1. Field of the Invention
The invention relates to a semiconductor electronic device primarily used for high-power and/or high-frequency electric/electronic circuit. More specifically, the invention relates to e.g. diodes or transistors such as Schottky diodes, metal-semiconductor field effect transistors (MESFET), metal insulator semiconductor field effect transistors (MISFET), bipolar transistors, and heterobipolar transistors (HBT) using group III nitride semiconductor.
The invention also relates to a method of making such electronic devices.
The invention also relates to an epitaxial multi-layer wafer used to fabricate such electronic devices.
2. Description of the Existing Technology
(Note: This patent application refers several publications and patents as indicated with numbers within brackets, e.g., [x]. A list of these publications and patents can be found in the section entitled “References.”)
Gallium nitride (GaN) and its related group III nitride alloys are the key semiconductor material for various electronic devices such as power switching transistors. Despite the fact that the maximum performance of GaN theoretically predicted with Baliga's Figure of Merit (BFOM) exceeds that of silicon carbide (SiC) by ˜5-fold, the lack of low-cost GaN wafers impedes development of GaN-based power switching transistors that can switch between two voltage levels quickly and with minimal loss. Currently, the majority of these devices are fabricated using a group III nitride film grown heteroepitaxially on a heterogeneous wafer, such as silicon, SiC and sapphire. However, heteroepitaxial growth of group III nitride results in highly defective or even cracked films. Typical defects in group III nitride heteroepitaxial films are threading dislocations at the level of 109 cm−2 along the growth direction. Because of this, vertical defects can become a current leakage path when high-voltage is applied vertically (i.e. along the growth direction). At this moment, GaN-based electronic devices are practically limited to horizontal devices such as high-electron mobility transistors (HEMT), which utilize current flow along the lateral directions near the surface. Since the electric current passes through a thin film in such horizontal devices, the thin film must have a large area to provide high-current (i.e. high-power) devices. In addition, all contacts are located on one side of the device, which makes the device much larger than a device having a vertical configuration. Due to these limitations, it is quite challenging to attain high-power devices in horizontal configuration of group III nitride semiconductors.
A homoepitaxial wafer or substrate such as GaN or AN is required to provide a GaN-based electronic device with a vertical configuration. The lack of low-cost and high crystallinity GaN substrates originates from difficulties in growing bulk crystal of GaN and other group III nitride compounds. Currently, the majority of commercially available GaN wafers are produced by hydride vapor phase epitaxy (HVPE). HVPE is a vapor phase method in which it is difficult to make GaN having a dislocation density less than 105 cm−2 when GaN grown on heteroepitaxial wafers (e.g. sapphire). Furthermore, the manufacturing process involves removal of the heteroepitaxial wafer after growing a thick (more than 0.1 mm) GaN layer, which is quite labor intensive and results in low yield.
Ammonothermal growth has been developed [1-6] to obtain low-cost, high crystallinity GaN substrates in which the density of dislocations and/or grain boundaries is less than 105 cm−2. The ammonothermal method is one of the bulk growth methods of group III nitride crystals using supercritical ammonia. Growth rate of crystals in supercritical ammonia is typically low. To grow bulk GaN crystals at a practically useful rate to produce substrates, a chemical additive called a mineralizer is added to the supercritical ammonia. A mineralizer is typically an element or a compound of group I elements or group VII elements, such as potassium, sodium, lithium, potassium amide, sodium amide, lithium amide, ammonium fluoride, ammonium chloride, ammonium bromide, ammonium iodide and gallium iodide. Sometimes more than two kinds of mineralizers are mixed to attain a good growth condition. Although most of the alkali-based mineralizers are interchangeable, sodium is the most favorable mineralizer in terms of growth rate, purity and handling. GaN substrates having dislocation density less than 105 cm−2 are produced using sodium mineralizer in ammonothermal growth. However, to achieve high-power electronic device having a vertical configuration with ammonothermal group III nitride substrates (in which one electrode is on one side or surface of a substrate and its corresponding electrode is formed on an opposite side or surface of the substrate so that the substrate resides between the two electrodes), an innovative device structure and fabrication method is required.
The present invention provides, in one instance, an electronic device using a group III nitride substrate fabricated via the ammonothermal method. By utilizing the high-electron concentration of ammonothermally grown substrates having the dislocation density less than 105 cm−2, combined with a high-purity, low-carrier concentration active layer of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) grown by e.g. a vapor phase method, a device can be made that has a high breakdown voltage as well as low resistance when the device is in its “on” state (“on-resistance”). To realize a better match between the ammonothermally grown substrate and the high-purity, low-carrier concentration active layer, a transition layer is optionally introduced. The electronic device operates by changing a depletion region in the active layer. The high-purity, low-carrier concentration active layer is preferably sufficiently thick that the depletion region in the active layer does not extend through the active layer's entire thickness, and preferably the active layer is sufficiently thick to avoid the depletion region from extending into the interface and/or the substrate on which the high-purity, low-carrier concentration active layer resides.
Consequently, in one instance the invention provides an epitaxial multi-layer wafer for fabricating electronic devices. This wafer may comprise (i) a group III nitride substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) having a first side and a second side opposite to the first side and (ii) an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on the first side of the group III nitride substrate. The dislocation density of the group III nitride substrate may be less than 105 cm−2. The group III nitride substrate may also have an electron concentration and/or an oxygen concentration higher than 1018 cm−3. The group III nitride substrate may be fabricated from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown in supercritical ammonia. The active layer may be an epitaxially deposited layer which has an electron and/or an oxygen concentration lower than 1018 cm−3. The active layer may have a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating the electronic device with a first electrode on the first side of the wafer and a second electrode on the second side of the wafer is outside of the substrate.
