EP2659523A1 - Composite substrate, semiconductor chip having a composite substrate and method for producing composite substrates and semiconductor chips - Google Patents

Abstract

The invention relates to a composite substrate (1) having a carrier (2) and a useful layer (5), wherein the useful layer is fastened to the carrier (2) by means of a dielectric connecting layer (3) and the carrier (2) contains a radiation conversion material. The invention furthermore relates to a semiconductor chip (10) having such a composite substrate, a method for producing a composite substrate and also a method for producing a semiconductor chip having a composite substrate are specified.

Description

description

Composite substrate, composite substrate semiconductor chip and composite substrate manufacturing method and apparatus

Semiconductor chips

The present application relates to a composite substrate, a semiconductor chip with a composite substrate, and a method for producing composite substrates and of

Semiconductor chips.

This patent application claims the priority of German patent applications 10 2010 056 447.8 and 10 2011 012 298.2, the disclosure of which is hereby incorporated by reference.

White light sources based on optoelectronic

Semiconductor chips typically have a semiconductor chip provided for generating radiation and a

Radiation conversion material, which is intended to partially generate the radiation generated in the semiconductor chip

so as to radiate white radiation that appears white to the human eye.

This radiation conversion material is often embedded in a cladding of the semiconductor chip.

The comparatively low refractive index of the for

Potting material used makes difficult efficient coupling of the radiation conversion material to the

Semiconductor chip. One task is to specify an efficient and technically easy to implement type of radiation conversion.

Furthermore, a manufacturing method is to be specified with which radiation conversion for white light sources based on optoelectronic semiconductor chips can be achieved efficiently and cost-effectively.

 This object is achieved by a composite substrate or a method for producing a composite substrate according to the independent patent claims.

According to one embodiment, a composite substrate has a carrier and a wear layer, wherein the wear layer is fastened to the carrier by means of a dielectric connection layer. The carrier contains a

Radiation conversion material.

Such a composite substrate is particularly suitable for use as an epitaxial substrate, in particular for the production of optoelectronic semiconductor chips. A surface of the wear layer facing away from the wearer is

preferably provided as a deposition surface.

The carrier is preferably so thick that it is cantilevered and furthermore preferably mechanically stabilizes the material to be deposited on the carrier, in particular also at temperatures of, for example, 700 ° C. to 1100 ° C. used for epitaxy processes.

The proportion of the radiation of a first wavelength range radiated into the carrier into radiation of a second one different from the first wavelength range

Wavelength range is in particular by means of the efficiency of the excitation, the thickness of the carrier and / or the concentration of the radiation conversion material adjustable.

In a preferred embodiment, the carrier contains

Ceramic and / or a glass.

A carrier containing a ceramic is preferably formed largely by the radiation conversion material. For the most part means that the carrier the

Radiation conversion material to a volume fraction of at least 50%. Preferably, the carrier contains the radiation conversion material to a volume fraction of at least 75%, more preferably to a volume fraction of at least 90%. To increase the thickness of the carrier at the same conversion rate, the

 Radiation conversion material but also be formed to a lower volume fraction in the carrier.

The ceramic is preferably formed by particles which are connected to each other and / or with other particles to the ceramic.

As a radiation conversion material is particularly suitable material that can be connected by sintering to form a ceramic. For example, a garnet activated in particular with rare earth metals, for example Y 3 (Al, Ga) s O 12, for example activated with Ce, can be used.

For a carrier containing a glass, the glass is

preferably formed as a matrix material in which the radiation conversion material is embedded. The wear layer is expediently thinner than the carrier. The thinner the wear layer, the more cost effective the composite substrate can be made. The groove layer preferably has a thickness of at most 1 μm, preferably a thickness of between 10 nm and 500 nm inclusive, particularly preferably between 10 nm and 200 nm inclusive.

The wear layer contains, in a preferred embodiment, a material suitable for the deposition of nitridic

Compound semiconductor material is suitable.

