Zener diodes are two-terminal electronic devices which act as conventional diodes when forward-biased, i.e., with unidirectional conduction, but when reverse-biased above a certain threshold voltage, conduct in the reverse direction. The term “Zener diode” is traditionally applied to devices comprised of p-n junctions formed in conventional semiconductor materials, e.g., Si, which junctions undergo avalanche breakdown at reverse bias potentials above about 5 volts, for example, and such devices may be utilized in voltage regulating and circuit protection circuitry.
A current (I) vs. voltage (V) plot of an idealized Zener diode is illustrated in
During a surge event, it is desired to limit the voltage drop across the device to a minimum value. Accordingly, an important characteristic of a Zener diode is its reverse surge capability.
In accordance with one aspect of the invention, a semiconductor device such as a Zener diode is provided. The semiconductor device includes a first semiconductor material of a first conductivity type and a second semiconductor material of a second conductivity type in contact with the first semiconductor material to form a junction therebetween. A first oxide layer is disposed over a portion of the second semiconductor material such that a remaining portion of the second semiconductor material is exposed. A polysilicon layer is disposed on the exposed portion of the second semiconductor material and a portion of the first oxide layer. A first conductive layer is disposed on the polysilicon layer. A second conductive layer is disposed on a surface of the first semiconductor material opposing a surface of the first semiconductor material in contact with the second semiconductor material.
In accordance with another aspect of the invention, a method is provided of fabricating a semiconductor device. The method includes forming a first oxide layer over a portion of a semiconductor substrate formed from a first semiconductor material having a first conductivity type such that a remaining portion of the semiconductor substrate is exposed. A protective layer is formed on a first surface of the semiconductor substrate and the first oxide layer. A dopant of the second conductivity type is introduced into the semiconductor substrate through the protective layer to form a junction layer that defines a junction with the semiconductor substrate. A first conductive layer is formed over the junction layer. A second conductive layer is formed on a second surface of the semiconductor substrate opposing the first a surface of the semiconductor substrate.
As detailed below, a Zener diode is provided which has an improved reverse surge capability and a reduced leakage current. Although this improvement will be described in terms of one illustrative Zener diode design, the methods and techniques described herein are equally applicable to a wide variety of Zener diode configurations as well as other types of transient voltage suppressors.
During the fabrication process of the Zener diode show in
Without being bound by any theory of operation, the polysilicon layer is believed to reduce defects that are created by the doping process used to form the junction layer 120. When the dopants are directly introduced into the substrate 110 by implantation or the like, defects are typically created to a certain depth within the substrate. These defects may adversely impact the reverse surge performance and the leakage current of the resulting device. By introducing the dopant onto and through a polysilicon layer, however, defects in the substrate can be reduced.
One example of a process that may be used to fabricate the Zener diode shown in
Next, an oxide layer 220 is formed. In one embodiment oxide layer 220 may be produced by exposing the wafer to an environment of approximately 1000° C. for about 200 minutes and to approximately 1200° C. for an additional 200 minutes. During this time the heated semiconductor materials are exposed to a mixture of nitrogen and oxygen gas. In one embodiment, a layer of silicon dioxide ranging in thickness from about 1400 angstroms to about 1800 angstroms is grown on the surface of the structure. It is understood that other processes for forming an oxide layer can be used in connection with the present invention. Further, the oxide layer can be of a different thickness.
Next, a photolithography step is performed to create an opening in the oxide layer. First, as shown in
As shown in
An ion implantation process is next performed. The remaining oxide that has not been etched away forms a hard mask to prevent ions from passing therethrough so that they do not enter the substrate 210. In some cases, the remaining photoresist material, approximately 1.3 microns thick, may be left on the wafer until after the ion implantation procedure to aid the oxide in absorption of ions in the region outside of the exposed window.
The ion implantation process is indicated in
As shown in
A series of Zener diodes were manufactured using a polysilicon layer of different thicknesses to demonstrate the improvements in the reverse surge capability and leakage current that can be achieved. The results are shown in Table 1 for a series of 5 V diodes and a series of 7V diodes. Three samples were manufactured in each series, one with no polysilicon which serves as a control, one with a polysilicon layer 1 micron in thickness and one with a polysilicon layer 2 microns thick. The minimum, average and maximum reverse surge capability and leakage current were measured for each device. As Table 1 shows, the reverse surge capability increases as the polysilicon thickness increases. Likewise, the leakage current decreases as the polysilicon thickness increases, thereby completing the device structure.
Zener diodes were also manufactured with polysilicon layers thicker than 2 microns. For these devices the reverse surge capability was found to decrease as polysilicon thickness increases beyond two microns. This is presumably because of poor thermal dissipation caused by the polysilicon layer. Accordingly, the trade-off between fewer junction defects and poor heat dissipation resulted in an optimal polysilicon thickness of about 1 to 2 um for the 5 and 7 V Zener diodes.
However, for these same devices the leakage current continued to decrease as the polysilicon layer thickness increased to 4 um, which was the sample test thickness limit. The leakage current for the devices with a 4 um thick polysilicon layer was reduced to less than one-tenth of the leakage current of the control sample. Accordingly, for some low voltage diode embodiments, a polysilicon layer thickness of 1-4 um, and more particularly a layer thickness of 1-2 um, may provide a significant increase in the reverse surge capability as well as a decrease in the leakage current.
Those of ordinary skill in the art will recognize that the use of a polysilicon layer to improve the reverse surge capability is applicable to devices having different configurations and compositions from that described above. Moreover, different fabrication techniques from those described above may be employed to manufacture the devices. For instance, As shown in
In other embodiments, a material other than polysilicon may be used to form the layer through which the dopants are introduced to form the junction layer. Any appropriate material may be employed which can serve as a protective layer protecting the substrate surface from damage arising during the doping process, without also forming a barrier to dopant diffusion. An advantage of using a material such as polysilicon, which is electrically conducting, is that it does not need to be removed after completion of the doping process. For instance, while an oxide layer may be used instead of a polysilicon layer, the oxide layer will need to be removed after the structure is doped since it is not an electrically conducting material.
While exemplary embodiments and particular applications of this invention have been shown and described, it is apparent that many other modifications and applications of this invention are possible without departing from the inventive concepts herein disclosed. It is, therefore, to be understood that, within the scope of the appended claims, this invention may be practiced otherwise than as specifically described, and the invention is not to be restricted except in the spirit of the appended claims. Though some of the features of the invention may be claimed in dependency, each feature may have merit if used independently.
This application is a continuation of U.S. application Ser. No. 14/043,431, filed Oct. 1, 2013, the contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 14043431 | Oct 2013 | US |
Child | 14819803 | US |