The invention also provides an electronic device that includes a wafer as set out above and elsewhere herein. One of the electrodes may be on a first face of the wafer, and another of the electrodes may be on a second, opposite face of the wafer. The electrodes may cooperate to form e.g. a transistor or diode as the electronic device.
The invention in another instance provides a new method of making a multi-layer wafer. The method may comprise epitaxially depositing from vapor phase an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) upon a first side of a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1), where the substrate was formed by an ammonothermal method. The active layer may have a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating an electronic device with a first electrode on the first side of the wafer and a second electrode on a second, opposite side of the wafer is outside of the substrate. The substrate may have an oxygen concentration and/or an electron concentration of greater than 1018 cm−3, and the vapor phase may have a sufficiently low concentration of oxygen and/or concentration of electron donor to provide an oxygen concentration and/or an electron concentration in the active layer of less than 1018 cm−3.
The invention further provides a new electronic device. This device may comprise a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1), an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on a first side of the substrate, and a back ohmic contact on a second side of the substrate that is opposite to the first side of the substrate.
The contacts of the device may form a depletion region in the active layer that has a depth, and the active layer may have a thickness greater than the depth of the depletion region for any applied voltage within an operation range of the device. Further or instead, the active layer and the transition layer may have a combined thickness that is greater than the depth of the depletion region for any applied voltage within the operation range of the device.
The substrate of a device as discussed above or elsewhere herein may have a dislocation density of less than 105 cm−2. The substrate may have an electron concentration and/or an oxygen concentration greater than 1018 cm−3. The active layer of a device as discussed above or elsewhere herein may have an electron concentration and/or an oxygen concentration of less than 1018 cm−3.
The invention also provides a new method of fabricating an electronic device. The method may comprise growing an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) by vapor phase epitaxy on a first side of a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) sliced from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown in supercritical ammonia. The method may comprise forming an Ohmic contact on a second side of the substrate and/or forming a Schottky contact, metal-insulator-semiconductor structure or p-type semiconductor on the active layer. The depletion region may be solely within the active layer, so that the depth of the depletion region is less than the thickness of the active layer for any applied voltage within an operation range of the device. Alternatively, the depletion region may extend through the active layer and into a transition layer. In this latter instance, the depth of the depletion region may be greater than the thickness of the active layer but less than the thickness of the active layer plus the thickness of a transition layer. It is, of course, not necessary that the depth of the depletion region is greater than the thickness of the active layer but less than the combined thickness of the active layer and a transition layer when a transition layer is provided in this method. The substrate may have a dislocation density of less than 105 cm−2. The substrate may have an electron concentration and/or an oxygen concentration higher than 1018 cm−3. The active layer may have an electron concentration and/or an oxygen concentration of less than 1018 cm−3.
These substrates, wafers, devices, and methods are provided by way of example and not by way of limitation.
Referring now to the drawings in which like reference numbers represent corresponding parts throughout:
1. Back Ohmic contact
2. Substrate
3. Active layer
4. Schottky contact
1. Back ohmic contact
2. Substrate
3. Active layer
4. Schottky contact
5. Transition layer
1. Back ohmic contact
2. Substrate
3. High-purity, low-carrier concentration active layer
4. Schottky contact
5. Transition layer
6. Current blocking layer
7. Regions of high electron concentration
8. Front ohmic contact
1. Back ohmic contact
2. Substrate
3. High-purity, low-carrier concentration active layer
4. Schottky contact
5. Transition layer
6. Current blocking layer
7. Regions of high electron concentration
8. Front ohmic contact
In the figure each number represents the following:
9. Substrate of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) sliced from a bulk crystal of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) grown in supercritical ammonia
10. A current blocking layer
10
a. A hole of the current blocking layer
11. A transition layer grown in the hole of the current blocking layer
12. A high-purity, low-carrier concentration active layer
13. A layer with high electron concentration
13
a. A window in the layer with high electron concentration
14. Back ohmic contact
15. Front ohmic contact
16. Schottky contact
17. An individual electronic device after die cut
In the figure each number represents the following:
9. Substrate of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) sliced from a bulk crystal of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) grown in supercritical ammonia
10. A current blocking layer
10
a. A hole of the current blocking layer
11. A transition layer grown in the hole of the current blocking layer
12. A high-purity, low-carrier concentration active layer
13. A layer with high electron concentration
13
a. A window in the layer with high electron concentration
14. Back ohmic contact
15. Front ohmic contact
16. Schottky contact
17. An individual electronic device after die cut
Overview
To attain high breakdown voltage as well as low on-resistance, the current invention utilizes a group III nitride substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) which is sliced from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown by the ammonothermal method. In the typical semiconductor device fabrication, many devices are fabricated on one wafer followed by separation of each device by dicing, cleavage or other method. In the case that one device is fabricated from one wafer, the substrate can be a whole wafer. In one instance, the dislocation density of the group III nitride substrate is less than 105 cm−2 and electron concentration of the substrate is higher than 1018 cm−3. In another instance the dislocation density of the substrate is less than 105 cm−2 and oxygen or silicon concentration of the substrate is higher than 1 atom per 1018 cm−3. In this case, oxygen or silicon can be the primary donor of electrons. By taking advantage of high electron concentration of Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) substrate by the ammonothermal growth, we can attain low on-resistance.
