This application claims the benefit of priority based on Taiwan Patent Application No. 096130880 filed on 21 Aug. 2007, the disclosure of which is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a semiconductor device structure. More particularly, the present invention relates to a semiconductor device structure that arranges an insulating dielectric region in a semiconductor device to increase a breakdown voltage.
2. Descriptions of the Related Art
Power devices have been widely used in power electronic fields. Such devices normally have to withstand a considerably high voltage, and when a power device is turned on, a large current is often expected to flow therethrough. Consequently, power devices consume a considerable amount of power.
Therefore, breakdown voltages and turn-on impedances have become two of the greatest factors in designing power devices. Although power devices are designed to deliver both a high breakdown voltage and a low turn-on impedance, it is usually difficult to meet these requirements simultaneously for the following reasons. First, the conventional practice used to obtain a high breakdown voltage is to lower the doping level of extrinsic atoms in the power device. However, this will cause the power device to provide less conductive ions when being turned on, thus resulting in an increased turn-on impedance. In other words, the breakdown voltage is inversely proportional to the doping level: the lower the doping level, the higher the breakdown voltage of the device. At the same time, as shown in the following equation, the higher the breakdown voltage, the higher the impedance of the device. For a device presenting a one-dimensional electric field, the impedance and the breakdown voltage will exhibit the following squared relationship:
Additionally, for a typical PN semiconductor junction, the electric field therein is distributed in a one-dimensional form when a reverse bias is applied. In this case, a curvilinear integral of the electric field (i.e., BV=∫Edx) will result in a breakdown voltage that the junction can withstand under ideal conditions.
Based on this theory, a super junction structure has been proposed as an improved structure, as shown in
However, the concern of charge balance in a power device with a super junction structure leads to an increased difficulty in the manufacturing process. Accordingly, there is still a need in the art for a power device structure that has an increased breakdown voltage, a decreased turn-on impedance, and a less difficult manufacturing process.
One objective of this invention is to provide a semiconductor device structure. By placing at least an insulating dielectric material in a semiconductor region of a semiconductor device to alter the electric field distribution and current flow direction in the semiconductor region, a breakdown voltage of the device is increased.
According to this invention, by arranging at least an insulating dielectric material in the semiconductor region, the electric field distribution in the semiconductor region is modulated from one-dimensional to two-dimensional or even three-dimensional to increase the breakdown voltage of the device. Meanwhile, the turn-on impedance is decreased by shortening the length or increasing the doping level of the semiconductor region. The arrangement of the insulating dielectric material in the semiconductor region has no influence on either the charge balance or the characteristics of the device. Furthermore, this invention allows the use of a simple manufacturing process, and can be manufactured through a semiconductor manufacturing process incorporating a trench forming step.
The detailed technology and preferred embodiments implemented for the subject invention are described in the following paragraphs accompanying the appended drawings for people skilled in this field to well appreciate the features of the claimed invention.
a) is a schematic view of structure in accordance with yet another preferred embodiment of this invention;
b) is a schematic view of structure in accordance with still another preferred embodiment of this invention;
c) is a schematic view of structure in accordance with yet a further preferred embodiment of this invention;
d) is a schematic top view of the embodiment shown in
e) is a schematic view of structure in accordance with still a further preferred embodiment of this invention.
In reference to
The semiconductor region 21 in this embodiment is provided with a first longitudinal dimension H1 and a first lateral dimension W1, while the insulating dielectric region 22 is provided with a second longitudinal dimension H2, a second lateral dimension W2 and a third lateral dimension W3. In this embodiment, H2 is smaller than or equal to H1, and W2 or W3 is also smaller than or equal to W1. Furthermore, when an electric field is applied to the semiconductor region 21, the electric lines of the force in the areas of the semiconductor region 21 near the insulating dielectric region 22 are distorted, resulting in a higher breakdown voltage than that of a semiconductor device without the insulating dielectric region 22.
As can be seen clearly from
As shown in
In
Accordingly, compared to the semiconductor device structure without an insulating dielectric region, the necessary length of the semiconductor device structure 2 in this embodiment may be reduced in the longitudinal direction (i.e., the current flow direction) to design a semiconductor device structure with the same breakdown voltage. The smaller length of the semiconductor region will yield a shorter current flow path. Therefore, as per Equation 2, the turn-on impedance will be effectively decreased under the same breakdown voltage.
To further illustrate effect of this invention, the dimensions of the insulating dielectric region 22 in this embodiment are modulated in Table 1 to simulate the influence on the breakdown voltage and the turn-on impedance. In this table, the reference value represents the turn-on impedance and the breakdown voltage of the semiconductor device structure 2 when the semiconductor region 21 does not comprise the insulating dielectric region 22, i.e., when H2, W2 and W3 all have a zero value. Here, it is assumed that the first longitudinal dimension H1 of the semiconductor region 21 is 70 μm, and the first lateral dimension W1 is 25 μm.
As indicated in Table 1, the breakdown voltage and the turn-on impedance of the semiconductor device structure 2 change as a function of the dimensions of the insulating dielectric region 22.
It follows from the above two embodiments that the breakdown voltage and turn-on impedance of a semiconductor device structure may be modulated by altering the shape of an insulating dielectric region in the semiconductor region. Similarly, the electric field of the semiconductor region may be modulated into at least a two-dimensional field by altering the number and relative positions of the insulating dielectric region, for example, by forming a plurality of insulating dielectric regions made of the same or different insulating materials. Thus, it is also possible to modulate the breakdown voltage and the turn-on impedance of the semiconductor device structure.
To produce a semiconductor device structure with a semiconductor region that comprises an insulating dielectric region, a trench manufacturing process may be used to form an interval space on the semiconductor region, and then an insulating dielectric material is formed in the interval space, as shown in
Next,
e) illustrates another embodiment of this invention. When a polycrystalline semiconductor layer or a conductive layer is formed, the polycrystalline semiconductor layer or the conductive layer may also cover a portion of the semiconductor region in addition to the original trench location. In this figure, a polycrystalline semiconductor layer 621e formed within the insulating dielectric region 62e is illustrated as an example. Such a polycrystalline semiconductor layer 621e covering a portion of the semiconductor region 61 may be formed by depositing outside the original location or by means of a polysilicon gate mask. The polycrystalline semiconductor layer 621e covering a portion of the semiconductor region 61 may act as an electrode of a floating electric field to alleviate the electric field that has accumulated on the surface of the semiconductor region 61 to increase the breakdown voltage.
In the embodiments shown in
In all the aforesaid embodiments, the insulating dielectric region may span across the entire semiconductor region. For example, as shown in
According to the above disclosure, by arranging at least an insulating dielectric material in the semiconductor region, the electric field distribution in the semiconductor region is modulated from one-dimensional to two-dimensional or even three-dimensional to increase the breakdown voltage of the device. Meanwhile, the turn-on impedance is decreased by shortening the length or increasing the doping level of the semiconductor region. Furthermore, this invention allows the use of a simple manufacturing process, and can be manufactured through a semiconductor manufacturing process that incorporates a trench forming step.
The above disclosure is related to the detailed technical contents and inventive features thereof. People skilled in this field may proceed with a variety of modifications and replacements based on the disclosures and suggestions of the invention as described without departing from the characteristics thereof. Nevertheless, although such modifications and replacements are not fully disclosed in the above descriptions, they have substantially been covered in the following claims as appended.
Number | Date | Country | Kind |
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096130880 | Aug 2007 | TW | national |