PLANAR TRIPLE-IMPLANTED JFET
A JFET is formed with vertical and horizontal elements made from a high band-gap semiconductor material such as silicon carbide via triple implantation of a substrate comprising an upper drift region and a lower drain region, the triple implantation forming a lower gate, a horizontal channel, and an upper gate, in a portion of the drift region. A source region may be formed through a portion of the top gate, and the top and bottom gates are connected. A vertical channel region is formed adjacent to the planar JFET region and extending through the top gate, horizontal channel, and bottom gate to connect to the drift, such that the lower gate modulates the vertical channel as well as the horizontal channel, and current from the sources flows first through the horizontal channel and then through the vertical channel into the drift.
Vertical junction field-effect transistors made from wide bandgap materials such as silicon carbide are useful in power electronic circuits, such as power factor correction (PFC) circuits, DC-DC converters, DC-AC inverters, and motor drives.
SUMMARYJunction field-effect transistors (JFETs) and methods of constructing JFETs are described herein. A JFET having vertical and horizontal elements may be made from a semiconductor material such as silicon carbide (SiC) by a process using a triple implantation to form a horizontal planar JFET region comprising a lower gate, a horizontal channel, and an upper gate, all above a drift region resting on a drain substrate region. A source region may be formed through a portion of the top gate, and the top and bottom gates are connected. A vertical channel region may be formed adjacent to the planar JFET region and extending through the top gate, horizontal channel, and bottom gate to connect to the drift, such that the lower gate modulates the vertical channel as well as the horizontal channel, and current from the sources flows first through the horizontal channel and then through the vertical channel into the drift region.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to limitations that solve any or all disadvantages noted in any part of this disclosure.
A more detailed understanding may be had from the following description, given by way of example in conjunction with the accompanying figures. The figures are not necessarily drawn to scale.
Junction field-effect transistors and methods of constructing JFETs are described herein. A JFET having vertical and horizontal planar elements may be made from a high band-gap semiconductor material such as silicon carbide (SiC) by a process using a triple implantation on a substrate comprising an upper drift region and a lower drain region. The triple implantation is used to form a horizontal planar JFET region comprising a lower gate, a horizontal channel, and an upper gate, all above a drift region resting on a drain substrate region. A source region may be formed through a portion of the top gate, and the top and bottom gates are connected. A vertical channel region is formed adjacent to the planar JFET region and extending through the top gate, horizontal channel, and bottom gate to connect to the drift, such that the lower gate modulates the vertical channel as well as the horizontal channel, and current from the sources flows first through the horizontal channel and then through the vertical channel into the drift.
When making transistors in a wide-bandgap semiconductor material, such as SiC, GaN, AlN, or diamond, JFET-type structures are often preferred over MOS-type structures. This is due to the difficulty of obtaining the same quality of oxide interface as seen with Si/SiO2. This in turn makes it difficult to achieve transistors with the same level of reliability in MOS surface conduction channels, which are prone to degradation. JFETs avoid this issue because JFETs are bulk devices, unlike MOS devices, and do not require surface conduction channels. This is particularly advantageous for high power devices, since surface conduction channel reliability issues are exacerbated at higher operating temperatures.
Precise control of the threshold voltage (Vth) in such a trench vertical JFET may be challenging since Vth varies with the amount and the position of charge in the channel 103. These may be strongly affected by process variations. For example, the mesa width may fluctuate due to variations in the photo process, the etch process, and the etch slope. This may lead to large variations in Vth. These variations may be reduced to some extent by forming the channel 102 by implantation. However, some variation in mesa dimensions and sidewall angles will persist. For example, in order to maintain good blocking capability in the off-state, especially for normally-off devices and normally-on devices with very negative Vth voltages, the vertical structure requires the use of very long channel regions 102. This in turn adds the complexity of deep trench etches, which are quite difficult to control in wide bandgap materials.
The gate regions 105a, 105b and 105c are of the opposite doping type to the drain 107, drift 106, vertical channels 102a and 102b, horizontal channel 104, and source 103. Lightly doped regions 101a and 101b of either doping polarity may be used to increase gate-source breakdown voltage and/or add a source ballast resistance. For example, the lightly doped regions 101a and 101b may be doped at ten percent or less of the doping level of the adjacent source 103 or gates 105a and 105c. Such added source ballast resistance may benefit device operation in short circuit mode, and is particularly useful when the JFET is employed as a current limiting device. The gate connection region 105d is the same polarity as the gate regions 105a, 105b and 105c, but a heavier implant is used to short the top and bottom gates and to provide a sufficient surface doping for good ohmic contact formation.
At the left of
The vertical JFET is formed by the combination of bottom gate regions 305c and 305d and the vertical channel region 302. The current from lateral channels 304a and 304b flows down the vertical channel 302 between the gate regions 305d and 305d, and then into the drift region 306, and from there into the substrate drain region 307 and ultimately to the drain contact 308.
The lateral JFET sets the device threshold voltage, Vth. The vertical JFET is useful in shielding the lateral channels 304a-b from the effects of high drain bias once the region between 305c and 305d has been depleted. In making devices where low on-resistance and short channel lengths are required, this feature allows the designer to make the lateral channels quite short without suffering from drain bias induced barrier lowering and the loss of blocking capability. This is particularly useful in making normally-off JFETs. In the case of 4H-SiC normally-off JFETs, the device Vth must ideally be kept close to 1V with +/−0.2V control. This is because the gate drive voltage should be kept between 2.5-3V to limit the maximum gate current that results from forward biasing the gate-source junction. Given that the overdrive voltage available is just 2.5V-1V=1.5V, a short channel is needed to get a high on-state current. In the trench structure, this is not possible without degrading the blocking capability of the device, so a high cell repeat density must be used. The shielding effect of the lower gate may be employed to minimize channel length. By disposing the peak of the channel implant close to the top gate junction, a higher channel charge is also possible for the same Vth, further allowing a high transconductance for normally-off devices.