The group III nitride substrate may be formed by growing one or more bulk crystals of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) using the ammonothermal method. The crystals may be grown under acidic, basic, or neutral conditions in a high-pressure reactor as known in the art or as described in any of the generally-related patent applications listed above. An electron donor such as oxygen and/or silicon is incorporated into the bulk crystal during ammonothermal growth by introducing enough oxygen and/or silicon into the growth chamber of the high-pressure reactor as nutrient, mineralizer, seed, ammonia, and any other desired materials are placed in the reactor. Oxygen can be introduced into the chamber from air by evacuating the reactor of ambient air after loading the raw materials but leaving a sufficient amount of air in the reactor to provide the desired level of oxygen in the chamber. Oxygen can also or alternatively be introduced into the reactor chamber in the form of an oxide of e.g. an element used in the mineralizer. For instance, sodium and/or potassium may be used as the mineralizer, and often the sodium and/or potassium added to the reactor has an amount that has oxidized. The oxygen from the mineralizer may provide a sufficient amount of oxygen to provide the specified level of oxygen concentration in the bulk crystal. Silicon can be introduced by e.g. adding an amount of silane gas to the reactor that results in the specified concentration of silicon in the bulk crystal or using other methods known in the art.
The high-purity, low-carrier concentration active layer may be formed by vapor phase epitaxy on the first side of the substrate so that the impurity level and the electron concentration in the active layer is low. The growth conditions of the active layer can be optimized so that no dislocations are newly generated at the interface between the substrate and the active layer. The optimization may include adjusting growth temperature, temperature ramping profile, timing of introducing reaction gas or source, or other technique as known by a person of ordinary skill. In this way, the dislocation density of the Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) active layer can be at the same level of that of the substrate (i.e. less than 105 cm−2). The dislocation density of the active layer can therefore be lower than the dislocation density for an active layer on comparable horizontal devices formed on heteroepitaxial wafers (109 cm−2 level) (where all electrodes for an electrical device on a wafer are found on only one side or surface of the wafer and no electrodes for that device are on the opposite side of the wafer). In addition, vapor phase epitaxy can attain a lower impurity concentration than that of the ammonothermal substrate. Therefore, the electron concentration of the active layer is lower than 1016 cm−3. The high structural quality and high purity nature of the active layer enables faster electron mobility and higher breakdown voltage.
To attain sufficient breakdown voltage, the high-purity, low-carrier concentration active layer has a sufficient thickness, for example, larger than 5 microns, or typically 10 microns.
The active layer may have a much lower concentration of sodium or other mineralizer than the group III nitride substrate. The active layer may have a concentration e.g. less than one-tenth or one-hundredth of the sodium or other mineralizer present in the substrate. The substrate may have a concentration of mineralizer such as sodium of greater than about 1016 cm−3.
To maximize the structural quality and the purity of the active layer, a transition layer can be optionally grown on the substrate before growing the active layer. The lattice constant of a GaN or other Group III nitride substrate formed using ammonothermal growth may be slightly larger than the lattice constant of a corresponding GaN or Group III nitride substrate grown using a vapor phase method. This may be due to high concentration of impurities and/or electrons in the substrate formed by ammonothermal growth. Therefore, it can be helpful to grow a transition layer having a lattice constant matched to the substrate initially. The alloy composition of the Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) transition layer can be gradually changed to make the lattice constant of the transition layer at the surface of the transition layer that will contact the active layer suitable for the successive active layer. The composition can be changed by e.g. altering the flow rates of reactant gases during growth, so that the transition layer's crystalline structure is well-matched to the substrate on one surface of the transition layer and the active layer on an opposite surface of the transition layer. In this way, the structural quality of the active layer is maximized.
When the lattice constant or the lattice curvature of the ammonothermal substrate is too large, a Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) transition layer grown by vapor phase epitaxy sometimes cracks. However these cracks can be buried by further growing the material by changing growth temperature, temperature ramping profile, and/or timing of introducing reaction gas or source to increase growth and fill in the cracks based on observations during layer growth or from observations of transition layers formed during previous runs. The active layer can be grown after all cracking damages are healed.
The transition layer can also be used to prevent potential diffusion of impurity from the Group III nitride substrate into the active layer. In particular, sodium in the substrate can diffuse into the active layer during the fabrication process or device operation. An appropriate dopant such as silicon and magnesium in the transition layer may block such diffusion.
Instead of using a Group III nitride substrate having a transition layer, one can use a template-type wafer as disclosed in US 2006/0057749 A1, the contents of which are incorporated by reference in their entirety as if put forth in full below. The purpose of a template is to maintain the crystal quality (i.e. dislocation/defect density) of the wafer during epitaxial growth of the high-purity, low-carrier concentration active layer.
It is worth noting that the transition layer can be a portion of the active layer. If the active layer is grown in two or more steps by, e.g., changing growth temperature, pressure, and/or flow rate of reactants, the part of the active layer closer to the substrate will have a lattice constant that more closely matches the substrate's lattice constant so that part of the active layer acts as a transition layer.
The device has a depletion region in the active layer. A structure such as a Schottky contact, metal insulator semiconductor structure, or p-n junction depletes charge carriers from the depletion region in the active layer so that the device functions as an electronic device. The structure can be a Schottky contact, metal-insulator-semiconductor structure or p-n junction. In any case, formation of such structure requires that the surface of the semiconductor active layer has high quality. When a Schottky contact is made on the active layer and one ohmic contact is made on the backside of the substrate, the device can work as a Schottky diode. If an additional ohmic contact is made on the active layer with a current blocking region and a low-resistance contact region, the device can be a metal-semiconductor field effect transistor (MESFET). The Schottky contact of the MESFET can be replace with a metal-insulator-semiconductor structure. When p-type semiconductor is formed on the active layer, the device can be a p-n diode. With an additional n-type semiconductor on the p-type semiconductor, the device can be a bipolar transistor. One can use heterojunction for these n-p-n structure (hetero bipolar transistor: HBT). Since all of these devices have a vertical configuration, they are suitable for high-current operation.
