed in the substrate. Next, a precursor mixture is provided to form a non-doped epitaxial layer on the inner surface of the recesses. The precursor mixture includes a silicon precursor, an epitaxial material precursor and a hydrogen-halogen compound. The flow rate ratio of the silicon precursor to the epitaxial material precursor is greater than 1.7. Later, a doped epitaxial layer including Si, the epitaxial material and the dopant is formed and substantially fills up the recess. In one embodiment of the present invention, a gate structure is formed on the substrate so that the recesses are adjacent to the gate structure.
On one hand, due to the segregation of the non-doped epitaxial layer in the composite epitaxial layer structure of the present invention, the doped epitaxial layer does not contact the substrate at all, so the back-diffusing of the dopant in the doped epitaxial layer is blocked. On the other hand, non-doped epitaxial layer has a proper bottom to sidewall thickness ratio, so a sufficient gate channel stress is able to be induced to maintain the carriers in the gate channel to have sufficient carrier mobility.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
The present invention provides a semiconductor structure and the method for making the same. The semiconductor structure of the present invention has a non-doped epitaxial layer sticking to a recess and serving as a buffer layer. The doped epitaxial layer may block the back-diffusing of the dopant in the doped epitaxial layer. Besides, the non-doped epitaxial layer has a proper thickness ratio so the stress generated by the doped epitaxial layer is not compromised.
The present invention in a first aspect provides a method for making a semiconductor structure.
Next, please refer to
Optionally, at least one of the recesses 120/130 may extend outwards, for example, to and under the gate conductive layer 111, or even further to and under the spacer 113, and overlaps with the gate conductive layer 111 or even with the spacer 113. The extending recesses 120/130 may be formed by first anisotropically etching the substrate then followed by isotropically etching the substrate to perform a lateral etching.
Then, as shown in
The non-doped epitaxial layer 122/132 substantially consists of Si and an epitaxial material. Preferably, the non-doped epitaxial layer 122/132 is free of a dopant. The epitaxial material may be multivalent atoms larger or smaller than silicon, such as at least one of Ge, C, Ga, Sn and Pb. The non-doped epitaxial layer 122/132 may be formed by a conventional method. For example, the non-doped epitaxial layer 122/132 is formed by an epitaxial method using a suitable silicon precursor and a suitable epitaxial material precursor to form a non-doped epitaxial layer 122/132 in the recesses 120/130 and on the inner surface of the recesses 120/130. Please notice that the non-doped epitaxial layer 122/132 does not completely fill up the recesses 120/130.
Later, please refer to
For example, a suitable silicon precursor, a suitable epitaxial material precursor and a dopant are provided, so the doped epitaxial layer 125/135 is formed by an epitaxial method to fill the recesses 120/130. In accordance with different procedures, the dopant concentration in the doped epitaxial layer 125/135 may have different embodiments as well. For example, the doped epitaxial layer 125/135 may have a fixed doping concentration. Or, the doped epitaxial layer 125/135 may have a gradient doping concentration distribution. Although the doped epitaxial layer 125/135 is disposed within the recesses 120/130 and in direct contact with the non-doped epitaxial layer 122/132, the doped epitaxial layer 125/135 does not directly contact the substrate 101 at all due to the segregation of the non-doped epitaxial layer 122/132.
Optionally, the semiconductor structure 100 may include an etching-stop layer (not shown). In addition, the non-doped epitaxial layer 122/132 and the doped epitaxial layer 125/135 may continue to be converted to become a set of source 128 and drain 138. Later a silicide may be selectively formed on the surface of the source 128 and the drain 138, and a source contact plug 129 and a drain contact plug 139 are formed on the source 128 and the drain 138 to serve as the electric connection of the source 128 and the drain 138, as shown in
The present invention in a second aspect provides another method for making a semiconductor structure.
Next, please refer to
Then, as shown in
The following steps may be used to render the bottom 223/233 and the sidewall 224/234 of the non-doped epitaxial layer 222/232 to have a proper thickness ratio. For example, a precursor mixture 240 is provided to form the non-doped epitaxial layer 222/232 on the inner surface 221/231 of the recesses 220/230 by an epitaxial method. The precursor mixture 240 may include various components. For example, the precursor mixture 240 may include a silicon precursor, an epitaxial material precursor and a hydrogen-halogen compound. The silicon precursor may include dichlorosilane. The epitaxial material precursor may include multivalent atoms larger or smaller than silicon, such as at least one of Ge, C, Ga, Sn and Pb. The hydrogen-halogen compound may be hydrogen chloride. Another feature of the present invention lies in the flow rate ratio of the silicon precursor to the epitaxial material precursor to be greater than 1.7.