"On nitride compound semiconductors" as used herein means that the active epitaxial layer sequence or at least one layer thereof is a nitride III / V compound semiconductor material, preferably Al _n Ga _m ini- _n - comprises _m N, where 0 <n < 1, 0 <m <1 and n + m <1. In this case, this material does not necessarily have to have a mathematically exact composition according to the above formula, but rather it may contain one or more dopants and additional dopants

Have components that are the characteristic

Physical properties of Al _n Ga _m ini- _n - _m N-change material does not substantially. For the sake of simplicity, however, the above formula contains only the essential constituents of the crystal lattice (Al, Ga, In, N), even if these may be partially replaced by small amounts of other substances.

The wear layer is preferably based on a nitridic compound semiconductor material. Such a wear layer is particularly suitable for the deposition of high-quality nitridic compound semiconductor material. In a preferred embodiment, only the dielectric connection layer between the wear layer and the carrier is arranged. In other words that's it

Radiation conversion material only by the dielectric compound layer of the wear layer spaced.

In a further preferred embodiment, the dielectric compound layer contains an oxide, for example silicon oxide, a nitride, for example silicon nitride or an oxynitride, for example silicon oxynitride. In the production, such a connecting layer is characterized by a particularly simple and stable connection of the groove layer with the carrier. For an oxynitride, the refractive index is adjustable over the material composition.

In a preferred embodiment, a refractive index of the dielectric bonding layer decreases from the wear layer toward the wearer. The decrease can be continuous or stepped. A variation of the material of the dielectric connection layer is particularly useful when the material having the higher refractive index used for the dielectric compound layer has a higher absorption coefficient than the material having the lower refractive index.

In a preferred embodiment, the borders

Connecting layer on at least one side to a

structured interface. In particular, a surface of the carrier facing the wear layer and / or a surface of the wear layer facing the wearer can have a surface

Have structuring. The structuring can

irregular, for example, as a roughening, or regularly, for example as a periodically recurring pattern to be formed. Furthermore, an optical element can be formed by means of structuring.

The composite substrate described is particularly suitable for the production of an optoelectronic semiconductor chip, in particular a LED chip, such as an LED. In a preferred embodiment, a semiconductor body, which has a semiconductor layer sequence with an active region provided for the generation of radiation, is arranged on the wear layer, wherein in operation in the active

Area generated radiation of a first wavelength range at least partially by means of

 Radiation conversion material in one of the first

Wavelength range different second wavelength range is converted.

In such a semiconductor chip so can the

Composite substrate in the production serve as an epitaxial substrate and the operation of the semiconductor chip integrated into the semiconductor chip

 Meet radiation conversion element. In other words, the semiconductor chips in the production even before their isolation from a semiconductor chip composite on the radiation conversion material.

On additional, later on the semiconductor chip

applied or placed in a potting of the semiconductor chip radiation conversion material can therefore

be waived.

Furthermore, the semiconductor chip is characterized by a

particularly good optical connection of the

Radiation conversion material to the active area, since between the radiation conversion material and the semiconductor material of the semiconductor chip only the

Dielectric connection layer of the composite substrate is arranged. Furthermore, the carrier can the

Mechanically stabilize semiconductor body, so that the semiconductor chip as a whole by a high mechanical

Stability distinguishes. Furthermore, the

Semiconductor chip due to the relatively high thermal conductivity of the carrier and / or the dielectric

Bonding layer by good heat dissipation properties. Preferably, the thickness of the carrier is finished

Asked semiconductor chip between 10 μπι inclusive and 200 μπι, more preferably between

including 20 μπι and 100 μπι, for example, 50 μπι.

In one embodiment variant, the carrier has a mirror layer on the side facing away from the semiconductor body. Such a semiconductor chip is preferably provided for mounting on the part of the mirror layer. Radiation emitted by the active region in the direction of the carrier can be reflected at the mirror layer and, in particular after at least one further pass through the carrier, can emerge on a radiation exit surface of the semiconductor chip facing away from the mirror layer.

In an alternative embodiment forms one of

Semiconductor layer sequence facing away from the main surface of the carrier, a radiation exit surface. Such a semiconductor chip is particularly suitable for mounting in flip-chip geometry.

In a method for producing a composite substrate having a support and a wear layer, according to In the form of a carrier provided, which contains a radiation conversion material. On the carrier is by means of a dielectric compound layer, the

Wear layer attached.

The attachment of the wear layer is preferably carried out by direct bonding. In contrast to adhesive bonding by means of an adhesive layer is for fastening no

Adhesion layer required. For example, the

Connection can be achieved directly by heat input and exerting pressure.