Some example structures of the electronic devices in this invention are explained by using the drawings.
The Schottky contact can be replaced with p-type Ga1-x4-y4Alx4Iny4N (0≦x4≦1, 0≦y4≦1) having an ohmic contact on top of the p-type layer. In this case the device can function as a p-n diode. If the ohmic contact of this p-n diode is replaced with a n-type Ga1-x5-y5Alx5Iny5N (0≦x5≦1, 0≦y5≦1), the device can function as bipolar transistor. If the active layer, p-type layer and the n-type layer have different alloy compositions, the device can function as a hetero bipolar transistor (HBT). For example, the active layer can be undoped GaN, the p-type layer can be p-GaN, and the top n-type layer can be n-AlGaN with aluminum content of e.g. 10%. For forming additional Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) layers, MOCVD, HVPE, MBE or other vapor phase method can be used. Schottky and ohmic contacts can be formed with metal evaporation, sputtering or other typical metallization used in the semiconductor processing.
The Schottky contact can be replaced with metal-insulator-semiconductor structure. In this case, an appropriate insulator such as SiO2, Al2O3, MN may be used. The device can operate as MISFET.
The insulator layer thickness and properties such as composition and resistance can be adjusted. The current blocking layer can optionally be formed on the transition layer.
One example of the fabrication process of an electronic device in
Bulk crystals of GaN were grown with the basic ammonothermal method in a pressure reactor having internal volume of 127 cc using polycrystalline GaN (15 g) as a nutrient, supercritical ammonia (53% fill to the reactor volume) as a solvent, sodium (5 mol % to ammonia) as a mineralizer. The growth temperature was between 500 to 600° C. and the growth was extended to 181 days. Bulk crystal of GaN was grown on a c-plane GaN seed crystals. The size of the crystal was approximately 10 mm2. Then the crystal was sliced into substrates using a multiple wire saw. Nine substrates were sliced out of one bulk GaN crystal. These substrates were lapped with diamond slurry and polished using CMP. The defect density of one of these substrates was characterized with X-ray topography. The dislocation density was 4×104 cm−2. The oxygen concentration was 3.2×1019 cm−3. From the oxygen concentration, the electron concentration is estimated to be mid to high-1018 cm−3 range.
Using a pressure reactor having a similar internal volume, bulk GaN crystals can be grown in the similar conditions of polycrystalline GaN nutrient (1˜500 g), ammonia (30˜60% fill), and sodium (1˜10% to ammonia). The bulk GaN crystals grown is this way typically shows n-type conductivity with electron concentration higher than 1018 cm−3.
Using GaN substrates prepared by ammonothermal growth, GaN layers were grown by HVPE. The obtained epitaxial multi-layer wafer can be used to fabricate the electron devices as presented in Examples 3 and 4. In each run, one substrate of approximately 10 mm×10 mm in size was used. Inside the HVPE reactor, hydrogen chloride gas was passed over heated Ga, and the resultant gallium chloride then mixed with ammonia and subsequently contacted the heated substrate. The temperature of the Ga was in the range of 800 to 1000° C. and the temperature of the substrate was in the range of 900 to 1150° C. In this example, GaN having thickness of 11 microns, 24 microns, 56 microns, and 164 microns were grown on the Ga-polar surface of the ammonothermal c-plane GaN substrates. The growth rate was in the range of 50 to 400 microns per hour. The surface of the 11 micron-thick GaN film had cracks originating from the interface between the ammonothermal substrate and the HVPE film; however, the other three films did not have cracks in their surfaces. This confirmed that cracks originating from the interface between the ammonothermal substrate and the active layer formed by HVPE can be buried by growing a thicker layer.
For the 56 micron-thick film, a transition layer of GaN was grown for 4 minutes before growing the active layer for 5 minutes. The growth temperature for the transition layer was approximately 100 degree lower than that of the active layer. Also in this case, the top surface of the active layer was crack-free and showed high quality surface.
The carrier concentration of the active layers for 24 micron, 56 micron and 164 micron-thick film was less than 1016 cm−2, representing high-purity and low-carrier concentration feature.
Using other vapor phase method such as MOCVD and MBE for growing the transition layer and/or the active layer should have the same benefit of the crack reduction presented in this example.
Although a transition layer is optional, a device preferably has a separate transition layer with e.g. composition and/or impurity concentration varied from one face of the layer to the other in order to provide a surface matched to the active layer to maximize its crystallinity and purity.
Using the epitaxial multi-layer wafer having a GaN high-purity, low-carrier concentration active layer, a Schottky diode can be fabricated by forming a ohmic contact of aluminum on the back side of the wafer and Schottky contact of Ni on the surface of the active layer. First, the wafer with the active layer is cleaned in hydrofluoric acid to remove surface oxide. Then, approximately 1 micron of nickel is evaporated on the surface of the active layer. Patterning of photo resist is performed using a standard semiconductor process and nickel is etched with nitric acid. Then, the photo resist is removed with acetone. After forming the Schottky contact, approximately 1 micron of Ti/Al ohmic contact is evaporated on the back side of the wafer. Then each device is separated with wafer dicer.
This structure has a benefit of low on-resistance due to high electrical conductivity (higher than 1018 cm−3) of the substrate and high break down voltage due to high resistivity of the active layer. The high resistivity of the active layer is achieved by low carrier concentration less than 1016 cm−3. Combination of vapor phase growth with ammonothermal GaN substrate is beneficial to achieve both low on-resistance and high breakdown voltage. Also, optional transition layer by the vapor phase growth can achieve higher performance by ensuring high crystallinity and purity of the active layer.
