Embodiments described herein relate generally to a semiconductor device and a method for driving the same.
In recent years, a MOSFET (Metal Oxide Semiconductor Field-Effect Transistor), a super junction-type MOSFET, an IGBT (Insulated Gate Bipolar Transistor), an IEGT (Injection Enhanced Gate Transistor), etc., are used as semiconductor devices for power control. Compared to a unipolar MOSFET, a larger current can be controlled in IGBTs and IEGTs because IGBTs and IEGTs are bipolar semiconductor devices that use both electrons and holes as carriers. However, even in such a semiconductor device for power control, it is desirable to control even larger currents.
and
A semiconductor device according to an embodiment includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type provided on the first semiconductor layer, a third semiconductor layer of the first conductivity type provided on the second semiconductor layer, a fourth semiconductor layer of the second conductivity type provided on the second semiconductor layer, a first electrode connected to the second semiconductor layer and the fourth semiconductor layer, a second electrode facing the second semiconductor layer with an insulating film interposed, a fifth semiconductor layer of the second conductivity type provided under the first semiconductor layer, a sixth semiconductor layer of the first conductivity type provided under the fifth semiconductor layer, a seventh semiconductor layer of the second conductivity type provided under the fifth semiconductor layer, a third electrode connected to the fifth semiconductor layer and the seventh semiconductor layer, and a fourth electrode facing the fifth semiconductor layer with an insulating film interposed. A carrier concentration of the third semiconductor layer is higher than a carrier concentration of the first semiconductor layer. A carrier concentration of the fourth semiconductor layer is higher than a carrier concentration of the second semiconductor layer. A carrier concentration of the sixth semiconductor layer is higher than the carrier concentration of the first semiconductor layer. A carrier concentration of the seventh semiconductor layer is higher than a carrier concentration of the fifth semiconductor layer.
First, a first embodiment will be described.
As shown in
As shown in
An XYZ orthogonal coordinate system is employed in the specification for convenience of description. Two mutually-orthogonal directions parallel to the upper surface of the n−-type high resistance layer 20 are taken as an “X-direction” and a “Y-direction;” and a direction perpendicular to the upper surface is taken as a “Z-direction.” The “Z-direction” is a direction that connects the collector electrode and the emitter electrode described below. Although the emitter electrode side is called “up” and the collector electrode side is called “down” in the specification for convenience of description, these notations are independent of the direction of gravity.
Emitter-side trench gate electrodes 31a and 31b that extend in the Y-direction are provided on the upper surface of the n−-type high resistance layer 20. The emitter-side trench gate electrodes 31a (hereinbelow, also called simply the “electrode 31a;” this is similar for the other electrodes as well) and 31b are arranged alternately and separated from each other along the X-direction. For example, the electrodes 31a and 31b are formed of polysilicon. The length in the Z-direction of the electrode 31a is longer than the length in the Z-direction of the electrode 31b. In the Z-direction, the lower end of the electrode 31a and the lower end of the electrode 31b are at substantially the same position. On the other hand, the upper end of the electrode 31a is higher than the upper end of the electrode 31b. An insulating film 32a is provided around the electrode 31a. An insulating film 32b is provided around the electrode 31b.
An n-type base layer 33 that extends in the Y-direction is provided between the electrode 31a and the electrode 31b. The lower surface of the n-type base layer 33 contacts the upper surface of the n−-type high resistance layer 20. The side surface of the n-type base layer 33 facing the X-direction is covered with the insulating film 32a and the insulating film 32b. A p-type base layer 34 that extends in the Y-direction is provided on the n-type base layer 33. The lower surface of the p-type base layer 34 contacts the upper surface of the n-type base layer 33. One side surface of the p-type base layer 34 facing the X-direction is covered with the insulating film 32a; and the lower portion of the other side surface is covered with the insulating film 32b. An n++-type contact layer 35 and a p++-type contact layer 36 are provided on the p-type base layer 34. The n++-type contact layer 35 and the p++-type contact layer 36 are arranged alternately along the Y-direction. The lower surface of the n++-type contact layer 35 and the lower surface of the p++-type contact layer 36 contact the upper surface of the p-type base layer 34; and one side surface of the n++-type contact layer 35 facing the X-direction and one side surface of the p++-type contact layer 36 facing the X-direction are covered with the insulating film 32a.
Thereby, the electrode 31a faces, with the insulating film 32a interposed, the n−-type high resistance layer 20, the n-type base layer 33, the p-type base layer 34, the n++-type contact layer 35, and the p++-type contact layer 36. The electrode 31b faces, with the insulating film 32b interposed, the n−-type high resistance layer 20, the n-type base layer 33, and the lower portion of the p-type base layer 34.
An emitter electrode 39 that is made of, for example, a metal is provided above the emitter-side trench gate electrodes 31a and 31b, the insulating films 32a and 32b, the n-type base layer 33, the p-type base layer 34, the n++-type contact layer 35, and the p++-type contact layer 36 to cover these components. The emitter electrode 39 contacts the upper surface of the insulating film 32a, the upper surface of the insulating film 32b, the upper portion of one side surface facing the X-direction of the p-type base layer 34, the upper surface and one side surface facing the X-direction of the n++-type contact layer 35, and the upper surface and one side surface facing the X-direction of the p++-type contact layer 36.