In a preferred embodiment, the wear layer is provided on an auxiliary carrier. After attachment to the carrier, the wear layer is detached from the rest of the subcarrier. The subcarrier is used for the preferred

epitaxial deposition of the material for the wear layer. After detachment of the subcarrier, this can be reused for further manufacturing steps.

In a preferred embodiment, separation wedges are formed before the attachment of the wear layer along which the wear layer is removed after fastening to the support. This can be achieved for example by implantation of ions, wherein the position of the separation nuclei and thus the thickness of the wear layer after detachment via the energy of the

introduced ions is adjustable.

The detachment is preferably carried out by heating the composite of carrier and auxiliary carrier.

In a method for producing a plurality of

Semiconductor chips according to an imple mentation form Composite substrate provided. On the composite substrate, a semiconductor layer sequence is deposited with an active region provided for generating radiation,

preferably epitaxially, for example by means of MBE or MOCVD.

The composite substrate with the semiconductor layer sequence is singulated into a plurality of semiconductor chips. The singulation can be done, for example, by means of coherent radiation, mechanically or chemically.

During production, the composite substrate mechanically stabilizes the semiconductor layer sequence. In the finished semiconductor chip, the composite substrate can remain completely or at least partially in the component and fulfill the function of a radiation conversion element.

In a preferred embodiment, the carrier is thinned after depositing the semiconductor layer sequence. to

mechanical stabilization during the epitaxial

Deposition of the semiconductor layer sequence, the carrier can therefore have a greater thickness than in the finished

Semiconductor chip. The thinning can be done before or after the singulation of the composite substrate.

The semiconductor chip is preferably already electrically contacted during thinning, so that the color location of the radiation emitted by the semiconductor chip, in particular for each semiconductor chip individually and separately,

is adjustable.

The described methods for producing a

Composite substrate or a plurality of

Semiconductor chips are for making one up composite substrate described or a

Semiconductor chips particularly suitable. Therefore, features described in connection with the composite substrate or the semiconductor chip can also be used for the production methods or vice versa.

Further features, embodiments and expediencies will become apparent from the following description of

Embodiments in conjunction with the figures.

Show it:

Figures 1A and 1B show a first and second embodiment, respectively, of a composite substrate in schematic section; Figures 2A to 2E an embodiment of a

Process for producing a composite substrate by means of a schematic sectional view

Intermediate steps; Figures 3A and 3B show an embodiment of a

A semiconductor chip with a composite substrate (Figure 3A) and a device having such a semiconductor chip (Figure 3B); FIGS. 4A and 4B show a second exemplary embodiment of a semiconductor chip with a composite substrate (FIG. 4A) and a component with such a semiconductor chip (FIG. 4B), each in a schematic sectional view; and FIGS. 5A to 5C show an exemplary embodiment of a method for producing a plurality of semiconductor chips schematically illustrated in sectional view

Intermediate steps.

The same, similar or equivalent elements are provided in the figures with the same reference numerals. The figures and the proportions of the elements shown in the figures with each other are not to scale

consider. Rather, individual elements may be exaggerated in size for better representability and / or better understanding.

A first exemplary embodiment of a composite substrate is shown schematically in a sectional view in FIG. 1A. The

Composite substrate 1 has a carrier 2 and a wear layer 5. Between the carrier and the wear layer is a

Dielectric connection layer 3 is arranged. One of the

Carrier 2 facing away from the wear layer is as a Abscheichtoberberfläche for epitaxial deposition

educated .

The carrier 2 comprises a radiation conversion material, for example a luminescent or phosphorescent material. The carrier may be formed as a ceramic, in which the radiation conversion material for producing the carrier in the form of phosphor particles is assembled into a ceramic, for example by sintering. to

Production of ceramics can be in addition to the

Radiation conversion material further particles and / or

Add additives. The additives can completely escape from the carrier during production or at least partially remain in the carrier. A ceramic-based support is preferably formed largely by the radiation conversion material.

Preferably, the carrier contains the

 Radiation conversion material to a volume fraction of at least 75%, more preferably of at least 90%.