By growing an additional layer of p-type GaN by a vapor phase epitaxy, followed by forming an ohmic contact of Ni/Au, a p-n diode can be fabricated using the epitaxial multi-layer wafer having a GaN high-purity, low-carrier concentration active layer. The thickness of the p-type GaN can be more than 0.1 micron. The thickness of Ni/Au is approximately 1 micron. The back ohmic contact is formed as discussed in Example 3. The device can operate as a p-n diode.
The process in Example 3 can be incorporated in a process to fabricate MESFET. In addition to the two electrodes (one ohmic back drain contact and one Schottky gate contact), MESFET has one more ohmic source contact next to the Schottky gate contact. Since the active layer has low concentration of electrons, an appropriate highly doped contact region is used to ensure low contact resistance of the ohmic source contact. To attain this structure, additional layer of GaN with high-electron concentration is grown on the active layer followed by reactive ion etching to make a window for the Schottky gate contact. 1 micron-thick Ti/Al ohmic contacts are used for the source and drain contacts.
With an appropriate device design such as the distance of the current blocking layer to the Schottky gate contact, the MESFET can operate normally off mode. This is achieved by reducing the electron concentration of the active layer as well as reducing the distance of the current blocking layer to the Schottky gate contact so that the depletion region created by the Schottky barrier closes the current channel between the gate and the current blocking layer. By changing the applied voltage to the gate, we can control the channel width, thus control the amount of current through the source contact and the drain contact. The active layer and/or transition layer alone or together preferably has a thickness sufficiently large that the depletion region does not reach the ammonothermal substrate or damaged (i.e. cracked region) at the interface between the substrate and the transition/active layer under appropriate bias condition for the gate contact.
The Schottky gate contact can be replaced with a metal-insulator-semiconductor structure. In such case, insulator layer of SiO2, Al2O3 or AN is deposited on the active layer with a sputtering. Then Ti/Al contact is evaporated on the insulator layer with appropriate patterning. The device can operate as MISFET.
By additionally growing n-GaN or n-AlGaN on the p-n diode in Example 4, the device can operate as bipolar transistor or hetero bipolar transistor (HBT). In this case, the p-type Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1) layer must be thinner than other layers. The growth of these layers is conducted with MOCVD, MBE, HVPE or other vapor phase method. Ni/Au can be used for p-type contact and Ti/Al can be used for n-type contact.
Although the preferred embodiment describes GaN substrates, the substrate can be group III nitride alloys of various composition, such as AN, AlGaN, InN, InGaN, or GaAlInN The scope of the invention is maintained with these substrates.
Although the preferred embodiment describes Ga-face c-plane GaN, other orientations such as N-face c-plane, a-face, m-face, and various semipolar surface can also be used. In addition, the surface can be slightly miscut (off-sliced) from these orientations. The scope of the invention is maintained with these orientations and miscut. In particular, usage of N-face c-plane GaN, nonpolar a-face and m-face, semipolar planes will modulate the energy band structure of the electronic devices, thus can control the turn-on voltage of the MESFET or MISFET.
Although the preferred embodiment utilizes HVPE, other methods such as MOCVD, MBE, reactive sputtering, ion-beam deposition can be used to grow the active layer and/or the transition layer in this invention.
Although the preferred embodiment uses Ni for Schottky contact and Ti/Al for ohmic contact, other metals can also be used. Examples for Schottky contact is Pt, Pd, Co, Au, Mg, and examples for ohmic contacts is Cr, In, Ag.
Further examples of the invention include the subject matter laid out in the following paragraphs, which are provided by way of example and which do not, of course, limit the scope of the invention:
1. An epitaxial multi-layer wafer for fabricating electronic devices comprising (i) a group III nitride substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) having a first side and a second side opposite to the first side and (ii) an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on the first side of the group III nitride substrate, wherein:
(a) a dislocation density of the group III nitride substrate is less than 105 cm−2;
(b) the group III nitride substrate has an electron concentration higher than 1018 cm−3;
(c) the group III nitride substrate is fabricated from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown in supercritical ammonia;
(d) the active layer is an epitaxially deposited layer which has an electron concentration lower than 1018 cm−3;
(e) the active layer has a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating the electronic device with a first electrode on the first side of the wafer and a second electrode on the second side of the wafer is outside of the substrate.
2. An epitaxial multi-layer wafer according to paragraph 1 wherein the active layer has an electron concentration lower than 1016 cm−3.
3. An epitaxial multi-layer wafer for fabricating electronic devices comprising (i) a group III nitride substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) having a first side and a second side opposite to the first side and (ii) an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on the first side of the group III nitride substrate, wherein:
(a) a dislocation density of the group III nitride substrate is less than 105 cm−2;
(b) the group III nitride substrate has an electron concentration higher than 1018 cm−3;
(c) the group III nitride substrate is fabricated from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown in supercritical ammonia;
(d) the active layer is an epitaxially deposited layer which has an oxygen concentration lower than 1018 cm−3;
(e) the active layer has a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating the electronic device with a first electrode on the first side of the wafer and a second electrode on the second side of the wafer is outside of the substrate.
4. An epitaxial multi-layer wafer according to paragraph 3 wherein the active layer has an oxygen concentration lower than 1016 cm−3.
5. An epitaxial multi-layer wafer according to any of paragraphs 1-4 wherein the thickness of the active layer is more than 5 microns.
