DE102014116276A1 - An epitaxial wafer, device and method of making an epitaxial wafer and a device - Google Patents

Abstract

The invention relates to a component and a method for producing a component, the method comprising the following steps:
Forming or providing an epitaxial wafer comprising a substrate and a release layer disposed on the substrate, the release layer having a plurality of columnar structures of a semiconductor material,
Forming a layer sequence with an active layer on the epitaxial wafer; and
Removing the substrate from the layer sequence at the separating layer by at least partially destroying the columnar structures.
Furthermore, an epitaxial wafer is specified which is particularly suitable for the production of the component.

Description

An epitaxial wafer, a device and methods for producing an epitaxial wafer and a component are specified.

To produce a semiconductor component with a semiconductor body which is free of a growth substrate, the growth substrate can be separated from the semiconductor body by means of a laser lift-off method. However, the laser lift-off method is suitable only for certain types of growth substrate. In alternative methods of separating the growth substrate, it is often not possible to reuse the growth substrate. For example, a controlled gap method can be used for separating the growth substrate, in which the growth substrate is selectively separated from the semiconductor body by mechanical influences at various points. However, the growth substrate is often damaged, so that a reuse of the growth substrate is no longer possible.

An object is to provide a simplified, reliable and inexpensive method of manufacturing semiconductor devices in which a growth substrate is recyclable. As further objects an epitaxial wafer with a reusable growth substrate as well as a component produced in particular with such an epitaxial wafer should be specified.

In accordance with at least one embodiment of a method for producing a component, an epitaxial wafer is formed or provided. In particular, the epitaxial wafer has a substrate and a separating layer arranged on the substrate. The separation layer has, for example, a plurality of columnar structures made of a semiconductor material, for example.

The substrate has a main surface facing the separating layer, which is particularly flat. This means in particular that the main surface has no curvatures, elevations or depressions within the scope of the manufacturing tolerances.

A column-like structure of the separating layer is understood as meaning a structure which has a cross-section laterally extended to the main surface of the substrate and a height directed vertically to the main surface. A lateral direction is understood to mean a direction which is directed in particular parallel to the main surface of the substrate. The vertical direction is directed perpendicular to the main surface and is thus perpendicular to the lateral direction. A border of the cross section may take on any shape, for example, curved, approximately circular, elliptical or oval, or polygonal, approximately square or hexagonal. In particular, the cross section of the columnar structure remains substantially constant along the direction of the height, that is, along the vertical direction. Substantially constant means that the shape of the cross section does not change in particular. In this case, a ratio of a minimum cross-section to a maximum cross-section of the columnar structure may be between 0.4 and 1 inclusive, for example between 0.6 and 1 or 0.8 and 1 inclusive inclusive. An aspect ratio of the height to the maximum extent of the cross section of the columnar structure is arranged so that the columnar structure has sufficient mechanical stability in the normal state in the manufacture of the device. For example, the aspect ratio is between 0.1 and 10, such as between 0.5 and 5 or between 1 and 5. For example, the columnar structure has a lateral width which is the maximum lateral extent of the cross section, the vertical height being greater than the lateral width is.

The columnar structures may have different sized cross sections. In particular, the columnar structures may be arranged regularly or irregularly on the substrate. In particular, the substrate is not completely covered by the columnar structures, but between the columnar structures are uncovered areas of the substrate.

The separating layer has in particular a semiconductor material or consists of this. For example, the semiconductor material is a III-V or II-VI semiconductor material. In particular, a material of the substrate and a material of the separation layer are chosen so that a remote crystallographic order is maintained within the epitaxial wafer from the substrate and the release layer. By maintaining the crystallographic long-range order, the columnar structures can be overgrown in a simple manner with a semiconductor layer or a layer sequence, whereby lattice defects within the semiconductor layer or layer sequence applied to the epitaxial wafer can be largely avoided.

In accordance with at least one embodiment of the method, a layer sequence is formed on the epitaxial wafer. The layer sequence contains in particular a plurality of semiconductor layers. In particular, the layer sequence and the separation layer exclusively comprise semiconductor layers. By way of example, the layer sequence has an active layer which, for example, emits electromagnetic radiation during operation of the component. Alternatively, the active layer may be so be configured such that it absorbs electromagnetic radiation during operation of the device and converts this into electrical signals or electrical energy. The layer sequence may also have multiple semiconductor layers of different types of charge carriers. In particular, the layer sequence is applied in layers on the epitaxial wafer by means of an epitaxy process.

