JP4997660B2 - Semiconductor device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a semiconductor device including a high electron mobility transistor (HEMT) that achieves both high g _m (g _m : mutual conductance) and high BV _on (BV _on : ON breakdown voltage).
[0002]
HEMTs have been widely used as devices in the microwave band and millimeter wave band because of their excellent high frequency characteristics, but in recent years, they have also been used as power devices with the development of communication systems in the millimeter wave band. I came.
[0003]
In the HEMT used as a power device, a high current driving capability is required, and therefore a double heterostructure (DH) structure is used.
[0004]
In such a DH-HEMT, two-dimensional electron gas (2-DEG) is epitaxially grown so as to be generated at the center of the channel layer in order to obtain high characteristics by suppressing the influence of interface scattering. Often the layer structure is designed.
[0005]
In recent years, demands for higher output and lower distortion for power amplifiers have increased, so it is indispensable to operate the power amplifier at a high voltage, and the HEMT used in the power amplifier is operated at a high voltage. The withstand voltage must be high.
[0006]
However, as described above, when 2DEG is located at the center of the channel layer, collision ionization is likely to occur and there is a problem that the breakdown voltage of the HEMT is lowered. There is a trade-off relationship.
[0007]
[Problems to be solved by the invention]
In the present invention, by adopting simple means, the generation position of 2DEG in the HEMT is changed to achieve high characteristics such as high output and low distortion, and at the same time, high breakdown voltage.
[0008]
[Means for Solving the Problems]
In the HEMT according to the present invention, on the source side, 2DEG is generated so as to be located at the center of the channel to realize high g _m , and on the drain side, 2DEG is placed either above or below the channel center. so produced shifted position to achieve high breakdown voltage, and is both high g _m and a high breakdown voltage.
[0009]
In order to realize such a structure, in the case of DH-HEMT, the layer thickness, the composition, the carrier concentration of the upper or lower electron supply layer, the upper and lower electron supply layers, or a combination thereof is changed. In addition, it is also possible to change the layer thickness of the spacer layer, the composition of the channel layer, and the like from the source side to the drain side.
[0010]
Here, in order to understand the principle of the present invention, the generation position of 2DEG in DH-HEMT will be described.
[0011]
FIG. 1 is a cut-away side view of the main part showing a HEMT, wherein 1 is a substrate, 2 is a buffer layer, 3 is a lower electron supply layer, 4 is a channel layer, 5 is an upper electron supply layer, and 6 is The barrier layer, 7 is a cap layer, 8 is a source electrode, 9 is a drain electrode, 10 is a gate electrode, and 11 is 2DEG.
[0012]
Usually, the position of 2DEG in the channel layer of the DH-HEMT is determined by the distribution of the carrier supply amount from the upper and lower electron supply layers, and the carrier from the lower electron supply layer 3 and the upper electron supply layer 5 is determined. If the supply amount is substantially equal, the 2DEG 11 is generated at the approximate center of the channel layer 4 as seen in FIG.
[0013]
When many carriers are supplied from the upper electron supply layer 5, 2DEG 11 is generated on the upper side of the channel layer 4 as seen in FIG.
[0014]
If many carriers are supplied from the lower electron supply layer 3, 2DEG 11 is generated below the channel layer 4 as shown in FIG.
[0015]
FIG. 2 is a diagram comparing g _m and BV _on in the three types of HEMTs shown in FIG. 1. In FIG. 2A, the 2DEG position is plotted on the horizontal axis and the vertical axis is plotted on the vertical axis. Yes takes the g _m respectively, is at (B), the the 2DEG position on the horizontal axis, also are taken respectively BV _on the vertical axis.
[0016]
As apparent from FIG. 2 (A), the HEMT in which 2DEG is present in the center of the channel layer, that is, the HEMT shown in FIG. 1 (A) has the highest g _m. Because of the separation, the interface scattering is small and the electron mobility is the highest.
[0017]
However, when the three types of HEMTs are compared from the BV _on surface shown in FIG. 2B, it is clear that a tendency opposite to that of g _m appears. This is because the electron mobility is high. This is because the electron velocity increases and collision ionization is likely to occur.
[0018]
In order to operate the HEMT at a high voltage, it is natural that BV _on must be high, but the off breakdown voltage (BV _off ) must also be high, and this BV _off is also shown in FIG. There is a tendency similar to BV _on described in.