The configuration of the collector side is a configuration in which the configuration of the emitter side is vertically inverted. In other words, collector-side trench gate electrodes 41a and 41b that extend in the Y-direction are provided on the lower surface of the n−-type high resistance layer 20. The collector-side trench gate electrodes 41a and 41b are arranged alternately and separated from each other along the X-direction. For example, the electrodes 41a and 41b are formed of polysilicon. The length in the Z-direction of the electrode 41a is longer than the length in the Z-direction of the electrode 41b. In the Z-direction, the upper end of the electrode 41a and the upper end of the electrode 41b are at substantially the same position. On the other hand, the lower end of the electrode 41a is lower than the lower end of the electrode 41b. An insulating film 42a is provided around the electrode 41a. An insulating film 42b is provided around the electrode 41b.
An n-type base layer 43 that extends in the Y-direction is provided between the electrode 41a and the electrode 41b. The upper surface of the n-type base layer 43 contacts the lower surface of the n−-type high resistance layer 20. The side surfaces of the n-type base layer 43 facing the X-direction are covered with the insulating film 42a and the insulating film 42b. A p-type base layer 44 that extends in the Y-direction is provided under the n-type base layer 43. The upper surface of the p-type base layer 44 contacts the lower surface of the n-type base layer 43. One side surface of the p-type base layer 44 facing the X-direction is covered with the insulating film 42a; and the upper portion of the other side surface is covered with the insulating film 42b. An n++-type contact layer 45 and a p++-type contact layer 46 are provided under the p-type base layer 44. The n++-type contact layer 45 and the p++-type contact layer 46 are arranged alternately along the Y-direction. The upper surface of the n++-type contact layer 45 and the upper surface of the p++-type contact layer 46 contact the lower surface of the p-type base layer 44; and one side surface of the n++-type contact layer 45 facing the X-direction and one side surface of the p++-type contact layer 46 facing the X-direction are covered with the insulating film 42a.
A collector electrode 49 that is made of, for example, a metal is provided below the collector-side trench gate electrodes 41a and 41b, the insulating films 42a and 42b, the n-type base layer 43, the p-type base layer 44, the n++-type contact layer 45, and the p++-type contact layer 46 to cover these components. The collector electrode 49 contacts the lower surface of the insulating film 42a, the lower surface of the insulating film 42b, the lower portion of one side surface facing the X-direction of the p-type base layer 44, the lower surface and one side surface facing the X-direction of the n++-type contact layer 45, and the lower surface and one side surface facing the X-direction of the p++-type contact layer 46.
Thereby, the electrode 41a faces, with the insulating film 42a interposed, the n−-type high resistance layer 20, the n-type base layer 43, the p-type base layer 44, the n++-type contact layer 45, and the p++-type contact layer 46. The electrode 41b faces, with the insulating film 42b interposed, the n−-type high resistance layer 20, the n-type base layer 43, and the upper portion of the p-type base layer 44.
The n−-type high resistance layer 20, the n-type base layer 33, the p-type base layer 34, the n++-type contact layer 35, the p++-type contact layer 36, the n-type base layer 43, the p-type base layer 44, the n++-type contact layer 45, and the p++-type contact layer 46 are generally called a semiconductor portion 50. For example, the semiconductor portion 50 is formed as one body of monocrystalline silicon. For example, the insulating films 32a, 32b, 42a, and 42b are formed of silicon oxide. In
To further promote the injection of the electrons (the n-type carrier) of the emitter side by the electron IE effect, it is effective to design a width WE1 to be narrow and favorable to set the width WE1 to be, for example, 1 μm or less, where the width of the emitter-side trench gate electrode 31a in the X-direction is WE3, the width of the emitter-side trench gate electrode 31b in the X-direction is WE2, and the distance in the X-direction between the electrode 31a and the electrode 31b, i.e., the width of the n-type base layer 33, the p-type base layer 34, the n++-type contact layer 35, and the p++-type contact layer 36 on the emitter side is WE1. It is possible to further increase the electron IE effect by designing the width WE2 and the width WE3 to be wider than the width WE1.
For example, it is favorable when
WE2>2×WE1, and
WE3>2×WE1;
and more favorable when
WE2>10×WE1, and
WE3>10×WE1.
The width WE2 and the width WE3 may be configured by single trenches having wide widths (referring to
This is similar for the collector side as well. To further promote the injection of the holes (the p-type carrier) of the collector side by the hole IE effect, it is effective to design a width WC1 to be narrow and favorable to set the width WC1 to be, for example, 1 μm or less, where the width of the collector-side trench gate electrode 41a is WC3, the width of the collector-side trench gate electrode 41b is WC2, and the distance between the electrode 41a and the electrode 41b, i.e., the width of the n-type base layer 43, the p-type base layer 44, the n++-type contact layer 45, and the p++-type contact layer 46 on the collector side, is WC1. It is possible to further increase the hole IE effect by designing the width WC2 and the width WC3 to be wider than the width WC1.
For example, it is favorable when
WC2>2×WC1, and
WC3>2×WC1;
and more favorable when
WC2>10×WC1, and
WC3>10×WC1.