In accordance with at least one embodiment of the method, the substrate is removed from the layer sequence at the separating layer, wherein the columnar structures are at least partially destroyed during the separation of the substrate. In particular, the columnar structures of the separation layer for the separation of the substrate are broken by lateral mechanical forces, such as by applying a shearing force.

In at least one embodiment of a method for producing a component, an epitaxial wafer is formed or provided. The epitaxial wafer has a substrate and a release layer disposed on the substrate. The separation layer has a plurality of columnar structures of a semiconductor material. A layer sequence, for example a semiconductor layer sequence, with an active layer is formed on the epitaxial wafer. The substrate is removed from the layer sequence at the separating layer, whereby the columnar structures are at least partially destroyed during the removal of the substrate.

The columnar structures contribute to the fact that the substrate and the layer sequence can be separated from one another in a non-destructive manner in a simplified and reliable manner by a mechanical separation process with regard to the substrate and the layer sequence. A separation process merely by means of external mechanical force effects can be used independently of the material selection of the substrate used. The non-destructive peeled substrate can also be reused, reducing the cost of manufacturing the devices.

In accordance with at least one embodiment of the method, the layer sequence is applied directly on the epitaxial wafer. The layer sequence can be applied directly to the columnar structures of the separation layer. In particular, the layer sequence after application has a transition layer facing the columnar structures, which completely covers the columnar structures in a plan view of the substrate. In this case, the transition layer and further layers of the layer sequence are applied in layers in a same process step, for example by means of an epitaxy process. Alternatively, it is also possible for the transition layer and the further layers of the layer sequence to be produced in separate process steps. In this case, the epitaxial wafer can be provided prefabricated in the manufacture of the device, wherein the prefabricated epitaxial wafer has the transition layer, which is formed for example by a lateral overgrowth over the columnar structures and is present as a coherent semiconductor layer. In particular, a material of the transition layer is chosen so that the remote crystallographic order is maintained within the epitaxial wafer with the substrate, the release layer, and the transition layer.

In accordance with at least one embodiment of the method, in the case of the formation of the epitaxial wafer, the separating layer is first applied flatly to the substrate. To form the columnar structures, the separating layer is subsequently structured. In this case, separating layer after structuring may have a base layer facing the substrate with columnar structures arranged thereon. By way of derogation, it is also possible for the columnar structures to be applied to the substrate in a structured manner, for example by a mask. Such a mask may be prefabricated or be formed by marking the substrate, for example, with an oxide layer, wherein the columnar structures can be grown on non-labeled areas of the substrate, for example by an epitaxial process.

In accordance with at least one embodiment for producing a plurality of components, the layer sequence is fastened to a carrier composite prior to removal from the substrate. After removal of the substrate, the carrier assembly and the layer sequence for separating the plurality of components can be singulated so that the separated components each have a carrier from the carrier composite and an associated layer sequence.

In accordance with at least one embodiment of the method, at least one trench is formed through the layer sequence, in particular before the layer sequence is attached to the carrier assembly. The substrate is then removed from the layer sequence so that the trench is exposed in particular. Subsequently, the carrier assembly can be singulated for singling the plurality of components along the trench.

The trench thus serves as a dividing line between the layer sequences of the components to be produced. For example, you can saw along the trench. It is also possible that the at least one trench is formed such that it extends through the separating layer to the substrate. Also, a plurality of trenches can be formed. In particular, the trenches can be formed so that the layer sequences of the components to be produced are respectively surrounded by the trenches and thus present on the common carrier composite laterally spaced apart. This means that the size of the components to be produced can already be determined by the formation of the trenches. The separation of the carrier composite along the trenches can be designed in a simplified and reliable manner with high yield.

In accordance with at least one embodiment of the method, the substrate is mechanically separated from the layer sequence. This can be done in particular by applying a shearing force, for example by lateral mechanical force effects, whereby the columnar structures are at least partially or completely broken. As a result, the substrate can be separated from the layer sequence in a non-destructive manner and thus reused.