A ceramic with a radiation conversion material and a method for producing such a ceramic is described in the document WO 2010/045915, whose

The disclosure content is hereby explicitly incorporated by reference into the present application.

As a radiation conversion material is particularly suitable with rare earth metals, such as Ce, garnet doped, for example, Y ₃ (Al, Ga) 5 O12.

Alternatively or additionally, the support may include at least one of rare earth activated alkaline earth sulfides, rare earth activated thiogallates, rare earth activated aluminates, and rare earth metals

Activated orthosilicates, rare earth activated chlorosilicates, rare earth activated metals alkaline earth silicon nitrides, metals of the

rare earth activated oxynitrides and rare earth activated aluminum oxynitrides, rare earth activated silicon nitrides.

Alternatively or additionally, the carrier may comprise a matrix material, for example a glass into which the

 Radiation conversion material is embedded. In this case, the radiation conversion material and the glass are

suitably adapted to each other so that the Radiation conversion material is not degraded or destroyed when introduced into the molten glass. Of the

Volume fraction of the radiation conversion material in this case is preferably between 5% inclusive and 30% inclusive.

The dielectric compound layer 3 preferably contains an oxide, for example silicon oxide, a nitride,

for example, silicon nitride, or an oxynitride,

for example, silicon oxynitride. For silicon oxynitride, the refractive index is adjustable by varying the nitrogen content between about 1.45 and 2.5, with the

Refractive index is higher, the greater the nitrogen content.

The composition of the dielectric connection layer 3 may be in the vertical direction, ie in a direction perpendicular to a main extension plane of the composite substrate 1

extending direction, vary. The dielectric connecting layer 3 preferably has a higher refractive index on the side facing the wear layer 5 than on the side facing the carrier 2. The refractive index may decrease continuously or stepwise toward the wearer.

For silicon oxynitride not only increases the refractive index, but also the increasing nitrogen content

Absorption coefficient. A dielectric tie layer with a decreasing nitrogen content to the wearer

distinguishes itself in comparison with a pure one

Silicon oxide layer through a better

Refractive index matching on semiconductor material and in the

Comparison with a pure silicon nitride layer by a lower absorption at the same thickness. The wear layer 5 is preferably designed such that it is suitable for the deposition of III-V

Compound semiconductor material is suitable. Preferably, the wear layer 5 is based on a nitridic

Compound semiconductor material. Deviating from this, however, the slot layer may also contain or consist of another material, in particular another semiconductor material such as, for example, silicon, silicon carbide, gallium phosphide or gallium arsenide, or consist of such a material.

The illustrated in Figure 1B second embodiment of a composite substrate substantially corresponds to the

Related to Figure 1A described first

Embodiment.

In contrast, the composite substrate 1 has a

Structuring 25, which is exemplified at an interface between the carrier 2 and the dielectric

Connecting layer 3 is formed. Alternatively or

In addition, an interface between the wear layer and the dielectric connection layer 3 can also be structured.

The structuring 25 can, for example, by means of a

Roughening be irregular. Also one

regular, especially periodic recurring

Structuring can be applied. The structuring is in particular intended to reduce the waveguide effects of radiation irradiated into the composite substrate 1 and / or radiation converted by means of the radiation conversion material. Alternatively or additionally, the structuring 25 can fulfill the function of an optical element, for example a lens or a diffraction grating. Farther the structuring and / or the optical element may alternatively or additionally also be formed on the side of the carrier 2 facing away from the wear layer 5.

FIGS. 2A to 2E show a first exemplary embodiment of the production of a composite substrate on the basis of FIG

shown schematically in section intermediate steps shown.

As shown in FIG. 2A, a semiconductor material 50 is provided on an auxiliary carrier 4. The auxiliary carrier 4 is used in particular for the epitaxial deposition of

Semiconductor material 50, for example by MBE or MOCVD.

In the semiconductor material 50, separation nuclei 51 are formed by implantation of ions, for example hydrogen ions (represented by arrows in FIG. 2B). The separating germs extend in a plane parallel to a surface facing away from the auxiliary carrier 4

Semiconductor material 50 extends. The energy of the ions determines the penetration depth of the ions into the ions

Semiconductor material and thus the thickness of the subsequently transmitted semiconductor material.