6. An epitaxial multi-layer wafer according to any of paragraphs 1-5 and further comprising a transition layer of Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) between the substrate and the active layer, wherein a first side of the transition layer has a crystal lattice matched to a crystal lattice of the first side of the substrate, and wherein a second side of the transition layer has a crystal lattice matched to a crystal lattice of a first side of the active layer, the lattice constant of the transition layer varies along the growth direction so that the lattice matching is realized at the interface between the substrate and the transition layer and at the interface between the transition layer and the active layer.
7. An epitaxial multi-layer wafer according to paragraph 6 wherein the transition layer is grown by a vapor phase epitaxy.
8. An epitaxial multi-layer wafer according to paragraph 6 or paragraph 7 wherein the transition layer is thick enough to bury cracks created at the interface between the substrate and the transition layer.
9. An epitaxial multi-layer wafer according to any of paragraphs 6-8 wherein the depletion zone extends into the transition layer.
10. An epitaxial multi-layer wafer according to any of paragraphs 6-8 wherein the active layer is thicker than the depletion zone.
11. An epitaxial multi-layer wafer according to any of paragraphs 6-10 wherein the transition layer is doped with an impurity which prevents diffusion of impurities contained in the substrate.
12. An epitaxial multi-layer wafer according to any of paragraphs 1-11 and further comprising a current blocking layer between the group III nitride substrate and the active layer.
13. An epitaxial multi-layer wafer according to any of paragraphs 1-12 wherein the active layer has a dislocation density less than 105 cm−2.
14. An epitaxial multi-layer wafer according to any of paragraphs 1-13 wherein the substrate has a sodium concentration of greater than 1016 cm−3 and the active layer contains at least 100 times less sodium than the substrate.
15. An epitaxial multi-layer wafer according to any of paragraphs 1-14 wherein the substrate is a c plane with miscut more than 0.1 degree and less than 5 degree.
16. An electronic device comprising a multi-layer wafer according to any of paragraphs 1-15 and said electrodes which form the depletion region outside of the group III nitride wafer over an operating range of the electronic device.
17. A method of making a multi-layer wafer comprising epitaxially depositing from vapor phase, upon a first side of a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) formed by an ammonothermal method and having a second side opposite to the first side, an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1), wherein the active layer has a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating an electronic device with a first electrode on the first side of the wafer and a second electrode on the second side of the wafer is outside of the substrate, wherein the substrate has an oxygen concentration of greater than 1018 cm−3 and the vapor phase has a sufficiently low concentration of oxygen to provide an oxygen concentration in the active layer of less than 1018 cm−3.
18. A method according to paragraph 17 wherein the vapor phase has a sufficiently low concentration of oxygen to provide an oxygen concentration in the active layer of less than 1016 cm−3.
19. A method of making a multi-layer wafer comprising epitaxially depositing from vapor phase, upon a first side of a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) formed by an ammonothermal method and having a second side opposite to the first side, an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1), wherein the active layer has a thickness sufficiently large that a depletion region which is formed in the active layer after fabricating an electronic device with a first electrode on the first side of the wafer and a second electrode on the second side of the wafer is outside of the substrate, wherein the substrate has an oxygen concentration of greater than 1018 cm−3 and the active layer has a sufficiently low concentration of an electron donor to provide an electron concentration in the active layer of less than 1018 cm−3.
20. A method according to paragraph 19 wherein the active layer has a sufficiently low concentration of electron donor to provide an electron concentration in the active layer of less than 1016 cm−3.
21. A method according to any of paragraphs 17-20 wherein the active layer is deposited to a thickness of at least about 5 microns.
22. A method according to any of paragraphs 17-21 and further comprising epitaxially depositing a transition layer of Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) while varying a concentration of a reactant and/or deposition conditions so that a first face of the transition layer matches a crystal lattice of the first side of the substrate during the depositing and a second, opposite face of the transition layer matches a crystal lattice of a first side of the active layer upon completion of depositing the transition layer.
23. A method according to paragraph 22 wherein the transition layer cracks during said depositing, and wherein the method further comprises depositing an additional amount of the transition layer to bury the transition layer cracks so that the second surface of the transition layer has no cracks.
24. A method according to paragraph 22 or paragraph 23 wherein the active layer is deposited to a thickness such that the depletion zone extends into a portion of the transition layer.
25. A method according to paragraph 24 wherein the depletion zone ends before reaching cracks in the transition layer.
26. A method according to any of paragraphs 22-25 wherein the transition layer is doped with an impurity which prevents diffusion of impurities contained in the substrate.
27. A method according to any of paragraphs 17-26 and further comprising depositing a current blocking layer between the group III nitride substrate and the active layer.
28. A method according to any of paragraphs 17-27 wherein the active layer has a sufficiently low concentration of sodium that the active layer contains at least 100 times less sodium than the substrate, and the substrate contains sodium at a concentration greater than 1016 cm−3.
29. A method according to any of paragraphs 17-28 wherein said first side of the substrate is miscut more than 0.1 degree and less than 5 degree to a c plane.
30. A method according to any of paragraphs 17-29 and further comprising providing said electrodes.
31. An electronic device comprising a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1), an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on a first side of the substrate, a back ohmic contact on a second side opposite to the first side of the substrate, and a depletion region having a depth in the active layer, wherein;
32. An electronic device according to paragraph 31 wherein the electron concentration of the active layer is less than 1016 cm−3.
33. An electronic device comprising a substrate of Ga1-x1-y1Alx1Iny1N (0≦x≦1, 0≦y1≦1), an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on a first side of the substrate, a back ohmic contact on a second side opposite to the first side of the substrate, a depletion region in the active layer and having a depth, wherein;
34. An electronic device according to paragraph 33 wherein the oxygen concentration of the active layer is less than 1016 cm−3.
