EP1459362A2

EP1459362A2 - Method for depositing iii-v semiconductor layers on a non-iii-v substrate

Info

Publication number: EP1459362A2
Application number: EP02790389A
Authority: EP
Inventors: Holger JÜRGENSEN; Alois Krost; Armin Dadgar
Original assignee: Aixtron SE
Current assignee: Aixtron SE
Priority date: 2001-12-21
Filing date: 2002-11-16
Publication date: 2004-09-22
Also published as: WO2003054929B1; WO2003054929A3; JP2006512748A; US7078318B2; US20050026392A1; AU2002366856A1; AU2002366856A8; WO2003054929A2; TWI265558B; TW200301515A

Abstract

The invention relates to a method for depositing thick III-V semiconductor layers on a non-III-V substrate, particularly a silicon substrate, by introducing gaseous starting materials into the process chamber of a reactor. The aim of the invention is to carry out the crystalline deposition of thick III-V semiconductor layers on a silicon substrate without the occurrence of unfavorable lattice distortions. To this end, the invention provides that a thin intermediate layer is deposited at a reduced growth temperature between two III-V layers.

Description

Process for the deposition of III-N semiconductor layers on a light III-V substrate.

The invention relates to a method for depositing III-V semiconductor layers, for example gallium arsenide, aluminum arsenide, gallium indium arsenide or gallium indium aluminum arsenide phosphide, on a light III-V substrate, for example silicon, by introducing gaseous starting materials into the process chamber of a reactor.

The III-V layers are deposited according to the invention in the MOCVD

Nerfahr in which, for example, TMG, TMI, TMA1, arsine, phosphine or ΝH _{3 are introduced} as starting materials into the heated process chamber of a reactor, where a substrate made of silicon lies on a substrate holder heated to the process temperature. In contrast to the deposition of gallium arsenide on gallium arsenide or indium phosphide on indium phosphide, mismatches occur when III-V layers are deposited on silicon substrates. Along with this, the grown layers have high defect densities.

On the other hand, silicon substrates have the advantage of being less expensive than III-V substrates and also suitable for integration into silicon component structures. One possibility of improving the layer quality is the deposition of thick semiconductor layers. However, this is limited by the thermal mismatch of the layers. These thermal mismatches lead to lattice tension and strong tension

Layer sequences. It can lead to cracks in the layers or mechanical bending.

Another problem is the combination of Ill-V layer structures or electronic components made from such layer structures with silicon Components on a substrate. In particular, it is desirable to combine optoelectronic III-V components with CMOS components on a substrate.

The invention is based on the object of crystalline deposition of thick III-V semiconductor layers on a silicon substrate without the disadvantageous lattice stresses occurring.

The invention is also based on the abe to combine on a Sustrat III-V components with silicon components.

The object is achieved by the invention specified in the claims, claim 1 initially and essentially aimed at depositing a thin intermediate layer between two III-V layers at a reduced growth temperature. The reduced growth temperature for the intermediate layer should, if possible, be at least 100 ° C. below the growth temperature for the III-V layers. It is further provided that the lattice constant of the intermediate layer is preferably smaller than the lattice constant of the III-V layers. In a preferred development of the invention it is provided that a multiplicity of intermediate layers, each separated by a III-V layer, is deposited. Multiple thin intermediate layers are thus deposited on one III-N layer each. The intermediate layer is preferably deposited untensioned. The intermediate layer can contain boron or silicon. The thickness of the intermediate layer is in the annometer range. The III-N layers deposited between the intermediate layers can be considerably thicker. They can be a few micrometers thick. There is preferably a seed layer between the silicon substrate and a first III-V layer, which can also consist of a III-V material. The III-V layer grows on the at low temperatures different intermediate layer on pseudomorph. This leads to tension. A compressive prestress is preferably achieved. The compressive pre-tension is achieved with the low-temperature intermediate layer.