To further simplify the separation of the substrate by mechanical force actions, the columnar structures may be formed on the substrate so that a distribution density of the columnar structure varies depending on a distance from an edge of the substrate. By way of example, distances of adjacent columnar structures from a first edge of the substrate to a first edge facing the first or to a central region of the substrate may vary at least in regions. Spaces of adjacent columnar structures mean lateral distances between columnar structures that are in particular immediately adjacent to each other. A central region of the substrate is understood to mean a region which is arranged, for example, around a geometric center or about a center of mass of the substrate, wherein a surface of the central region is in particular at most 30%, approximately at most 20% or at most 10%, of an overall surface of the main surface of the substrate.

According to at least one embodiment of the method, the columnar structures each have a cross section whose maximum lateral extent is smaller than a distance from the associated columnar structure to its immediately adjacent columnar structure or adjacent columnar structures. By such a design of the columnar structures, the separation of the substrate from the layer sequence by lateral mechanical force effects is particularly simplified.

In accordance with at least one embodiment of the method, an etching agent is fed into the at least one trench or into the plurality of trenches for the separation of the substrate so that the etchant partially etches away the columnar structures. Subsequently, the substrate can be completely removed by lateral force effects of the layer sequence. It is also possible for the amount or concentration of the etchant to be chosen so that the substrate is completely separated from the layer sequence solely on account of the etching process, whereby a separation process due to mechanical force effects can be dispensed with.

In accordance with at least one embodiment of the method, the separating layer contains a sacrificial layer and a further layer, wherein the sacrificial layer is arranged between the substrate and the further layer. For example, the sacrificial layer comprises a material that is more susceptible to etching than a material of the further layer. The sacrificial layer and the further layer of the separation layer are patterned or structured on the substrate, so that the columnar structures are each formed a first region of the sacrificial layer and a second region of the further layer. Due to the sacrificial material of the sacrificial layer, the columnar structures are etched when supplying an etchant predominantly or exclusively at the sacrificial layer. As an alternative or in addition to the separation of the substrate by lateral mechanical force effects, the columnar structures can thus be etched completely or partially on the sacrificial layer.

In at least one embodiment of an epitaxial wafer, it has a substrate, a release layer and in particular a transition layer. The transition layer and the separation layer are, for example, semiconductor layers, wherein the separation layer is arranged between the substrate and the transition layer. The separation layer has a plurality of column-like structures made of, for example, a semiconductor material, wherein the columnar structures for separating the substrate from the transition layer are made breakable by a mechanical separation method, such as by lateral mechanical force effects.

Such an epitaxial wafer is particularly suitable for the method described above. The features disclosed in connection with the method described above can therefore also be used for the epitaxial wafer or vice versa.

In accordance with at least one embodiment of the epitaxial wafer, there is a crystallographic long-range order within the entire epitaxial wafer maintained within the manufacturing tolerances. The separation layer and the transition layer can have the same semiconductor material. Deviating from this, they can also have different materials, which are chosen in particular such that the crystallographic long-range order of the substrate over the separating layer in the transition layer is maintained, in particular within the manufacturing tolerances.

In at least one embodiment of a component, this has a carrier and a layer sequence arranged on the carrier with an active layer. The component is in particular free of a growth substrate.

In particular, the device is manufactured with an epitaxial wafer described above. The device is free of the substrate of the epitaxial wafer. In particular, the component has a support, facing away from the support, in particular an exposed surface with partially removed columnar structures made of a semiconductor material, for example. Under partially removed columnar structures are understood columnar structures having, for example, separation marks. The separation traces can emerge from an etching process or from a mechanical separation process.

In accordance with at least one embodiment of the component, the active layer emits an electromagnetic radiation during operation of the component, in particular in the ultraviolet, visible or in the infrared spectral range. Alternatively, the active layer can be designed so that it absorbs electromagnetic radiation during operation of the component and converts the radiation into electrical energy or electrical signals. The partially removed columnar structures can serve as coupling-out structures of the component.

Deviating from the surface with the partially removed columnar structures, the carrier facing away, in particular exposed surface of the device may be formed by a surface of the transition layer. The surface of the transition layer can be structured. This structured surface serves, for example, as a radiation coupling-out surface of the component. In particular, the transition layer is overgrown directly onto the columnar structures, so that the structured surface of the transition layer simulates a distribution of the columnar structures.