The width WC2 and the width WC3 may be configured by single trenches having wide widths (referring to
Operations of the semiconductor device according to the embodiment, i.e., a method for driving the semiconductor device according to the embodiment, will now be described.
First, the basic driving method will be described.
Compared to
As shown in
Then, as shown in
When the potentials of the emitter-side trench gate electrodes 31a and 31b (hereinbelow, also called the “emitter-side gate potential”) are set to negative potentials in this state, an inversion layer is not formed in the p-type base layer 34; the electron current is blocked because a reverse bias is applied to the p-n interface between the p-type base layer 34 and the n-type base layer 33; and the semiconductor device 1 is switched to the OFF state.
On the other hand, when the emitter-side gate potential is set to a positive potential, an inversion layer is formed in the p-type base layer 34; and electrons are injected through the path of the n++-type contact layer 35, the inversion layer of the p-type base layer 34, and the n-type base layer 33. Thereby, an electron current flows inside the semiconductor portion 50; and the semiconductor device 1 is switched to the ON state.
As shown in
When the emitter-side gate potential is set to a negative potential in this state, an inversion layer is not formed in the p-type base layer 34; and the semiconductor device 1 is switched to the OFF state. On the other hand, when the emitter-side gate potential is set to a positive potential, an inversion layer is formed in the p-type base layer 34; and electrons are injected. Thereby, the semiconductor device 1 is switched to the ON state as a bipolar IEGT having electrons and holes as carriers.
Thus, the semiconductor device 1 according to the embodiment can be switched between the MOSFET mode and the IEGT mode by selecting the carrier injected into the semiconductor portion 50 by controlling the collector-side gate potential. Modes that are intermediate between the MOSFET mode and the IEGT mode also are possible. A diode mode also is possible. The ON state and the OFF state can be switched by controlling the emitter-side gate potential.
In the semiconductor device 1 shown in
Generally, in a unipolar device such as a MOSFET or the like, there is no built-in voltage and a current flows from a low applied voltage (substantially 0 V); but the current-carrying capacity of a unipolar device is nowhere near that of a bipolar device such as an IGBT, an IEGT, a thyristor, a GCT (Gate Commutated Turn-Off thyristor), etc., in the region where the applied voltage is the built-in voltage or higher. While the current-carrying capacity of the bipolar device is superior in the region where the applied voltage is the built-in voltage or higher, a current does not flow when the applied voltage is less than the built-in voltage. The built-in voltage of silicon (Si) is about 0.5 V; and the built-in voltage of silicon carbide (SiC) is about 3.5 V.
As shown in
In the semiconductor device 1 as shown in
As a result, the carrier can be stored at a high density inside the n−-type high resistance layer 20 of the semiconductor portion 50. A maximum value Cmax of the carrier concentration of the n−-type high resistance layer 20 is, for example, 1×1013 to 1×1019 cm−3. Thereby, the ON resistance can be reduced; and the collector current can be increased even further.
A practical driving method will now be described.
According to the embodiment, various operations are possible by adjusting the timing of the switching of the operation mode and the switching ON/OFF.
The position shown at the vertical axis for
In this operation as shown in
In this operation as shown in
Although an example of an operation is shown in
In the embodiment, as a modification of the operation shown in
For example, when a depletion layer or a strong space charge region undesirably spreads from the opposite side of the side used as the major junction when in the OFF state, a loss that is larger than that of normal operation occurs; but in the embodiment, such abnormal operations can be avoided effectively by appropriate gate control.
Similarly, by controlling each of the gate applied voltages and the timing of the gate applied voltages, it is possible to prevent abnormal operations causing element breakdown and/or heat generation and the undesirable behavior of the carriers in the element interior in the operation of the semiconductor device 1.
The potential of the emitter-side trench gate electrode 31a and the potential of the electrode 31b may be controlled independently from each other. For example, the potential of one of the electrode 31a or 31b may be set to be the same as the potential of the emitter electrode 39 or the potential of the collector electrode 49. Or, the potential of the collector-side trench gate electrode 41a and the potential of the electrode 41b may be controlled independently from each other. For example, the potential of one of the electrode 41a or 41b may be set to be the same as the potential of the emitter electrode 39 or the potential of the collector electrode 49. By such settings, the electrostatic capacitance of the trench gate electrode can be reduced; and high-speed and stable operations of the semiconductor device 1 are possible.
An example in which a DC-DC converter includes the semiconductor device according to the embodiment will now be described.
In a DC-DC converter 101 of the embodiment as shown in
As shown in
Similarly, by controlling each of the gate applied voltages and the timing of the gate applied voltages for the semiconductor device 13 and the semiconductor device 1, the semiconductor device 13 and the semiconductor device 1 can function as slow diodes, fast diodes, MOSFETs, MOSFETs including a protection function, IEGTs (IGBTs), IEGTs (IGBTs) including a protection function, the reverse blocking type of each of these devices, etc. These functions of the semiconductor device 13 and the semiconductor device 1 can be realized by controlling each of the gate applied voltages and the timing of the gate applied voltages at any timing when operating or when not operating the application device. Thus, because one semiconductor device can have many functions and the optimal operation of each function is possible, the number of components of the application device decreases drastically; the reliability increases; and the performance also improves drastically.
Effects of the embodiment will now be described.