The method according to the invention enables the growth of essentially unstressed III-V semiconductor layers in the system (AI, Ga, In) (As, PN, Sb) by the growth of low-temperature layers between III-V layers, the low temperature always showing a clear temperature , is at least 100 ° C below the usual growth temperature. The preferred compressive tension is created by the tensile stress during cooling. In the case of an indium phosphite system, this can be carried out by means of a GaAs, AlAs, AlInAs or GalnAlAsPN low-temperature layers. In the gallium arsenide system, aluminum arsenide, boron aluminum arsenide and also boron arsenite are considered as compressively tensioning low-temperature layers. However, it can also be used for materials in the nitridic system.

By repeatedly depositing such low-temperature intermediate layers, the thermal stress, but also the strain induced by lattice mismatch, can be reduced again and again to such an extent that layers of any thickness can be deposited, which are then essentially unstressed overall.

The second task mentioned at the outset is achieved by first depositing a III-V semiconductor layer on a non-III-V substrate, in particular on a silicon substrate, by introducing gaseous starting materials into the process chamber of a reactor. This III-V semiconductor layer is deposited on a first substrate which has an orientation which is optimized for the deposition of the III-V layer. For ab- A GaN layer is particularly suitable for a silicon substrate with an (III) orientation. In a next step, this semiconductor layer is detached from the substrate together with a thin film of the first substrate. The thickness of the detached film is, for example, 50 μm. In a further method step, the detached layer is applied to a second substrate together with the thin film of the first substrate. This second substrate can be a silicon substrate with a (100) orientation. The detached layer is preferably applied by gluing. A masking step can follow this bonding. According to the invention, it is provided that lateral areas of the applied layer are removed as far as the area of the second substrate. This removal is preferably done by etching. A layer sequence with silicon technology is then applied to the (100) silicon crystal which then forms the surface. These layers, which are adjacent to the III-V layer structures, can be insulation layers, electrically conductive layers or p- or n-doped silicon layers. The deposited III-N layer is preferably a gallium nitride layer.

In a first exemplary embodiment of the invention, a seed layer made of gallium arsenide is first deposited on a silicon substrate. A gallium arsenide buffer layer is deposited on this seed layer at the typical growth temperatures known in the literature for the deposition of high quality gallium arsenide layers in the MOCVD or VPE process or MBE. A low-temperature intermediate layer is then deposited on this first III-V layer. For this purpose, the temperature inside the process chamber, i.e. the substrate temperature, is reduced by at least 100 ° C. The gases required for the growth of the intermediate layer are then introduced into the process chamber. Trimethylaluminium nium and arsine or a boron compound. The intermediate layer is deposited at this reduced temperature until the desired layer thickness, which is between 5 and 50 nm, is reached. The layer thickness is preferably between 10 and 20 nm.

After the low-temperature intermediate layer has been deposited, the temperature inside the process chamber is raised again. This is done by heating the substrate holder accordingly. Then another gallium arsenide layer is pseudomorphically deposited on the low-temperature intermediate layer. This gallium arsenide layer is considerably thicker than the low-temperature intermediate layer. Their thickness can be a few μm.

In order to achieve particularly thick buffer layers, a further low-temperature intermediate layer can be deposited on the last described gallium arsenide layer, which also has a smaller lattice constant than gallium arsenide. Gallium arsenide can be deposited again on this intermediate layer. Overall, the process leads to a thick gallium arsenide layer with few dislocations.

In a second exemplary embodiment, the method for applying III-V layers in lateral proximity to IV structures is explained. Show it:

1 schematically shows in cross section a first substrate with an (Ιll) crystal orientation optimized for the deposition of a III-V layer,

2 shows the substrate with III-V layers deposited thereon, 3 shows the substrate with a III-V layer structure detached therefrom, together with a thin film of the first substrate,

4 shows the previously detached layer structure and

FIG. 5 shows an illustration according to FIG. 4 after a lateral structuring by etching.

A (III) silicon substrate is shown in regions and in cross section in FIG. 1. Two III-V layers 2, 3 are deposited on this silicon substrate (see FIG. 2) in the exemplary embodiment. These layers 2, 3 can be gallium arsenide, gallium nitride, indium phosphide or any other III-V composition.