[0019]
Thus, in ordinary HEMTs, it is known that both g _m and breakdown voltage depend on the electron mobility, but considering this point in more detail, g _m is the electron mobility on the source side. However, BV _on is related to the electron mobility _on the drain side.
[0020]
Thus, the source side will achieve a high g _m of by the location of the 2DEG at the center of the channel layer, and high breakdown voltage by causing shift in either up and down position of the 2DEG from the center of the channel layer at the drain side By realizing this, it is possible to achieve both high g _m and high breakdown voltage.
[0021]
FIG. 3 is a cut-away side view of the main part showing the DH-HEMT for explaining the principle of the present invention, and the same symbols as those used in FIG. 1 represent the same parts or have the same meaning.
[0022]
The difference between the illustrated DH-HEMT and the DH-HEMT shown in FIG. 1 is that the amount of electrons supplied from the lower electron supply layer 3 to the 2DEG 11 is gradually increased from the source side toward the drain side. Depending on this configuration, as shown in the figure, the 2DEG 11 is located at the approximate center of the channel layer 4 on the source side, but at the heterointerface between the channel layer 4 and the lower electron supply layer 3 toward the drain side. It approaches and is far away from the center of the channel layer 4 in the vicinity of the drain.
[0023]
Therefore, in the DH-HEMT of FIG. 3, g _m is maintained high on the source side, and the breakdown voltage is increased on the drain side. It is to be noted that the 2DEG 11 has the same effect as that shown in FIG. 3, that is, the inclination of the 2DEG 11 approaches the heterointerface between the channel layer 4 and the upper electron supply layer 5 toward the drain side.
[0024]
From the foregoing, in the semiconductor device according to the present invention,
(1)
The two-dimensional electron gas (for example, 2DEG 36) generated in the channel layer (for example, the channel layer 28) is at the center of the channel layer on the source side (for example, the source electrode 33 side) and on the drain side (for example, the drain electrode 34 side). Characterized in that it comprises a HEMT located either up or down from the center of the layer, or
[0025]
(2)
In (1), an electron supply layer (for example, electron supply layers 26 and 30) is formed below and on the channel layer, or
[0026]
(3)
In (1) or (2), the position of the two-dimensional electron gas generated in the channel layer is continuously shifted from the source side toward the drain side.
[0027]
Depending on adopting the means, by changing the generation position of the in 2DEG in the channel layer of the HEMT, a high g _m of the source side and the drain side is realized high breakdown voltage, conventionally, to balance This makes it possible to simultaneously achieve high characteristics such as high output and low distortion, and high breakdown voltage, which are difficult to achieve, and is suitable for use in power amplifiers operating at high voltages in the microwave band and millimeter wave band. is there.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 4 is a cutaway side view of the main part showing the structure of the wafer common to the respective embodiments of the present invention. In FIG. 4, 21 is a GaAs substrate, 22A is an i-AlGaAs buffer layer, and 23 is i-. A GaAs buffer layer, 24 is a mask layer made of SiO ₂ , and 25 is a recess formed in the i-GaAs buffer layer 23.
[0029]
The wafer shown in FIG. 4 was prepared as follows. That is, by applying the metal organic chemical vapor deposition method, an i-AlGaAs buffer layer 22A having an Al composition of 0.3 and a layer thickness of 300 nm is formed on the GaAs substrate 21 and the layer thickness is 200 nm. The i-GaAs buffer layers 23 are sequentially stacked.
[0030]
Next, by applying a chemical vapor deposition method, a mask layer 24 made of SiO ₂ having a layer thickness of 200 nm is formed on the i-GaAs layer 23, and then a resist process in lithography technology is performed. Depending on the application, a mask film 24 and i made of SiO ₂ is formed by applying a dry etching method in which a resist film having an opening is formed in a region where HEMT is to be prepared and an etching gas is SF ₆ -based gas. The GaAs buffer layer 23 is selectively etched to form a recess 25.
[0031]
After that, various semiconductor layers corresponding to the respective embodiments are formed in the recess 25, and then the source electrode, the drain electrode, the gate recess, the gate electrode, and the like are formed to complete the DH-HEMT. Hereinafter, each embodiment will be described.
[0032]
Embodiment 1 (see FIG. 5)
By applying the metal organic vapor phase epitaxy, the following semiconductor layers are stacked in the recess 25.