As described above, according to the embodiment, both a low ON resistance and a low turn-off loss can be realized. More stable operations are possible by selecting the timing of the operation mode and ON/OFF control according to the purpose.
According to the embodiment, the injection efficiency of the electrons and holes on the emitter side and the injection efficiency of the electrons and holes on the collector side can be controlled freely. As a result, a large current can be controlled efficiently in the semiconductor device 1 and the DC-DC converter 101.
Although an example is illustrated in the embodiment in which the semiconductor portion 50 is formed of silicon, this is not limited thereto; and the semiconductor portion 50 may be formed of a semiconductor material having a larger bandgap than silicon such as silicon carbide (SiC), gallium nitride (GaN), diamond, etc.
The proportion of the electron current flowing from the n−-type high resistance layer 20 toward the collector electrode 49 can be reduced by optimizing the disposition of the diffusion layers or the geometrical configurations of the collector-side trench gate electrodes 41a and 41b, etc. Thereby, the IE effect of the holes increases further; and more holes can be injected into the n−-type high resistance layer 20. As a result, the ON resistance of the semiconductor device 1 can be reduced even further.
A second embodiment will now be described.
In the semiconductor device 2 according to the embodiment as shown in
The following relationship is favorable, where the thickness of the n−-type high resistance layer 20 in the Z-direction is D (cm), and the specific resistance of the n−-type high resistance layer 20 is R (Q·cm).
R/D>104
According to the embodiment, both a low ON resistance and a high switching speed can be realized by forming the semiconductor portion 50 of silicon carbide which has a larger bandgap than silicon. By providing the p-type layer 51 between the n−-type high resistance layer 20 and the insulating films 32a and 42a, the electric field applied to the interface between the n−-type high resistance layer 20 made of silicon carbide and to the insulating films 32a and 42a made of silicon oxide can be relaxed.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A third embodiment will now be described.
However, a portion of
As shown in
According to the embodiment, the connection portion between the semiconductor portion 50 and the emitter electrode 39 is thinned out by providing the p-type buffer layer 52 and the insulating film 53. Thereby, the holes are stored on the emitter side of the semiconductor portion 50; and the IE effect of the electrons can be increased further. Similarly, the connection portion between the semiconductor portion 50 and the collector electrode 49 is thinned out by providing the p-type buffer layer 54 and the insulating film 55. Thereby, the electrons are stored on the collector side of the semiconductor portion 50; and the IE effect of the holes can be increased further.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A fourth embodiment will now be described.
However, a portion of
In the semiconductor device 4 according to the embodiment as shown in
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the third embodiment described above.
A fifth embodiment will now be described.
Similarly to
As shown in
Compared to the semiconductor device 1, the emitter-side trench gate electrode 31b, the insulating film 32b around the emitter-side trench gate electrode 31b, the collector-side trench gate electrode 41b, and the insulating film 42b around the collector-side trench gate electrode 41b are provided in the semiconductor device 5. Thereby, the n-type base layer 33 and the p-type base layer 34 are provided to be continuous between the emitter-side trench gate electrodes 31a adjacent to each other in the X-direction. Also, the n-type base layer 43 and the p-type base layer 44 are provided to be continuous between the collector-side trench gate electrodes 41a adjacent to each other in the X-direction. Similarly to the semiconductor device 1 according to the first embodiment described above (referring to
The n-type drift layer 57 is disposed between the X-direction central portion of the n-type base layer 33 and the X-direction central portion of the n-type base layer 43. The p-type drift layer 58 is disposed between the entire emitter-side trench gate electrode 31a, two X-direction end portions of the n-type base layer 33, the entire collector-side trench gate electrode 41a, and two X-direction end portions of the n-type base layer 43. Thereby, the n-type base layer 33 and the n-type base layer 43 are connected to both the n-type drift layer 57 and the p-type drift layer 58; and a super junction structure is realized by the n-type drift layer 57 and the p-type drift layer 58.
According to the embodiment, because the super junction structure is realized, the ON resistance can be reduced even further; and the breakdown voltage can be increased even further.
In the embodiment, the n−-type high resistance layer 20 of the first embodiment described above is replaced with the super junction structure made of the n-type drift layer 57 and the p-type drift layer 58 that vertically traverse the greater part of the semiconductor device 5 in the vertical direction (the Z-direction). Thereby, the movement path of the electrons is ensured by the n-type drift layer 57; and the movement path of the holes is ensured by the p-type drift layer 58. As a result, the injection (the storage) of the electrons from the emitter electrode 39 into the interior of the semiconductor device 5, the discharge (the extraction) of the electrons into the emitter electrode 39, the injection (the storage) of the holes from the collector electrode 49 into the interior of the semiconductor device 5, and the discharge (the extraction) of the holes into the collector electrode 49 can be controlled at a high speed and with high precision. Also, the injection (the storage) of the electrons from the emitter electrode 39 into the interior of the semiconductor device 5, the discharge (the extraction) of the electrons into the collector electrode 49, the injection (the storage) of the holes from the collector electrode 49 into the interior of the semiconductor device 5, and the discharge (the extraction) of the holes into the emitter electrode 39 can be controlled at a high speed and with high precision. Thereby, the speed of the switching operation can be increased; and the ON characteristics and the OFF characteristics can be improved.