The method described above and / or the epitaxial wafers described above are particularly suitable for the production of a device described above. The features described in connection with the method or epitaxial wafer can therefore also be used for the component and vice versa.

Further advantages, preferred embodiments and further developments of the epitaxial wafer, of the component and of the method will become apparent from the following in connection with FIGS 1 to 8th explained embodiments.

Show it:

1 a schematic representation of an embodiment of an epitaxial wafer and a method for its production,

2A to 2D schematic representations of various embodiments of an epitaxial wafer,

3 and 4 schematic representations of a method for producing a component,

5 and 6 schematic representations of a device, and

7 and 8th Further embodiments of a method for producing a component.

The same, similar or equivalent elements are provided in the figures with the same reference numerals. The figures are each schematic representations and therefore not necessarily to scale. Rather, comparatively small elements and in particular layer thicknesses may be exaggerated for clarity.

A first embodiment of an epitaxial wafer and its production is shown in FIG 1 shown schematically.

The epitaxy wafer 10 has a substrate 1 , a transitional layer 30 and one between the substrate 1 and the transitional layer 30 arranged separating layer 2 on. The separation layer 2 has a plurality of columnar structures 20 on.

The transitional layer 30 and the separation layer 2 are in particular semiconductor layers. They can be formed from a same semiconductor material or have different semiconductor materials. The substrate 1 has one of the columnar structures 20 facing main surface 11 on. One of the columnar structures 20 opposite main surface 301 the transitional layer 30 is parallel to the main surface 11 formed of the substrate. The main area 301 the transitional layer 30 is just trained. The transitional layer 30 has a surface facing the columnar structures 302 on, which is structured. The transitional layer 30 is in particular directly on the columnar structures 20 laterally overgrow, leaving the textured surface 302 the transitional layer 30 the positions of the columnar structures 20 reproduces. In other words, the structured surface 302 a distribution of the columnar structures 20 simulated.

The columnar structures 20 can be at least 20% and at most 80% of a total area of the main area 11 of the substrate 1 cover. In particular, the columnar structures cover 20 between and including 25% and 70% inclusive, between about 30% and 60% inclusive of the total area of the main area 11 of the substrate 1 , Preferably, the columnar structures cover 20 between 40% and 70% of the total area of the main area 11 , whereby the transition layer 30 reliable on the columnar structures 20 can be applied and the substrate 1 in a subsequent step, for example by a mechanical separation process simplified by the transition layer 30 can be separated.

For producing such epitaxial wafer 10 becomes the substrate 1 provided. The substrate 1 may be a sapphire substrate, a silicon substrate, a germanium substrate, or a gallium-containing substrate, such as a gallium nitride or a gallium arsenide substrate. On the substrate 1 becomes the separation layer 2 applied, for example, surface. The surface-applied separating layer 2 can then by means of phototechnology, such as by means of a photomask, and an etching process to the columnar structures 20 be structured. In this case, first a lacquer layer on the release layer 2 are applied and then the uncovered areas of the paint layer of the release layer 2 For example, by means of an etching process, such as a plasma etching process such as ICP etching (English: Inductively Coupled Plasma Etching), structured, whereby the columnar structures 20 be generated. The uncovered by the lacquer layer bodies can have any geometry, such as circular, elliptical or oval, or polygonal, approximately square or hexagonal. Alternatively, the columnar structures 20 directly on the substrate 1 be applied. The main area 11 of the substrate can be partially covered by a mask, such as silicon oxide such as SiO2, wherein the columnar structures 20 on uncovered areas of the main area 11 can be grown in particular by an epitaxial process, such as so-called molecular beam epitaxy. In particular, the mask has openings whose cross-section may have any desired geometry, for example circular, elliptical or oval, or polygonal, approximately quadrangular or hexagonal.

The geometry and distribution of the columnar structures 20 are chosen so that the columnar structures 20 for separation of the substrate 2 from the transitional layer 30 or one on the transition layer 30 trained layer sequence by a mechanical separation process, such as by lateral mechanical force, are formed breakable. In other words, the columnar structures become 20 designed so that the substrate 1 at the interface 2 Can be removed by the columnar structures 20 at least partially or completely destroyed.