The thickness is preferably at most 1 μm, preferably between 10 nm and 500 nm inclusive, particularly preferably between 10 nm and 200 nm inclusive.

On the semiconductor material 50, a first dielectric sub-layer 31 is deposited, which in the finished Composite substrate a part of the dielectric

Connecting layer 3 represents.

The carrier 2 is provided with a second dielectric

Partial layer 32 coated. As illustrated in step 2D, the carrier 2 and the subcarrier 4 are positioned to each other such that the first dielectric sublayer 31 and the second dielectric sublayer 32 directly

adjoin one another. The dielectric sub-layers 31, 32 are by direct bonding, for example by

Compress at a temperature between 700 ° C and 1200 ° C, connected together and together form the dielectric connection layer 3. An adhesion layer such as an adhesive layer or a solder layer is for the

Preparation of the connection is not required.

After establishing the direct bond, the subcarrier 4 is detached with a portion of the semiconductor material 50 along the separation nuclei. This is preferably thermally induced. The remaining on the carrier 2

Semiconductor material forms the wear layer 5 of

Composite Substrate 1 (FIG. 2E). The subcarrier, after peeling, may be used to make additional composite substrates

be reused.

Deviating from the exemplary embodiment described, it is also conceivable that the semiconductor material 50 for the useful layer 5 originates directly from the auxiliary carrier 4. The epitaxial

Deposition on the submount is not required in this case.

A first exemplary embodiment of a semiconductor chip is shown in a schematic sectional view in FIG. 3A. Of the Semiconductor chip 10 has, by way of example, a composite substrate 1 which is as described in connection with FIG. 1A

is executed.

On the composite substrate 1, a semiconductor body 7 with a semiconductor layer sequence 700 is arranged. The

Semiconductor layer sequence, which forms the semiconductor body, has an active region 70, which is arranged between a first semiconductor layer 71 and a second semiconductor layer 72. The first semiconductor layer 71 and the second semiconductor layer 72 are expediently different from each other in terms of their conductivity type. For example, the first semiconductor layer 71 may be n-type and the second

Semiconductor layer 72 may be p-type or

vice versa .

The first semiconductor layer 71 and the second

 Semiconductor layer 72 are each electrically connected to a first contact 81 and a second contact 82. The contacts 81, 82 are provided for external electrical contacting of the semiconductor chip 10. During operation of the semiconductor chip 10, charge carriers from different sides can be injected into the active region 70 via the contacts and recombine there with emission of radiation of a first wavelength range.

The radiation of the first wavelength range is in

Composite substrate 1, in particular in the carrier 2, partially converted into radiation of a second wavelength range different from the first wavelength range.

For example, the active region 70 for generating radiation in the blue spectral range and the Radiation conversion material in the carrier 2 to

Radiation conversion can be provided in radiation in the yellow spectral range, so that emerges from the semiconductor chip 10 for the human eye appearing white mixed light. The radiation conversion thus already takes place in the semiconductor chip itself. In contrast to a component in which

Radiation conversion material is embedded in a cladding or in which a radiation conversion element is attached to the semiconductor chip by means of an adhesion layer, the radiation does not pass through prior to the radiation conversion material with a relatively low refractive index, such as silicone. Because of the high refractive indices of the dielectric connecting layer 3, which separates the radiation conversion material of the carrier 2 from the semiconductor material of the semiconductor chip 10, the radiation conversion material is optically particularly efficiently bonded to the semiconductor material. Furthermore, the

thermal resistance through the dielectric

Compound layer compared to a semiconductor chip, to which by means of an adhesion layer, a conversion element is attached, reduced. For example, the

Heat conduction of a 250 nm thick dielectric

Connection layer 3 of silicon oxide about ten times as high as in a silicone layer with 1 μπι thickness.

An exemplary embodiment of a radiation-emitting

Component 100 with such a semiconductor chip is shown schematically in sectional view in FIG. 3B. Of the

Semiconductor chip 10 is attached to a connection carrier 9. The first contact 81 and the second contact 82 are in each case electrically conductive with a first connection surface 91 or a second connection surface 92

Connected connection carrier. The connection carrier 9 may be, for example, a printed circuit board, in particular a printed circuit board (PCB), an intermediate carrier (submount), for example a ceramic carrier, or a housing body for a

in particular be surface mountable component.