Otherwise, the configuration, the basic operations, and the effects according to the embodiment are similar to those of the first embodiment described above.
A first modification of the fifth embodiment will now be described.
However, a portion of
As shown in
A second modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects according to the modification are similar to those of the first modification described above.
A third modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the second modification described above.
A fourth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects according to the modification are similar to those of the third modification described above.
A fifth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the first modification described above.
A sixth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the fifth modification described above.
A seventh modification of the fifth embodiment will now be described.
As shown in
According to the modification, compared to the semiconductor device 5b according to the second modification described above (referring to
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the second modification described above.
An eighth modification of the fifth embodiment will now be described.
As shown in
According to the modification, the injection (the storage) and the discharge (the extraction) of the carriers can be performed at a higher speed for the super junction structure because the n-type drift layer 57 and the p-type drift layer 58 contact the electrodes 41a and 41b on the collector side. As a result, the speed of the switching characteristics can be increased; and the ON characteristics and the OFF characteristics can be improved further.
Otherwise, the configuration, the basic operations, and the effects of the modification are similar to those of the seventh modification described above.
A ninth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the eighth modification described above.
A tenth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the ninth modification described above.
An eleventh modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the tenth modification described above.
A twelfth modification of the fifth embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the eighth modification described above.
The positional relationship between the emitter-side trench gate electrodes 31a and 31b and the collector-side trench gate electrodes 41a and 41b is not limited to the case of being aligned vertically as in the fifth embodiment described above or the case of being different from each other vertically as in the first modification of the fifth embodiment described above; and any positional relationship is possible. For example, the electrodes 31a and 31b and the gate electrodes 41a and 41b may be arranged along mutually-different directions in the XY plane.
A sixth embodiment will now be described.
However, a portion of
In the semiconductor device 6 according to the embodiment as shown in
The configuration of the emitter side of the semiconductor device 6 is the same as the configuration of the emitter side of the semiconductor device 3 according to the third embodiment described above (referring to
Wp++>3×Wn++,
and more favorable to be
Wp++>4×Wn++,
where the length of the n++-type contact layer 35 in the Y-direction is Wn++, and the length of the p++-type contact layer 36 in the Y-direction is Wp++.
It is favorable for the relationship of the surface areas to be
Spb+Sp++>3×Sn++,
and more favorable to be
Spb+Sp++>4×Sn++,
where the contact surface area between the emitter electrode 39 and the n++-type contact layer 35 is Sn++, the contact surface area between the emitter electrode 39 and the p++-type contact layer 36 is Sp++, and the contact surface area between the emitter electrode 39 and the p-type base layer 34 is Spb.
On the other hand, on the collector side, a block 63 that is made of n-type layers 61 and p-type layers 62 periodically arranged alternately along the X-direction is multiply provided. The n-type layers 61 and the p-type layers 62 extend in the Y-direction. The blocks 63 are arranged to be separated from each other along the X-direction. An n-type layer 64 is provided between the blocks 63. In the X-direction, the width of the n-type layer 64 is wider than the widths of the n-type layer 61 and the p-type layer 62. The n-type layer 61, the p-type layer 62, and the n-type layer 64 contact the collector electrode 49. A p-type layer 65 is provided on the block 63. An n-type layer 66 is provided to cover the n-type layer 64 and the p-type layer 65. The upper surface of the n-type layer 66 contacts the lower surface of the n−-type high resistance layer 20.
According to the embodiment, the ON resistance can be reduced further by the sizes of the n++-type contact layer 35 and the p++-type contact layer 36 satisfying the formulas recited above.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the third embodiment described above.
A seventh embodiment will now be described.
In
In the semiconductor device 7 according to the embodiment as shown in
To further promote the injection of the electrons on the emitter side by the electron IE effect, it is effective to design a width W1 to be narrow and favorable to set the width W1 to be, for example, 1 μm or less, where the width of the n-type base layer 33 in the X-direction is W1, and the width of the electrode 31b in the X-direction is W2. Also, it is possible to increase the electron IE effect by designing the width W2 to be wider than the width W1.
It is favorable for the relationship of the width W1 and the width W2 to be, for example,
W2>2×W1,
and more favorable to be
W2>10×W1.
The width W2 may be configured by a single wide trench or multiple subdivided trenches.
On the other hand, the configuration of the collector side of the semiconductor device 7 is planar. In other words, a contact layer 69 that has a flat plate configuration is provided on the collector electrode 49; and an n−-type drift layer 70 is provided on the contact layer 69. The upper surface of the n−-type drift layer 70 contacts the lower surface of the n−-type high resistance layer 20. The conductivity type of the contact layer 69 may be the n+-type or the p+-type; and both an n+-type portion and a p+-type portion may be provided.
According to the embodiment, the injection of the electrons from the end portion in the Y-direction of the semiconductor device 7 can be suppressed because the p+-type contact layer 36a is provided to surround the end portion in the Y-direction of the region directly above the electrode 31b. As a result, the breakdown voltage of the end portion in the Y-direction increases; and a semiconductor device having a high breakdown voltage as an entirety can be obtained.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A first modification of the seventh embodiment will now be described.