While connecting the bottom gate regions 305c and 304d to the gate potential instead of to the source potential increases the gate-drain capacitance, it serves the purpose of depleting both the lateral channels 304a and 304b and the vertical channel 302 channels much more effectively. This in turn allows a greater doping level in the lateral and vertical channel 302, leading to lower specific on-resistance.
In
Mask 1202 may also be opened at the outer termination edge for the creation of a channel stop, along with the subsequent source implant.
In
The energy of implant 1301 is selected to balance design considerations. Region 603 should be deep enough to connect to the channel 604. However, it is preferable that implant 1301 does not increase the doping at the junction of the channel 604 to bottom gate 605b. This avoids or reduces any loss of gate-source breakdown or any increased leakage in the gate-source junction. Of course, the designer may also tune this depth. For example, a specific zener clamp voltage may be desired between the gate and source.
Once the implants are activated, the surface is cleaned and a dielectric is deposited.
In describing embodiments of the subject matter of the present disclosure, as illustrated in the figures, specific terminology is employed for the sake of clarity. The claimed subject matter, however, is not intended to be limited to the specific terminology so selected, and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner to accomplish a similar purpose.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
Claims
1. A method for creating a JFET, comprising:
- a. applying a first mask to a wafer to form a first patterned hard masking layer to the top of the wafer, the wafer comprising an upper drift region and a bottom drain region;
- b. applying three implants to the unmasked portion of the top of the wafer to form a lower gate region, a horizontal channel region, and a top gate region in an upper portion of the drift region;
- c. forming a source region in a portion of the top gate region;
- d. connecting the top and bottom gate regions.
2. The method of claim 1, further comprising:
- a. forming a vertical channel region via implantation, the vertical channel region being at a distance from the source region, the vertical channel region being adjacent to, and extending through, the top gate region, the horizontal channel region, and the bottom gate region, to connect to the drift region.
3. The method of claim 2, further comprising:
- a. forming the vertical channel region via angled implantation with the first patterned hard masking layer in place.
4. The method of claim 2, further comprising:
- a. forming a lightly doped region surrounding the source region via implantation, where the lightly doped region is doped at ten percent or less of the level of doping of the source region.
5. The method of claim 2, further comprising:
- a. forming a vertical channel region between two regions each comprising an upper and lower gate region.
6. The method of claim 2, further comprising:
- b. forming two vertical channel regions, one at each end of a region comprising an upper gate region and a lower gate region.
7. A JFET, comprising:
- a. a silicon carbide drift region atop a backside drain;
- b. in a portion of the top of the drift region, a top gate region having a shape in plan view with outer dimensions;
- c. beneath the top gate region, a horizontal channel region having the shape and outer dimensions in plan view, the horizontal channel region being vertically aligned with the top gate region;
- d. beneath the horizontal channel region, a bottom gate region having the shape and outer dimensions in plan view, the bottom gate region being vertically aligned with the topside gate region;
- e. a connection from the top gate region to the bottom gate region;
- f. within the outer dimensions in plan view of the top gate region, a source region; and
- g. abutting the top gate region, horizontal channel region, and bottom gate region to one side, a vertical channel region, the vertical channel region extending vertically below the bottom gate region to abut the drift region;
- h. where a first, second, and third doping concentration of the drain, the vertical channel region, and the horizontal channel region respectively are selected such that the threshold of the JFET is set by the horizontal channel region,
- i. such that, when activated by the top gate region and bottom gate region, current flows from source region into the horizontal channel region and then into the vertical channel region, drift region, and the backside drain.
8. (canceled)
9. A JFET, comprising:
- a. a drift region atop a drain;
- b. in a portion of the top of the drift region, a top gate region defined by a patterned mask;
- c. beneath the top gate region, a horizontal channel region defined by the patterned mask;
- d. beneath the horizontal channel region, a bottom gate region defined by the patterned mask;
- e. a connection from the top gate region to the bottom gate region;
- f. in a portion of the top gate region, a source region, such that current flows from source region in to the horizontal channel region and then into the drift region; and
- g. a ring of material around the source region, between the source region and the top gate region, where the ring of material has a doping concentration that is—at ten percent or less of the doping concentration—of the source region.
10. (canceled)
11. (canceled)
12. The JFET of claim 7, wherein the top gate region abuts the source region.
13. The JFET of claim 7, wherein the first connection from the first top gate region to the first bottom gate region is a bridge of implanted semiconductor material.
14. (canceled)
15. (canceled)
16. The JFET of claim 9, wherein the first connection from the first top gate region to the first bottom gate region is a bridge of implanted semiconductor material.
17. The JFET of claim 9, further comprising:
- a first vertical channel region at a distance from the source region, the first vertical channel region being adjacent to, and extending through, the top gate region, the horizontal channel region, and the bottom gate region, to connect to the drift region.
18. The JFET of claim 17, further comprising
- a. a second vertical channel at a distance from the source region, the second vertical channel region being adjacent to, and extending through, the top gate region, the horizontal channel region, and the bottom gate region, to connect to the drift region,
- b. wherein the first vertical channel is located at a first end of the horizontal channel and the second vertical channel is located at a second end of the horizontal channel.
19. The JFET of claim 7, further comprising:
- a ring of material around the source region, between the source region and the top gate region, where the ring of material has a doping concentration that is at ten percent or less of the doping concentration of the source region.
Type: Application
Filed: Oct 21, 2015
Publication Date: Apr 27, 2017
Inventors: Anup Bhalla (Princeton Junction, NJ), Zhongda Li (Somerset, NJ)
Application Number: 14/918,774