In particular, the first connection surface 91 and the second connection surface 92 may be formed by a leadframe.

The semiconductor chip 10 is in an encapsulation 95

embedded. The encapsulation is expediently transparent or at least translucent for the radiation emitted by the semiconductor chip 10. In particular, the encapsulation may be free of radiation conversion material, since this is already contained in the carrier 2 of the composite substrate 1. For the encapsulation is particularly suitable a silicone, an epoxy or a hybrid material with a silicone and an epoxy.

Alternatively, however, in addition to the

 Radiation conversion material in the carrier 2 another

Radiation conversion material and / or diffuser material contained in the encapsulation. The further

Radiation conversion material can in particular for

Tuning of the color locus of the radiation emitter

Component 100 may be provided radiated radiation.

The semiconductor chip 10 is arranged in flip-chip geometry on the connection carrier 9, that is to say that the composite substrate 1 is arranged on the side of the semiconductor layer sequence 7 facing away from the connection carrier 9. In operation of the

Semiconductor chips, the carrier 2 thus forms a top side, thus facing away from the connection carrier,

Radiation exit surface of the semiconductor chip 10th

In contrast to a thin-film semiconductor chip in which the growth substrate is removed, the composite substrate remains completely or at least partially in the semiconductor chip. The carrier 2 can thus the semiconductor body 7 mechanically

stabilize, reducing the risk of breakage.

The thickness of the carrier 2 is preferably between

including 10 μπι and including 200 μπι, more preferably between 20 μπι inclusive and 100 μπι, for example, 50 μπι. During the epitaxial

Deposition of the semiconductor layer sequence, the carrier may also have a greater thickness. The risk of bending the carrier at the comparatively high temperatures for epitaxial deposition can thus be reduced. A thick support is thinned after deposition to said thickness. About the thickness of the color of the radiated from the finished semiconductor chips radiation is adjustable.

In the manufacture of the device 100 may before the

Forming the encapsulation of the semiconductor chip 10 to

Determination of the color locus of the emitted radiation

be contacted electrically. To adapt the color locus, in particular to reduce the proportion of the radiation converted in the carrier 2, the carrier can be thinned, for example mechanically, for example by means of grinding, lapping or polishing or chemically, for example wet-chemically or

dry chemical or by material removal by coherent radiation, such as laser radiation. Thus, in particular also separately for each individual semiconductor chip, the color locus of be adjusted individually emitted by the semiconductor chip radiation. If necessary, the

Semiconductor chip also be provided for adjusting the color locus with a coating, which also

Radiation conversion material may contain.

The second exemplary embodiment for a semiconductor chip 10 shown in FIG. 4A essentially corresponds to the first embodiment described in connection with FIG. 3A

Embodiment. In contrast, on the side facing away from the semiconductor body 7 side of the composite substrate 1, a mirror layer 96 is formed, which is intended to reflect the radiation generated in the active region 70 radiation. The preferably metallic mirror layer 96 has

expediently for the generated in the active region 70 and / or in the carrier 2 by means of

 Radiation conversion material converted radiation to a high reflectivity. In the visible spectral range, for example, aluminum or silver is suitable.

Further, unlike the first embodiment, on the second semiconductor layer 72 is a

radiation-permeable contact layer 821 is formed, via which the charge carriers injected into the second contact 82 can be impressed over a large area and uniformly into the second semiconductor layer 72.

The radiation-transmissive contact layer 821 contains

preferably a transparent conductive oxide (TCO), for example indium tin oxide (ITO) or zinc oxide (ZnO). Alternatively or additionally, the radiation-transmissive contact layer may be a metal layer that is so thin that they are suitable for the

Semiconductor chip generated radiation is permeable.

As shown in Figure 4B, such is suitable

Semiconductor chip, in particular for a mounting, in which the mirror layer 96 faces the connection carrier 9.

The electrically conductive connection of the contacts 81, 82 with the pads 91, 92 can be made via connecting conductors 97, for example via wire bonds.

An exemplary embodiment of a method for producing a semiconductor chip is shown in FIGS. 5A to 5C

schematically illustrated by intermediate steps.

As shown in FIG. 5A, a composite substrate having a support 2 containing radiation conversion material, a dielectric connection layer 3 and a wear layer 5 is provided.