In the semiconductor device 7a according to the modification as shown in
To further promote the injection of the electrons on the emitter side by the electron IE effect, it is effective to design the width W12 to be narrow and favorable to set the width W12 to be, for example, 1 μm or less. Also, it is possible to increase the electron IE effect by designing the width W11 and the width W13 to be wider than the width W12.
For example, it is favorable when
W11>2×W12, and
W13>2×W12;
and more favorable for
W11>10×W12, and
W13>10×W12.
The width W11 and the width W13 may be configured by a single trench having a wide width or multiple subdivided trenches.
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the seventh embodiment described above.
A seventh embodiment and the second modification will now be described.
In the semiconductor device 7b according to the modification as shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the first modification of the seventh embodiment described above.
A third modification of the seventh embodiment will now be described.
In the semiconductor device 7c according to the modification as shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the second modification of the seventh embodiment described above.
A fourth modification of the seventh embodiment will now be described.
As shown in
A fifth modification of the seventh embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the fourth modification of the seventh embodiment described above.
A sixth modification of the seventh embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the modification are similar to those of the fifth modification of the seventh embodiment described above.
An eighth embodiment will now be described.
In the semiconductor device 8 according to the embodiment as shown in
In the semiconductor device 8, the insulating film 32a extends downward; and the lower end of the insulating film 32a is positioned slightly below an interface 75 between the n+-type buffer layer 73 and the n-type buffer layer 74. Also, the insulating film 32b extends downward; and the lower end of the insulating film 32b is positioned slightly above an interface 76 between the p+-type contact layer 72 and the n+-type buffer layer 73.
According to the embodiment, by setting the insulating films 32a and 32b to extend downward, the surface area of the p-n interface between the p-type base layer 34 and the n−-type high resistance layer 20 can be reduced; and the volume of the depletion layer extending on the n−-type high resistance layer 20 side can be reduced. Thereby, the lifetime of the carriers inside the n−-type high resistance layer 20 can be lengthened.
Generally, when the temperature of the semiconductor device increases, the electrons and the holes combine easily at crystal defects; and the leakage current increases. In the embodiment, by lengthening the lifetime of the carriers, the leakage current when the semiconductor device 8 operates at a high temperature can be suppressed. Therefore, the operating characteristics of the semiconductor device 8 are good at high temperatures, e.g., 200° C.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A ninth embodiment will now be described.
As shown in
In the portion (hereinbelow, called the “cell portion”) other than the terminal portion of the semiconductor device 9, the p-type base layer 34 is provided on the n−-type high resistance layer 20; and the n-type base layer 33 that extends in the Y-direction is provided at a portion of the upper portion of the p-type base layer 34. The multiple emitter-side trench gate electrodes 31a are provided to be adjacent to the n-type base layer 33 and the p-type base layer 34. The electrodes 31a extend in the Y-direction and are arranged periodically along the X-direction. The lower end portion of the electrode 31a is disposed inside the n−-type high resistance layer 20.
The insulating film 32a is provided around the electrode 31a. The emitter electrode 39 is provided on the emitter-side trench gate electrode 31a, the n-type base layer 33, the p-type base layer 34, and the end portion of the p+-type guard ring layer 78 on the cell portion side and is connected to the p+-type guard ring layer 78, the p-type base layer 34, and the n-type base layer 33.
At the X-direction central portion of the cell portion, an n+-type layer 79 is provided below the n−-type high resistance layer 20; and a p-type layer 80 is provided below the n+-type layer 79. The side surface and upper surface of the p-type layer 80 are covered with the n+-type layer 79. The lower surface of the p-type layer 80 is connected to the collector electrode 49. Multiple p-type trench layers 81 that extend in the Y-direction are provided at the lower surface of the n−-type high resistance layer 20 between the p+-type guard ring layer 78 and the n+-type layer 79. The terminal structure of the semiconductor device 9 is formed of the p+-type guard ring layer 78 and the p-type trench layer 81.
In the embodiment, the breakdown voltage of the terminal portion can be increased by providing the p+-type guard ring layer 78 and the p-type trench layer 81.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A tenth embodiment will now be described.
As shown in
In the semiconductor device 10, the structure of the emitter side and the structure of the collector side both are formed in the upper surface of the n−-type high resistance layer 20. The emitter electrode 39 and the collector electrode 49 also are disposed to be separated from each other on the upper surface of the n−-type high resistance layer 20. Similarly to the seventh embodiment described above (referring to
To promote the injection of the electrons on the emitter side by the electron IE effect, it is effective for the width WE1 to be narrow, and it is effective for the width WE2 and the width WE3 to be wider than the width WE1, where the trench-gate spacing on the emitter side, i.e., the width of the n-type base layer 33 in the X-direction, is WE1, the width of the electrode 31a is WE3, the width of the electrode 31b is WE2, the trench-gate spacing on the collector side, i.e., the width of the n-type base layer 43 in the X-direction, is WC1, the width of the electrode 41a is WC3, and the width of the electrode 41b is WC2. Also, to promote the injection of the holes on the collector side by the hole IE effect, it is effective for the width WC1 to be narrow, and it is effective for the width WC2 and the width WC3 to be wider than the width WC1. For example, it is favorable for the width WE1 and the width WC1 to be 1 μm or less. The width WE2 and the width WE3 may be configured by a single trench having a wide width or multiple subdivided trenches. This is similar for the width WC2 and the width WC3 as well.