[0033]
i-AlGaAs buffer layer 22B
(Al composition 0.3, layer thickness 100 [nm])
n-AlGaAs lower electron supply layer 26
(Al composition 0.25, layer thickness d1, electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs lower spacer layer 27
(Al composition 0.25, layer thickness 3 [nm])
i-InGaAs channel layer 28
(In composition 0.2, layer thickness 15 [nm])
i-AlGaAs upper spacer layer 29
(Al composition 0.25, layer thickness 3 [nm])
n-AlGaAs upper electron supply layer 30
(Al composition 0.25, layer thickness 15 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs barrier layer 31
(Al composition 0.25, layer thickness 10 [nm])
n-GaAs cap layer 32
(Layer thickness 50 [nm], electron concentration 5 × 10 ¹⁸ [cm ⁻³ ])
[0034]
When growing the semiconductor layer, it is possible to change the layer thickness according to the distance from the mask film 24 by selecting the growth condition, and the layer thickness d1 of the lower electron supply layer 26 is utilized. Is 5 [nm] near the source and 10 [nm] near the drain. The other semiconductor layers are grown by applying growth conditions that do not change the layer thickness.
[0035]
5D, the 2DEG 36 is located at the approximate center of the channel layer 28 on the source side, and on the lower side from the center of the channel layer 28 on the drain side. Is located.
[0036]
The change in the layer thickness d1 of the lower electron supply layer 26 is determined by the diffusion length of the group III material from the mask layer 24. The shorter the diffusion length, the larger the layer thickness change. It can be changed depending on the pressure in the tube, the substrate temperature, the raw material flow rate, the raw material supply amount, etc., but the easiest is the supply ratio of the Group 5 material to the Group 3 material (hereinafter referred to as Group 5 / For example, at a growth pressure of 76 [Torr] and a substrate temperature of 600 [° C.], if the fifth group / third group = 200, the layer thickness does not change, and the fifth group / third group. If it is set to = 20, the said layer thickness change is realizable.
[0037]
Thereafter, a lithography method, a vacuum vapor deposition method, and a lift-off method are applied to form a source electrode 33 and a drain electrode 34 made of AuGe / Au, and then a resist process in the lithography method is applied, A resist film having an opening is formed in a recess formation scheduled portion, and then a dry etching method using SF ₆ -based gas as an etching gas is applied, and the cap layer 22 is selectively etched using the resist film as a mask. A gate recess is formed, a barrier layer 31 is exposed at the bottom of the gate recess, and then a lithography method, a vacuum deposition method, and a lift-off method are applied to form a gate electrode 35 made of Al. In this case, the gate length was set to 0.2 [μm].
[0038]
Through the above-described steps, DH-HEMTs having g _{m to} 500 [mS / mm], BV _on to 10 [V], and drain breakdown voltage BV _gd to 15 [V] were obtained. Incidentally, in the DH-HEMT according to the prior art prepared for comparison, when the layer thickness of the lower electron supply layer is 5 nm over the entire region, g _{m to} 500 [mS / mm], BV _on -7 [V], BV _gd -10 [V], and when the thickness of the lower electron supply layer is 10 [nm] over the entire region, g _m -450 [MS / mm], BV _on -10 [V], BV _gd -15 [V].
[0039]
In the first embodiment, only the thickness of the lower electron supply layer 26 is changed. However, the same effect can be obtained when the thickness of the upper electron supply layer 30 is changed. it can.
[0040]
Embodiment 2 (see FIG. 6)
After forming the recess 25 in the same manner as in the first embodiment, the following semiconductor layers are stacked in the recess 25 by applying a metal organic chemical vapor deposition method.
[0041]
i-AlGaAs buffer layer 22B
(Al composition 0.3, layer thickness 100 [nm])
n-AlGaAs lower electron supply layer 26
(Al composition 0.25, layer thickness 5 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs lower spacer layer 27
(Al composition 0.25, layer thickness d2)
i-InGaAs channel layer 28
(In composition 0.2, layer thickness 15 [nm])
i-AlGaAs upper spacer layer 29
(Al composition 0.25, layer thickness 3 [nm])
n-AlGaAs upper electron supply layer 30
(Al composition 0.25, layer thickness 15 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs barrier layer 31
(Al composition 0.25, layer thickness 10 [nm])
n-GaAs cap layer 32
(Layer thickness 50 [nm], electron concentration 5 × 10 ¹⁸ [cm ⁻³ ])
[0042]
When growing the semiconductor layer, the growth conditions are selected in the same manner as in the first embodiment, and the layer thickness in the lower spacer layer 27 is utilized by utilizing the fact that the layer thickness changes according to the distance from the mask film 24. d2 is 3 nm near the source and 0.5 nm near the drain. In other semiconductor layers, growth is performed by applying growth conditions that do not change the layer thickness.