Because the precursor mixture 240 is dopant-free, the resultant non-doped epitaxial layer 222/232 is supposed to be dopant-free, too. Please notice that the resultant non-doped epitaxial layer 222/232 does not fill up the recesses 220/230 completely. In one preferred embodiment of the present invention, the ratio of the bottom thickness to the sidewall thickness of the resultant non-doped epitaxial layer 222/232 may be between 0.83 and 1.20.
Later, please refer to
For example, a suitable silicon precursor, a suitable epitaxial material precursor and a dopant are provided, so the doped epitaxial layer 225/235 is formed by any proper conventional method, such as an epitaxial method to fill the recesses 220/230. In accordance with different procedures, the dopant concentration in the doped epitaxial layer 225/235 may have different embodiments as well. For example, the doped epitaxial layer 225/235 may have a fixed doping concentration. Or, the doped epitaxial layer 225/235 may have a gradient doping concentration distribution. Although the doped epitaxial layer 225/235 is disposed within the recesses 220/230 and in direct contact with the non-doped epitaxial layer 222/232, the doped epitaxial layer 225/235 does not directly contact the substrate 201 at all due to the segregation of the non-doped epitaxial layer 222/232.
Optionally, the semiconductor structure 200 may include an etching-stop layer (not shown). Please refer to
After the previous steps, a semiconductor structure is consequently obtained.
The source 128 and the drain 138 may have a recessed or bulging structure, so at least one of the source 128 and the drain 138 includes a recess 120/130 disposed in the substrate 101. The recess 120/130 may include two different epitaxial layers, such as a non-doped epitaxial layer 122/132 and a doped epitaxial layer 125/135. The shapes and chemical compositions of the non-doped epitaxial layer 122/132 and the doped epitaxial layer 125/135 are different.
The non-doped epitaxial layer 122/132 is disposed on the inner surface 121/131 of the recess 120/130 and covers the inner surface 121/131. The non-doped epitaxial layer 122/132 has a sidewall 124/134 and a bottom 123/133. One feature of the present invention resides in that the bottom 123/133 thickness is not greater than 120% of the sidewall 124/134 thickness. In one preferred embodiment of the present invention, the ratio of the bottom thickness to the sidewall thickness may be between 0.83 and 1.20. The resultant non-doped epitaxial layer 122/132 may be in a form of an open box.
The non-doped epitaxial layer 122/132 substantially consists of Si and an epitaxial material. Preferably, the non-doped epitaxial layer 122/132 is free of a dopant. The epitaxial material may be multivalent atoms larger or smaller than silicon, such as at least one of Ge, C, Ga, Sn and Pb. Please notice that the non-doped epitaxial layer 122/132 does not completely fill up the recesses 120/130.
The doped epitaxial layer 125/135 fills up the recess 120/130.
Although the non-doped epitaxial layer 122/132 is preferably free of a dopant, the original non-doped epitaxial layer 122/132 is still possibly contaminated by dopants owing to other reasons, such as in direct contact with the dopant-containing doped epitaxial layer 125/135. Nevertheless, the dopant concentration in the non-doped epitaxial layer 122/132 should be as small as possible so that the doping concentration of the doped epitaxial layer 125/135 is at least 100 times greater than that of the non-doped epitaxial layer 122/132.
In accordance with different embodiments, the dopant concentration in the doped epitaxial layer 125/135 may be different. For example, the doped epitaxial layer 125/135 may have a fixed doping concentration. Or, the doped epitaxial layer 125/135 may have a gradient doping concentration distribution. Although the doped epitaxial layer 125/135 is disposed within the recesses 120/130 and in direct contact with the non-doped epitaxial layer 122/132, the doped epitaxial layer 125/135 does not directly contact the substrate 101 at all due to the segregation of the non-doped epitaxial layer 122/132 so the back-diffusing of dopants can be blocked.
Optionally, the non-doped epitaxial layer 122/132 and the doped epitaxial layer 125/135 may be the source 128 and drain 138 of the gate structure 110. There is a gate channel 102 between the source 128 and drain 138, under the gate structure 110 and in the substrate 101. Besides, a silicide may be selectively formed on the surface of the source 128 and the drain 138. Furthermore, a source contact plug 129 and a drain contact plug 139 are formed on the source 128 and the drain 138 to serve as the electric connection of the source 128 and the drain 138, as shown in
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
This application is a divisional application of and claims the benefit of U.S. patent application Ser. No. 12/897,728, filed Oct. 4, 2010.
Number | Date | Country | |
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Parent | 12897728 | Oct 2010 | US |
Child | 13707613 | US |