35. An electronic device according to any of paragraphs 31-34 further comprising a transition layer of Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) between the substrate and the active layer, wherein the transition layer is grown by vapor phase epitaxy.
36. An electronic device comprising a substrate of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1), an active layer of Ga1-x2-y2Alx2Iny2N (0≦x2≦1, 0≦y2≦1) on a first side of the substrate, a back ohmic contact on a second side opposite to the first side of the substrate, a depletion region in the active layer and having a depth, and a transition layer of Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1), wherein;
37. An electronic device according to paragraph 36 wherein the oxygen concentration of the active layer is less than 1016 cm−3.
38. An electronic device according to paragraph 36 or paragraph 37 wherein the electron concentration of the active layer is less than 1016 cm−3.
39. An electronic device according to any of paragraphs 36-38 wherein the active layer is thicker than the depth of the depletion region.
40. An electronic device according to any of paragraphs 36-38 wherein the depletion region extends into the transition layer.
41. An electronic device according to any of paragraphs 35-40 wherein the transition layer has a impurity concentration or alloy composition that varies along a growth direction so that lattice matching is realized at an interface between the substrate and the transition layer and at an interface between the transition layer and the active layer.
42. An electronic device according to paragraph 35-41 wherein the transition layer is sufficiently thick to bury cracks created at an interface between the substrate and the transition layer.
43. An electronic device according to paragraph 35-42 wherein the transition layer is doped with an impurity which prevents diffusion of impurities contained in the substrate.
44. An electronic device according to any of paragraphs 31-43 wherein the substrate is made of a wafer fabricated from a bulk crystal of Ga1-x1-y1Alx1Iny1N (0≦x1≦1, 0≦y1≦1) grown in supercritical ammonia.
45. An electronic device according to any of paragraphs 31-44 wherein the substrate contains sodium at a concentration of greater than about 1016 cm−3 and the active layer has a sodium concentration at least 100 times less than the substrate.
46. An electronic device according to any of paragraphs 31-45 wherein the active layer is grown by vapor phase epitaxy.
47. An electronic device according to any of paragraphs 31-46 wherein the wafer is a c plane wafer with miscut more than 0.1 degree and less than 5 degree.
48. An electronic device according to any of paragraphs 31-47 wherein the depletion region has an adjacent Schottky contact or an adjacent p-n junction.
49. An electronic device according to any of paragraphs 31-47 wherein the depletion region has a Schottky contact or a metal-insulator-semiconductor structure and further comprising:
and wherein the front ohmic contact and the Schottky contact or the metal-insulator-semiconductor structure are positioned to regulate an electric current through the front ohmic contact to the back ohmic contact with a voltage applied across the front ohmic contact and the Schottky contact.
50. An electronic device according to paragraph 49 wherein the current blocking layer comprises silicon dioxide.
51. An electronic device according to paragraph 49 wherein the current blocking layer comprises a gas.
52. An electronic device according to paragraph 51 wherein the gas is air.
53. An electronic device according to paragraph 49 wherein the current blocking layer comprises p-type or semi-insulating Ga1-x-yAlxInyN (0≦x≦1, 0≦y≦1).
54. An electronic device according to any of paragraphs 49-53 further comprising a region of high electron concentration underneath the front ohmic contact.
55. An electronic device according to any of paragraphs 31-47 wherein the depletion region has a p-n junction and further comprising an additional n-type semiconductor on the p-n junction to form a bipolar transistor.
56. A method of fabricating an electronic device comprising;
57. A method according to paragraph 56 wherein electron concentration of the active layer is less than 1016 cm−3.
58. A method of fabricating an electronic device comprising;
59. A method according to paragraph 58 wherein the oxygen concentration of the active layer is less than 1016 cm−3.
60. A method of fabricating an electronic device according to any of paragraphs 56-59 wherein step (a) includes growth of a transition layer of Ga1-x3-y3Alx3Iny3N (0≦x3≦1, 0≦y3≦1) between the substrate and the active layer.
61. A method of fabricating an electronic device according to any of paragraphs 56-60 further comprising the following steps before growing the active layer;
62. A method of fabricating an electronic device according to paragraph 61 wherein the dielectric layer comprises silicon dioxide.
63. A method of fabricating an electronic device according to paragraph 61 or paragraph 62 wherein the transition layer and/or the active layer is formed using vapor phase epitaxy that deposits the layer's material selectively in the hole of the dielectric layer and then laterally.
64. A method of fabricating an electronic device according to paragraph 63 wherein the material deposited laterally extends to an adjacent device on the substrate so that the active layer forms a continuous film.
65. A method of fabricating an electronic device according to paragraph 63 wherein the material deposited laterally does not extend to an adjacent device on the substrate so that the active layer forms a discontinuous film.
66. The invention of any paragraph above wherein x1=x2=x3=0 and y1=y2=y3=0.
The foregoing description of the preferred embodiment of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.
The following references are incorporated by reference herein:
Each of the references above is incorporated by reference in its entirety as if put forth in full herein, and particularly with respect to description of methods of making using ammonothermal methods and using these gallium nitride substrates.