[0043]
By doing so, as seen in FIG. 6, the 2DEG 36 is located at the approximate center of the channel layer 28 on the source side, and on the lower side from the center of the channel layer 28 on the drain side. Is located.
[0044]
Thereafter, the source electrode 33 and the drain electrode 34, the gate recess, and the gate electrode 35 are formed in the same manner as in the first embodiment.
[0045]
In the first embodiment, only the thickness of the lower spacer layer 27 is changed, but the same effect can be obtained when the thickness of the upper spacer layer 29 is changed.
[0046]
Embodiment 3 (see FIG. 7)
After forming the recess 25 in exactly the same manner as in the first embodiment, the following semiconductor layers are stacked in the recess 25 by applying a metal organic chemical vapor deposition method.
[0047]
i-AlGaAs buffer layer 22B
(Al composition 0.3, layer thickness 100 [nm])
n-AlGaAs lower electron supply layer 26
(Al composition 0.25, layer thickness 5 [nm], electron concentration N)
i-AlGaAs lower spacer layer 27
(Al composition 0.25, layer thickness 3 [nm])
i-InGaAs channel layer 28
(In composition 0.2, layer thickness 15 [nm])
i-AlGaAs upper spacer layer 29
(Al composition 0.25, layer thickness 3 [nm])
n-AlGaAs upper electron supply layer 30
(Al composition 0.25, layer thickness 15 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs barrier layer 31
(Al composition 0.25, layer thickness 10 [nm])
n-GaAs cap layer 32
(Layer thickness 50 [nm], electron concentration 5 × 10 ¹⁸ [cm ⁻³ ])
[0048]
When growing the semiconductor layer, the growth conditions are selected in the same manner as in the first embodiment, and the fact that the carrier concentration changes according to the distance from the mask film 24 makes it possible to use the electrons in the lower electron supply layer 26. The concentration N is 2 × 10 ¹⁸ [cm ⁻³ ] near the source and 3 × 10 ¹⁸ [cm ⁻³ ] near the drain. In other semiconductor layers, growth is performed by applying growth conditions that do not change the electron concentration or the layer thickness.
[0049]
By doing so, as seen in FIG. 7, the 2DEG 36 is located at the approximate center of the channel layer 28 on the source side, and on the lower side from the center of the channel layer 28 on the drain side. Is located.
[0050]
Thereafter, the source electrode 33 and the drain electrode 34, the gate recess, and the gate electrode 35 are formed in the same manner as in the first embodiment.
[0051]
In the third embodiment, only the carrier concentration of the lower electron supply layer 26 is changed. However, the same effect can be obtained when the layer thickness of the upper electron supply layer 30 is changed. it can.
[0052]
Embodiment 4 (refer FIG. 7)
After forming the recess 25 in the same manner as in the first embodiment, the following semiconductor layers are stacked in the recess 25 by applying a metal organic chemical vapor deposition method.
[0053]
i-AlGaAs buffer layer 22B
(Al composition 0.3, layer thickness 100 [nm])
n-AlGaAs lower electron supply layer 26
(Al composition x, layer thickness 5 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs lower spacer layer 27
(Al composition 0.25, layer thickness 3 [nm])
i-InGaAs channel layer 28
(In composition 0.2, layer thickness 15 [nm])
i-AlGaAs upper spacer layer 29
(Al composition 0.25, layer thickness 3 [nm])
n-AlGaAs upper electron supply layer 30
(Al composition 0.25, layer thickness 15 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs barrier layer 31
(Al composition 0.25, layer thickness 10 [nm])
n-GaAs cap layer 32
(Layer thickness 50 [nm], electron concentration 5 × 10 ¹⁸ [cm ⁻³ ])
[0054]
When growing the semiconductor layer, the growth conditions are selected in the same manner as in the first embodiment, and the fact that the Al composition changes according to the distance from the mask film 24 makes it possible to use the Al in the lower electron supply layer 26. The composition x is 0.25 near the source and 0.3 near the drain. In other semiconductor layers, growth is performed by applying growth conditions that do not change the Al composition, the layer thickness, and the like.
[0055]
By doing so, as seen in FIG. 7, the 2DEG 36 is located at the approximate center of the channel layer 28 on the source side, and on the lower side from the center of the channel layer 28 on the drain side. Is located.