This layer sequence 2, 3 is removed together with a thin film V of the first substrate 1. The detached layer system V, 2, 3 is then glued onto a second substrate (see FIG. 4). The second substrate is preferably a (100) silicon substrate. The (100) silicon surface is suitable for the deposition of further, in particular silicon

Optimized layers. In particular, this surface orientation is optimized for the deposition of CMOS structures.

In order to arrange such structures adjacent to the III-V layers, the intermediate product shown in FIG. 4 is structured laterally; this can be done, for example, by masking. Then the glued layer sequence Y, 2, 3 is etched away. This layer sequence is removed as far as into the second substrate 4, so that the exposed surface is in it etched area 5 is a (100) silicon surface on which CMOS structures can be deposited.

All of the features disclosed are (in themselves) essential to the invention. The disclosure content of the associated / attached priority documents (copy of the prior application) is hereby also included in full in the disclosure of the application, also for the purpose of including features of these documents in claims of the present application.

Claims

EXPECTATIONS

1. A method for depositing thick III-V semiconductor layers on a non-III-V substrate, in particular silicon substrate, by introducing gaseous starting materials into the process chamber of a reactor, characterized in that between two III-V layers thin interlayer is deposited at a reduced growth temperature.

2. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the growth temperature of the intermediate layer is at least 100 ° C lower than the growth layer of the III-V layers.

3. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the lattice constant of the intermediate layer is smaller than the lattice constant of the III-V layers.

4. The method according to one or more of the preceding claims or in particular according thereto, characterized in that several times a thin low-temperature intermediate layer is deposited on a III-V layer.

5. Verfaliren according to one or more of the preceding claims or in particular according thereto, characterized in that the intermediate layer is deposited without tension.

6. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the intermediate layer contains boron.

7. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the intermediate layer contains nitrogen.

8. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the intermediate layer has a thickness of 5-50 nm, preferably 10-20 nm.

9. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the MOCVD, VPE or MBE is used as the coating method.

10. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the thin intermediate layer is deposited in situ immediately after the first III-V layer and immediately before the second III-V layer.

11. The method according to one or more of the preceding claims or in particular according thereto, characterized in that the III-V layers and the thin intermediate layer are successively deposited in two or more processes.

12. The method according to one or more of the preceding claims or in particular according thereto, characterized in that on the thick III-V

Semiconductor layer component layer sequences are deposited.

13. The method according to one or more of the preceding claims or in particular according thereto, characterized in that components are produced from the component layer sequences.

14. A method for applying III-V semiconductor layers on a non-III-V substrate, in particular a silicon substrate, by introducing gaseous starting materials into the process chamber of a reactor, characterized in that the III-V layer on the surface of a first Substrate (1) with an orientation optimized for the deposition of the III-V layer (2, 3), in particular a (Hl) silicon substrate, the

Layer (2, 3) detached together with a thin film (1 ') of the first substrate (1), the detached layer (2, 3) together with the thin film (1') of the first substrate (1) on a second substrate (4), in particular applied to a (100) silicon substrate, and if necessary after a masking step, lateral regions (5) of the applied layer (2, 3) are removed into the second substrate (4).

15. The method according to claim 14 or in particular according thereto, characterized in that the layer (2, 3) detached together with the thin film (1 ') of the first substrate (1) is glued onto the second substrate (4).

16. The method according to claim 14 or 15 or in particular according thereto, characterized in that the III-V layer is a gallium nitride, gallium arsenide or indium phosphide layer.

17. The method according to one or more of the preceding claims 14 to 16 or in particular according thereto, characterized in that the areas (5) of the second one freed from the applied layer sequence (Y, 2, 3) Substrate (4) are coated with an insulation layer, an electrically conductive layer and / or a p- or n-doped layer.

18. The method according to one or more of the preceding claims 14 to 16 or in particular according thereto, characterized in that CMOS structures are applied to the exposed surface sections of the second substrate (4).