For example, it is favorable when
WE2>2×WE1,
WE3>2×WE1,
WC2>2×WC1, and
WC3>2×WC1;
and more favorable when
WE2>10×WE1,
WE3>10×WE1,
WC2>10×WC1, and
WC3>10×WC1.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
An eleventh embodiment will now be described.
As shown in
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the tenth embodiment described above.
A silicon substrate (not shown) may be provided below the insulating film 83. This is advantageous for high speed switching operations because the IEGT can be formed in the silicon layer of an SOI (silicon on insulator) substrate.
A twelfth embodiment will now be described.
As shown in
As shown in
On the other hand, on the drain side of the semiconductor device 12, an n-type drift layer 85 is provided on the n−-type high resistance layer 20; and a p+-type drain layer 86 is provided on the n-type drift layer 85. The p+-type drain layer 86 is separated from the n−-type high resistance layer 20 by the n-type drift layer 85. The p+-type drain layer 86 is connected to a drain electrode 87.
In the semiconductor device 12, a p-n-p-type field effect transistor is formed of the p-type base layer 34, the n−-type high resistance layer 20, the n-type drift layer 85, and the p+-type drain layer 86.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the tenth embodiment described above.
A thirteenth embodiment will now be described.
The semiconductor device 13 according to the embodiment is a lateral p-n diode as shown in
As shown in
On the other hand, on the cathode side of the semiconductor device 13, the n-type drift layer 85 is provided on the n−-type high resistance layer 20; and an n+-type cathode layer 89 is provided on the n-type drift layer 85. The n+-type cathode layer 89 is separated from the n−-type high resistance layer 20 by the n-type drift layer 85. The n+-type cathode layer 89 is connected to a cathode electrode 90.
In the semiconductor device 13, a p-n diode is formed of the p-type base layer 34, the n−-type high resistance layer 20, the n-type drift layer 85, and the n+-type cathode layer 89.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the tenth embodiment described above.
A fourteenth embodiment will now be described.
As shown in
Y-direction.
According to the embodiment, both the increase of the ON current and the increase of the breakdown voltage can be realized because a super junction structure is formed of the n-type layer 92 and the p-type layer 93.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the thirteenth embodiment described above.
A fifteenth embodiment will now be described.
As shown in
As shown in
The configurations of the emitter-side electrode plate 121 and the collector-side electrode plate 122 both are plate configurations; and the outer edges of the emitter-side electrode plate 121 and the collector-side electrode plate 122 are outside the outer edge of the semiconductor device 1 as viewed from the Z-direction. Connection members 123 and 124 are provided in the package 120; the emitter-side electrode plate 121 is connected to the emitter electrode 39 of the semiconductor device 1 via the connection member 123; and the collector-side electrode plate 122 is connected to the collector electrode 49 of the semiconductor device 1 via the connection member 124.
A field plate electrode 125 is provided on the surface of the terminal portion of the semiconductor device 1 and covers the entire terminal portion. A capping material 126 is provided in the package 120 and covers the field plate electrode 125. For example, the capping material 126 is formed of a semi-insulating polycrystalline silicon (SIPOS) layer. The capping material 126 is separated a prescribed distance from the emitter-side electrode plate 121 and the collector-side electrode plate 122. The capping material 126 may be formed of non-doped polysilicon.
Thus, in the package 120 according to the embodiment, by covering the terminal portion of the chip made of the semiconductor device 1 with the field plate electrode 125 and by covering the outside of the terminal portion with the semi-insulating capping material 126, the concentration of the electric field at the terminal portion can be relaxed; and the breakdown voltage of the terminal portion can be increased.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the first embodiment described above.
A sixteenth embodiment will now be described.
As shown in
In the semiconductor device 16, the emitter-side trench gate electrode 31a and the collector-side trench gate electrode 41a are not provided at the terminal portion; and a p-type RESURF layer 94 and an n+-type RESURF layer 95 are provided instead. The p-type RESURF layer 94 is disposed at a position separated from the chip surface; and the n+-type RESURF layer 95 is disposed at a corner of the chip and contacts the field plate electrode 125.
According to the embodiment, the depletion layer reaching the terminal portion can be suppressed by providing the p-type RESURF layer 94 and the n+-type RESURF layer 95 at the terminal portion of the semiconductor device 16. Thereby, the breakdown voltage of the terminal portion improves even further.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to the fifteenth embodiment described above.
A seventeenth embodiment will now be described.
As shown in
Connection members 144 and 145 are provided in the package 140. The external electrode 142 is connected to the emitter electrodes 39 of the semiconductor devices 9 (referring to
According to the embodiment, the emitter-side trench gate electrodes 31a of the semiconductor devices 9 are connected by the gate interconnect 150. In the gate interconnect 150, the periphery of the core interconnect 151 is covered with the shield interconnect 153 to which a fixed potential is applied. Thereby, it is possible to reduce the inductance of the gate interconnect 150 and to provide active control and a higher speed of the switching operations of the multiple semiconductor devices 9 connected in parallel. As a result, the multiple semiconductor devices 9 that are formed of a wide-gap semiconductor such as silicon carbide (SiC), gallium nitride (GaN), etc., can operate in parallel without loss of the high speed operation characteristics of the semiconductor devices 9 themselves.