[0056]
Thereafter, the source electrode 33 and the drain electrode 34, the gate recess, and the gate electrode 35 are formed in the same manner as in the first embodiment.
[0057]
In the third embodiment, only the Al composition x of the lower electron supply layer 26 is changed, but the same effect is obtained when the Al composition x of the upper electron supply layer 30 is changed. be able to.
[0058]
Embodiment 5 (see FIG. 7)
After forming the recess 25 in the same manner as in the first embodiment, the following semiconductor layers are stacked in the recess 25 by applying a metal organic chemical vapor deposition method.
[0059]
i-AlGaAs buffer layer 22B
(Al composition 0.3, layer thickness 100 [nm])
n-AlGaAs lower electron supply layer 26
(Al composition 0.25, layer thickness 5 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs lower spacer layer 27
(Al composition 0.25, layer thickness 3 [nm])
i-InGaAs channel layer 28
(In composition y, layer thickness 15 [nm])
i-AlGaAs upper spacer layer 29
(Al composition 0.25, layer thickness 3 [nm])
n-AlGaAs upper electron supply layer 30
(Al composition 0.25, layer thickness 15 [nm], electron concentration 2 × 10 ¹⁸ [cm ⁻³ ])
i-AlGaAs barrier layer 31
(Al composition 0.25, layer thickness 10 [nm])
n-GaAs cap layer 32
(Layer thickness 50 [nm], electron concentration 5 × 10 ¹⁸ [cm ⁻³ ])
[0060]
When growing the semiconductor layer, the same growth conditions as in the first embodiment are selected, and the In composition y in the channel layer 28 is changed by utilizing the fact that the In composition changes according to the distance from the mask film 24. The value is 0.20 near the source and 0.17 near the drain. In other semiconductor layers, growth is performed by applying growth conditions that do not change the In composition, the layer thickness, and the like.
[0061]
By doing so, as seen in FIG. 7, the 2DEG 36 is located at the approximate center of the channel layer 28 on the source side, and on the lower side from the center of the channel layer 28 on the drain side. Is located.
[0062]
Thereafter, the source electrode 33 and the drain electrode 34, the gate recess, and the gate electrode 35 are formed in the same manner as in the first embodiment.
[0063]
In the present invention, good results can be obtained even when the above embodiments are applied in combination.
[0064]
【Effect of the invention】
In the semiconductor device according to the present invention, the HEMT in which the two-dimensional electron gas generated in the channel layer is located at the center of the channel layer on the source side and is shifted either up or down from the center of the channel layer on the drain side. Is included.
[0065]
Depending on adopting the configuration, by changing the generation position of the in 2DEG in the channel layer of the HEMT, a high g _m of the source side and the drain side is realized high breakdown voltage, conventionally, to balance This makes it possible to simultaneously achieve high characteristics such as high output and low distortion, and high breakdown voltage, which are difficult to achieve, and is suitable for use in power amplifiers operating at high voltages in the microwave band and millimeter wave band. is there.
[Brief description of the drawings]
FIG. 1 is a cutaway side view of a main part showing a HEMT.
2 is a diagram comparing g _m and BV _on in the three types of HEMTs seen in FIG. 1. FIG.
FIG. 3 is a cutaway side view of a main part showing a DH-HEMT for explaining the principle of the present invention.
FIG. 4 is a cut-away side view of the main part showing the configuration of the wafer common to the respective embodiments of the present invention.
FIG. 5 is a cutaway side view of a main part showing a DH-HEMT.
FIG. 6 is a cutaway side view of a main part showing a DH-HEMT.
FIG. 7 is a cut-away side view of an essential part showing a DH-HEMT.
[Explanation of symbols]
21 Substrate 22A Buffer layer 22B Buffer layer 23 Buffer layer 24 Mask film 25 Recess 26 Lower electron supply layer 27 Lower spacer layer 28 Channel layer 29 Upper spacer layer 30 Upper electron supply layer 31 Barrier layer 32 Cap layer 33 Source electrode 34 Drain Electrode 35 Gate electrode 36 2DEG

Claims (2)

The HEMT in which the two-dimensional electron gas generated in the channel layer having the electron supply layer formed on the lower side and the upper side is located at the center of the channel layer on the source side, and shifted up or down from the center of the channel layer on the drain side. A semiconductor device comprising: The semiconductor device according to claim 1, wherein the position of the two-dimensional electron gas generated in the channel layer is continuously shifted from the source side toward the drain side .

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