The present invention relates to a method of manufacturing a semiconductor device composed of a p-channel transistor and protecting element by using a compound semiconductor of such as GaAs. More particularly, the present invention relates to a method of manufacturing a semiconductor device by which a p-channel transistor has a configuration of a junction transistor formed with a simple manufacturing process and a protecting element can be made in the fabricated manufacturing process as that of the p-channel transistor.
To lower electric usage of an integrated circuit, a CMOS (complementary circuit) has been used in an integrated circuit using Si. In a microwave device, on the other hand, a compound semiconductor of such as GaAs has been used in place of Si since such semiconductor is excellent for use in high frequencies and high speed use due to high mobility of electrons. Integrated circuits using such compound semiconductor have been put in practical use and the use of a complementary transistor in a circuit using a compound semiconductor has been considered in view of lower electric usage. For this purpose, a p-channel transistor with holes that are typically inferior in movability to electrons is also required.
As for such transistor (hereinafter also referred to as FET), an MESFET using a junction FET or heterojunction as shown in
For example, as shown by an example in
The configuration shown in
As described above, to form a junction FET, it is required to selectively epitaxially grow the n+-type semiconductor layer 54 or selectively diffusing the n+-type diffusion region 58 on the p-type channel layer 52 to form a p-n junction between the gate electrode and channel layer. In particular for the case of a composition semiconductor of such as GaAs, the temperature of epitaxy is approximately 600° C. and the temperature of selective growth or selective diffusion needs to be lower than that of the growth temperature. If not the case, there is a problem that characteristics degrade by the variability in impurity concentrations or the thickness of an impurity layer of a semiconductor layer such as a channel layer to which epitaxy has already performed. Thus selective growth and diffusion need to be performed at a lower temperature and highly advanced technique is required. In view of mass production, there are problems that the production process is costly due to the production complexity and yield decreases due to the lack of reproductivity and stability.
Furthermore, although it is possible to perform enhanced operation in MESFETs, in a composition semiconductor of such as GaAs, there is no electrode material available for performing a Schottky junction with high barrier height (potential barrier). Thus there is a problem that an operating voltage range cannot be increased by forward voltage Vf with high gate voltage. Moreover, since a p-channel FET needs to be protected from ESD (electrostatic) stress, a protecting element needs to be included. Such protecting element is desirably fabricated without increasing manufacturing processes as much as possible.
The present invention is provided in view of the above-mentioned problems. The present invention provides a method of manufacturing a semiconductor device including a p-channel FET and a protecting element by which a junction FET is manufactured in a simple manufacturing process and the protecting element can be made in the same manufacturing process as that of the junction FET.
A method of manufacturing a semiconductor device according to the present invention comprises steps of forming a semiconductor laminate portion by successively growing a p-type channel layer for a p-channel transistor and a p-type contact layer over an n-type contact layer provided on a substrate, exposing the n-type contact layer by etching the semiconductor laminate portion in a region of a semiconductor circuit element while leaving the semiconductor laminate portion in a region where the p-channel transistor is formed and in a region where the protecting element is formed, exposing the n-type contact layer by etching the semiconductor laminate portion in a portion of the p-channel transistor region, and exposing the n-type contact layer by etching a portion of the semiconductor laminate portion in a portion of the protecting element region so as to form an electrode or etching the semiconductor laminate portion so as to form two p-n junctions which are coupled by the n-type contact layer, forming a gate electrode in a region where the p-channel transistor is formed so as to form an ohmic contact with a surface of the n-type contact layer which is exposed by the etching, and forming a source/drain electrode on the p-type contact layer remaining on both sides in the channel region of the p-channel transistor region and forming at least one electrode for the protecting element on a surface of the p-type contact layer.
By providing an etch stop layer between the p-type channel layer and the p-type contact layer, only the p-type contact layer is formed on the p-type channel layer without damaging the channel region of the p-type channel layer while keeping a uniform thickness thereof.