In the package 140 according to the embodiment, the multiple semiconductor devices 9 are connected in straight lines to the common external electrodes 142 and 143 via the connection members 144 and 145. Thereby, the thermal resistance between the semiconductor devices 9 and the external electrodes 142 and 143 is low; and heat dissipation can be performed from two surfaces of the semiconductor device 9. Therefore, the cooling performance of the semiconductor devices 9 is high.
Thus, according to the embodiment, the multiple semiconductor devices 9 that are connected in parallel can operate at a high speed without a loss of cooling performance. As a result, the entire package 140 can operate at a high speed while effectively utilizing the high speed operation characteristics of the semiconductor devices 9 formed of a semiconductor material having a wide bandgap such as silicon carbide, gallium nitride, etc.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the ninth embodiment described above.
An eighteenth embodiment will now be described.
In the package 160 according to the embodiment as shown in
The spacer electrode 161 and the conductive paste 162 function as shield materials for the core interconnect 151 and the conductive material that conduct, to the emitter electrode 39, the emitter potential applied to the external electrode 142. Also, the spacer electrode 161 and the conductive paste 162 function as thermally conductive materials that conduct, to the external electrode 142, the heat generated by the semiconductor devices 9. Thereby, in the package 160 according to the embodiment, compared to the package 140 according to the seventeenth embodiment described above, the interconnect resistance and inductance on the emitter side are low; and the thermal conductivity is high.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the seventeenth embodiment described above.
A nineteenth embodiment will now be described.
As shown in
According to the embodiment, the cooling performance is high because the insulating member 171 also conducts heat in addition to the connection members 144 and 145.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the seventeenth embodiment described above.
A twentieth embodiment will now be described.
In the package 180 according to the embodiment as shown in
The emitter electrodes 39 of the semiconductor devices 1 (referring to
According to the embodiment, similar to the nineteenth embodiment, the package may include the double-sided trench gate-type semiconductor device as well.
Otherwise, the configuration, the operations, and the effects of the embodiment are similar to those of the nineteenth embodiment described above.
A twenty-first embodiment will now be described.
The embodiment summarily describes a first method for manufacturing the semiconductor device 1 according to the first embodiment described above (referring to
First, an n−-type high resistance wafer 20w is prepared as shown in
Although the surface A is notated as the upper side and the surface B is notated as the lower side constantly in the following drawings, the wafer is flipped as necessary in the actual processes. For example, normally, the wafer is held so that the surface B is the upper side in processes that perform processing of the surface B. Although only the method for forming the main portions of the semiconductor device are described summarily in the description hereinbelow, in the actual processes, various processes are appropriately inserted between, before, or after the processes described below. For example, formation processes of the terminal structure and the like are inserted.
As shown in
Then, as shown in
Continuing as shown in
Then, as shown in
Continuing as shown in
Then, as shown in
Continuing as shown in
A modification of the twenty-first embodiment will now be described.
The modification summarily describes a method for manufacturing the semiconductor device 5 according to the fifth embodiment described above (referring to
First, as shown in
Then, the processes shown in
A twenty-second embodiment will now be described.
The embodiment summarily describes a second method for manufacturing the semiconductor device 1 according to the first embodiment described above (referring to
First, the n−-type high resistance wafer 20w is prepared as shown in
As shown in
Then, as shown in
Continuing as shown in
Then, as shown in
Continuing as shown in
Then, as shown in
Continuing as shown in
Otherwise, the configuration and the manufacturing method of the embodiment are similar to those of the twenty-first embodiment described above.
In the embodiment as well, similarly to the modification of the twenty-first embodiment described above, the semiconductor device 5 according to the fifth embodiment described above (referring to
A twenty-third embodiment will now be described.
The embodiment summarily describes a third method for manufacturing the semiconductor device 1 according to the first embodiment described above (referring to
First, the n−-type high resistance wafer 20w is prepared as shown in
Then, as shown in
Then, as shown in
Continuing as shown in
Then, as shown in
Continuing as shown in
Continuing as shown in
Thereafter, the method is similar to that of the twenty-first embodiment described above. In other words, as shown in
According to the embodiment, compared to the twenty-first embodiment described above, the heat treatment can be performed while supporting the n−-type high resistance wafer 20w by the support substrate 205 in the process shown in
In the embodiment as well, similarly to the modification of the twenty-first embodiment described above, the semiconductor device 5 according to the fifth embodiment described above (referring to
According to the embodiments described above, a semiconductor device and a method for driving the semiconductor device capable of improving the controllability of the current can be realized.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention. Additionally, the embodiments described above can be combined mutually.
Number | Date | Country | Kind |
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2015-178582 | Sep 2015 | JP | national |
This application is a divisional of application Ser. No. 15/042,854, filed Feb. 12, 2016 and is based upon and claims the benefit of priority from Japanese Patent Application No. 2015-178582, filed on Sep. 10, 2015; the entire contents of which are incorporated herein by reference.
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Number | Date | Country | |
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20170317199 A1 | Nov 2017 | US |
Number | Date | Country | |
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Parent | 15042854 | Feb 2016 | US |
Child | 15652416 | US |