This application is a Continuation of U.S. patent application Ser. No. 14/329,730, filed Jul. 11, 2014, and entitled ELECTRONIC DEVICE USING GROUP III NITRIDE SEMICONDUCTOR AND ITS FABRICATION METHOD AND AN EPITAXIAL MULTI-LAYER WAFER FOR MAKING IT, inventor Tadao Hashimoto, which claims priority to U.S. App. 61/845,043, filed Jul. 11, 2013 and entitled ELECTRONIC DEVICE USING GROUP III NITRIDE SEMICONDUCTOR AND ITS FABRICATION METHOD, inventor Tadao Hashimoto, which the entire contents of each of the foregoing applications is incorporated by reference herein as if put forth in full below. This application is also related to the following patent applications: PCT Utility Patent Application Serial No. US2005/024239, filed on Jul. 8, 2005, by Kenji Fujito, Tadao Hashimoto and Shuji Nakamura, entitled “METHOD FOR GROWING GROUP III—NITRIDE CRYSTALS IN SUPERCRITICAL AMMONIA USING AN AUTOCLAVE,”; U.S. Utility patent application Ser. No. 11/784,339, filed on Apr. 6, 2007, by Tadao Hashimoto, Makoto Saito, and Shuji Nakamura, entitled “METHOD FOR GROWING LARGE SURFACE AREA GALLIUM NITRIDE CRYSTALS IN SUPERCRITICAL AMMONIA AND LARGE SURFACE AREA GALLIUM NITRIDE CRYSTALS,”, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Patent Application Ser. No. 60/790,310, filed on Apr. 7, 2006, by Tadao Hashimoto, Makoto Saito, and Shuji Nakamura, entitled “A METHOD FOR GROWING LARGE SURFACE AREA GALLIUM NITRIDE CRYSTALS IN SUPERCRITICAL AMMONIA AND LARGE SURFACE AREA GALLIUM NITRIDE CRYSTALS,”; U.S. Utility Patent Application Ser. No. 60/973,602, filed on Sep. 19, 2007, by Tadao Hashimoto and Shuji Nakamura, entitled “GALLIUM NITRIDE BULK CRYSTALS AND THEIR GROWTH METHOD,”; U.S. Utility patent application Ser. No. 11/977,661, filed on Oct. 25, 2007, by Tadao Hashimoto, entitled “METHOD FOR GROWING GROUP III—NITRIDE CRYSTALS IN A MIXTURE OF SUPERCRITICAL AMMONIA AND NITROGEN, AND GROUP III—NITRIDE CRYSTALS GROWN THEREBY,”; U.S. Utility patent application Ser. No. 12/392,960, filed on Feb. 25, 2009, by Tadao Hashimoto, Edward Letts, Masanori Ikari, entitled “METHOD FOR PRODUCING GROUP III—NITRIDE WAFERS AND GROUP III—NITRIDE WAFERS,”; U.S. Utility patent application Ser. No. 12/455,760, filed on Jun. 4, 2009, by Edward Letts, Tadao Hashimoto, Masanori Ikari, entitled “METHODS FOR PRODUCING IMPROVED CRTSTALLINITY GROUP III—NITRIDE CRYSTALS FROM INITIAL GROUP III—NITRIDE SEED BY AMMONOTHERMAL GROWTH,”; U.S. Utility patent application Ser. No. 12/455,683, filed on Jun. 4, 2009, by Tadao Hashimoto, Edward Letts, Masanori Ikari, entitled “HIGH-PRESSURE VESSEL FOR GROWING GROUP III NITRIDE CRYSTALS AND METHOD OF GROWING GROUP III NITRIDE CRYSTALS USING HIGH-PRESSURE VESSEL AND GROUP III NITRIDE CRYSTAL,”; U.S. Utility patent application Ser. No. 12/455,181, filed on Jun. 12, 2009, by Tadao Hashimoto, Masanori Ikari, Edward Letts, entitled “METHOD FOR TESTING III—NITRIDE WAFERS AND III—NITRIDE WAFERS WITH TEST DATA,”; U.S. Utility patent application Ser. No. 12/580,849, filed on Oct. 16, 2009, by Tadao Hashimoto, Masanori Ikari, Edward Letts, entitled “REACTOR DESIGN FOR GROWING GROUP III NITRIDE CRYSTALS AND METHOD OF GROWING GROUP III NITRIDE CRYSTALS,”; U.S. Utility patent application Ser. No. 13/781,509, filed on Feb. 28, 2013, by Tadao Hashimoto, entitled “COMPOSITE SUBSTRATE OF GALLIUM NITRIDE AND METAL OXIDE,”; U.S. Utility patent application Ser. No. 13/781,543, filed on Feb. 28, 2013, by Tadao Hashimoto, Edward Letts, Sierra Hoff entitled “A BISMUTH-DOPED SEMI-INSULATING GROUP III NITRIDE WAFER,”; U.S. Utility patent application Ser. No. 13/833,443, filed on Mar. 15, 2013, by Tadao Hashimoto, Edward Letts, Sierra Hoff entitled “METHOD OF GROWING GROUP III NITRIDE CRYSTALS,”; U.S. Utility patent application Ser. No. 13/834,015, filed on Mar. 15, 2013, by Tadao Hashimoto, Edward Letts, Sierra Hoff entitled “METHOD OF GROWING GROUP III NITRIDE CRYSTALS,”; U.S. Utility patent application Ser. No. 13/834,871, filed on Mar. 15, 2013, by Tadao Hashimoto, Edward Letts, Sierra Hoff entitled “GROUP III NITRIDE WAFER AND ITS PRODUCTION METHOD,”; U.S. Utility patent application Ser. No. 13/835,636, filed on Mar. 15, 2013, by Tadao Hashimoto, Edward Letts, Sierra Hoff entitled “GROUP III NITRIDE WAFER AND ITS PRODUCTION METHOD,”; U.S. Utility patent application Ser. No. 13/798,530, filed on Mar. 13, 2013, by Tadao Hashimoto, entitled “GROUP III NITRIDE WAFERS AND FABRICATION METHOD AND TESTING METHOD,”; which applications are incorporated by reference herein in their entirety as if put forth in full below.
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Child | 14460097 | US |