For the sake of simplicity, an area of the

Compound substrate 1 shown in the figures, from which in the production of the semiconductor chips, two semiconductor chips

emerge, the method being exemplary of

Semiconductor chips is described, which are carried out as described in connection with Figure 4A.

On the wear layer 5 of the composite substrate 1 is

epitaxially, for instance by means of MBE or MOCVD

Semiconductor layer sequence with a first semiconductor layer 71, an active region and a second semiconductor layer 72 deposited (Figure 5B). Unlike one

Adhesion layer such as an adhesive layer or a solder layer keeps the dielectric compound layer the typical Temperatures at the epitaxy, for example, between 700 ° C and 1100 ° C stood, so that the carrier 2 the

 Semiconductor layer sequence during deposition can stabilize mechanically.

To form the first contact 81, the first

Semiconductor layer 71 partially exposed. This can be carried out in particular chemically, for example wet-chemically or dry-chemically.

The deposition of the contacts 81, 82 and the

radiation-permeable contact layer and the mirror layer 96 is preferably carried out by means of vapor deposition or

Sputtering.

Subsequently, a singulation in semiconductor chips, for example by means of laser radiation, mechanically, for example by means of sawing or chemically, for example by means of wet-chemical or dry chemical etching.

In the described method, therefore, the epitaxial deposition of the semiconductor layers takes place on a

Composite substrate that already has the

Radiation conversion material contains.

When singulating in semiconductor chips so go

Semiconductor chips that already have the

Radiation conversion material included.

The invention is not limited by the description with reference to the embodiments. Rather, the includes

Invention every new feature as well as every combination of

Characteristics, which in particular any combination of features in The patent claims, even if this feature or this combination itself is not explicitly in the

Claims or the embodiments is given.

Claims

claims

1. Composite substrate (1) with a support (2) and with a wear layer (5) by means of a dielectric

Connecting layer (3) is attached to the carrier, wherein the composite substrate (1) is a radiation conversion material

contains.

2. Composite substrate according to claim 1,

in which the wear layer is a nitridic

Contains compound semiconductor material.

3. Composite substrate according to claim 1 or 2,

in which the wear layer has a thickness of at most 1 μπι.

A composite substrate according to any one of the preceding claims, wherein the dielectric compound layer contains an oxide, a nitride or an oxynitride.

5. Composite substrate according to one of the preceding claims, wherein a refractive index of the dielectric

Connecting layer of the wear layer in the direction of

Carrier decreases.

6. Composite substrate according to one of the preceding claims, in which the connection layer adjoins at least one side to an interface with a structuring (25).

7. A semiconductor chip with a composite substrate according to one of claims 1 to 6,

in which on the wear layer, a semiconductor body (7) with a provided for generating radiation active Region (70) is arranged, wherein the radiation generated during operation at least partially by means of

Radiation conversion material is converted.

8. Semiconductor chip according to claim 7,

in which the carrier has a mirror layer (96) on the side facing away from the semiconductor layer sequence.

9. semiconductor chip according to claim 7,

in which a main surface of the carrier facing away from the semiconductor body forms a radiation exit surface.

10. A method for producing a composite substrate (1) with a carrier (2) and a wear layer (5), comprising the steps of: providing the carrier (2), the one

Radiation conversion material contains; and

 - Fixing the wear layer (5) on the support (2) by means of a dielectric compound layer (3).

11. The method according to claim 10,

in which the wear layer is attached to the support by direct bonding

12. The method according to claim 10 or 11,

in which the wear layer is on a subcarrier (4)

is provided and the wear layer is detached after attachment to the carrier of the remaining subcarrier.

13. The method according to claim 12,

in which before the attachment of the wear layer separating bacteria (51) are formed, along which the wear layer is detached after attachment to the carrier.

14. A method for producing a plurality of semiconductor chips (10) comprising the steps of: a) providing a composite substrate according to one of

Claims 1 to 6;

b) depositing a semiconductor layer sequence (700) having an active region provided for generating radiation on the composite substrate; and

c) separating the composite substrate with the

Semiconductor layer sequence in a plurality of

Semiconductor chips.

15. The method according to claim 14,

in which the carrier is thinned after step b).