According to the present invention, a p-type channel layer for a p-channel FET and a p-type contact layer are laminated on an n-type semiconductor layer, and an n-type semiconductor layer, which is located below the channel layer, is used as a conductive layer which is different from the channel layer for forming a p-n junction between a gate electrode and channel layer of the junction FET. Thus, a junction FET can be formed, without performing selective epitaxy or selective diffusion, by forming a gate electrode on the surface of an n-type semiconductor layer which is exposed by etching. A protecting element is formed by the p-n junction of the semiconductor laminating portion which is laminated on the n-type semiconductor layer. Therefore, a protecting element with a p-n junction can be formed only by performing patterning in regions which is different from the junction FET in the semiconductor laminated configuration with the same junction FET. As a result, in the case of forming a circuit element of such as an n-channel FET for forming a complementary circuit, such element can be formed in a layer which is located below the n-type semiconductor layer by forming an n-channel layer below the n-type semiconductor layer, for example. Therefore, a p-channel FET for a complementary FET and protecting element can be formed in a highly simple manufacturing process.
a) is a sectional explanation view of steps showing one Embodiment according to the manufacturing method of the present invention;
b) is a sectional explanation view of steps showing one Embodiment according to the manufacturing method of the present invention;
c) is a sectional explanation view of steps showing one Embodiment according to the manufacturing method of the present invention;
d) is a sectional explanation view of steps showing one Embodiment according to the manufacturing method of the present invention;
e) is a sectional explanation view of steps showing one Embodiment according to the manufacturing method of the present invention;
a) is the I-V characteristics of the p-channel obtained by Embodiment shown in
b) is the I-V characteristics of the p-channel obtained by Embodiment shown in
c) is the I-V characteristics of the p-channel obtained by Embodiment shown in
d) is the I-V characteristics of the p-channel obtained by Embodiment shown in
a) is a sectional explanation view showing an example of a conventional junction FET; and
b) is a sectional explanation view showing an example of a conventional junction FET.
A method of manufacturing a semiconductor device according to the present invention is described by referring to the drawings. The manufacturing method of a semiconductor device according to the present invention is a manufacturing method of a semiconductor device comprising a compound semiconductor and having a p-channel FET 22 and protecting element 23 thereof.
As shown in
The substrate 1 is formed by using such as a semi-insulating GaAs substrate. Each of semiconductor layers of the semiconductor laminate portion 10 is also formed by using a compound semiconductor of such as GaAs so as to form a circuit element having large electron mobility and a high characteristic relative to microwave. In this case, the first and second etch stop layers 4, 8 are provided for providing different etching rates from that of the semiconductor layer consisting of GaAs, and may be formed to have a thickness of 3 to 10 nm by using AlGaAs compound, AlAs or InGaP compound.
The n+-type contact layer 3 is provided for forming an ohmic contact with electrode metal and is provided for forming a p-n junction of the junction FET in the case the n+-type semiconductor layer 5 is not provided. The n+-type contact layer 3 is formed as a layer with a high impurity concentration of approximately 5×1018 cm−3, for example. In the case the first etch stop layer 4 is provided, it is formed to have an impurity concentration which is approximately the same as those of the previous/subsequent layers of such as the n+-type contact layer 3 and n+-type semiconductor layer 5. The n+-type semiconductor layer 5 may be formed to have the same impurity concentration as that of the n+-type contact layer 3 or may have a different impurity concentration. By providing the n+-type semiconductor layer 5, the pressure resistance of the protecting element 23 may be increased. In the example shown in
In this example, the p-channel junction FET 22 performs the enhanced operation (enhancement; E mode) such that the p-type channel layer 7 is formed to have an impurity concentration and a thickness at which the p-channel closes when the gate voltage is 0. The p-type channel layer 7 is formed to have an impurity concentration of approximately 1×1017 to 5×1018 cm−3 (5×1017 cm−3, for example) and a thickness of approximately 20 to 100 nm. The p+-type contact layer 9 is provided for forming an ohmic contact between a source/drain electrode 16 as described below and the p-type channel layer 7 and is formed to have a thickness of 30 nm or more by doping carbon, for example, so as to have a sufficient high concentration of approximately 1×1019 cm−3 or more (3×1019 cm−3, for example).
As shown in
As shown in
As shown in
As shown in
As described above, the semiconductor device having the complementary circuit formed by the n-channel FET 21 and p-channel FET 22 and the protecting element 23 as shown in
The I-V characteristics of the p-channel FET 22 (with a gate width of 100 nm) of semiconductor device manufactured according to the configuration shown in
As described above, a junction FET can be fabricated by the simple manufacturing process without performing selective epitaxy and selective diffusion. Therefore, a protecting element with a p-n junction can be obtained in the same manufacturing process as that of a p-channel FET. Furthermore, when an enhancement type complementary circuit is configured, the manufacturing process is significantly simple and a semiconductor device with a highly large operating voltage range can be obtained.
Though an embodiment of the present invention is described above, it is to be understood that the present invention is not limited only to the above-mentioned, various changes and modifications may be made in the invention without departing from the sprit and scope thereof.