The columnar structures 20 may have a lateral cross section whose maximum lateral extent between 10 nm and 100 .mu.m, in particular between 20 nm and 10 mm, may be between about 20 nm and 1 mm. In particular, the columnar structures 20 on the substrate 1 so distributed that this at the separation of the substrate 1 serve as predetermined breaking points by a mechanical separation process, for example by lateral mechanical actions.

The distances between the columnar structures 20 are chosen so that the transitional layer 30 on the columnar structures 20 can overgrow lateral, such as by means of an epitaxial process. The transitional layer 30 forms in particular a coherent layer.

The transitional layer 30 and the separation layer 2 each may comprise a semiconductor material. In particular, they may comprise a similar semiconductor material, such as gallium arsenide or gallium nitride. The materials of the transitional layer 30 and the release layer 2 are designed such that in particular a crystallographic long-range order within the entire epitaxial wafer 10 is maintained. For example, a material of the substrate 1 selected so that the crystallographic long-range order of the substrate 1 over the separation layer 2 away in the transitional layer 30 continues to receive. For example, the substrate 1 a gallium arsenide or a gallium nitride substrate.

The columnar structures 20 are in the 1 evenly on the substrate 1 arranged. In other words, the distances between adjacent columnar structures 20 essentially the same. They have in particular the same cross sections. Alternatively, the columnar structures 20 be arranged unevenly. They can have different cross sections or so on the substrate 1 arranged that the distances between the adjacent columnar structures 20 especially different.

For example, the columnar structures 20 on the substrate 2 designed so that a distribution density of the columnar structures 20 varies depending on a distance from an edge of the substrate.

In the 2A the spacings of adjacent columnar structures vary 20 from a first edge of the substrate 1 steadily to a central area of the substrate. The distances between the adjacent columnar structures 20 thus take from one edge of the substrate 1 steadily towards the central area. Apart from that, it is also possible that the distances from one edge of the substrate 2 to steadily decrease to the central area.

In the 2 B the spacings of adjacent columnar structures vary 20 steadily from a first edge of the substrate 1 towards a second edge opposite the first edge. Apart from that, it is also possible that the distances vary only in certain regions.

In the 2C are the columnar structures 20 on the substrate 1 arranged so that a plurality of groups of the columnar structures 20 are formed, wherein a lateral distance between the adjacent groups is greater than the distances between the columnar structures 20 within a group.

In the 2D is the separation layer 2 designed so that the distances between the adjacent columnar structures 20 larger than the vertical heights of the columnar structures 20 ,

In the 3 is a method step of an embodiment for producing a component 100 shown schematically. The epitaxy wafer 10 this embodiment corresponds to that in connection with 1 described embodiment for an epitaxial wafer.

On the epitaxy wafer 10 becomes a layer sequence 3 educated. The layer sequence 3 has a first semiconductor layer 31 a first charge type, a second semiconductor layer 32 of a second charge type and one between the first semiconductor layer 31 and the second semiconductor layer 32 arranged active layer 33 on. The layer sequence 3 can do so directly after the application of the transition layer 30 be applied to these, for example by means of an epitaxial process. In other words, the layer sequence 3 and the transition layer 30 be formed in a common process step, such as in a common epitaxial process. In particular, the transition layer 30 and the first semiconductor layer 31 have a same semiconductor material, wherein they can also be formed in a common process step.

Alternatively, it is also possible that the epitaxial wafer 10 with the transitional layer 30 in a separate process, the epitaxial wafer 10 for the production of the device 10 is provided and the layer sequence 3 in one of the production of the epitaxial wafer 10 separate procedures on the transition layer 30 epitaxial wafer 10 is applied.

In a further method step, the layer sequence 3 on a carrier 9 or on a carrier composite 90 by means of a bonding layer 4 , such as an adhesive layer or a solder layer, attached. It is also possible that the tie layer 4 is formed radiation-reflective. The carrier 9 or the carrier association 90 may include germanium or silicon or consist of germanium or silicon. In particular, the layer sequence 3 on the carrier composite 90 bonded. In this case, the connection layer is 4 formed as a bond connection.

In 4 a further method step of an embodiment for producing one or a plurality of components is shown in a schematic sectional view.

This embodiment corresponds essentially to that in connection with FIG 3 described embodiment. In contrast, the substrate becomes 1 from the layer sequence 3 especially removed by a mechanical separation process. The substrate becomes of the layer sequence 3 at the interface 2 separated by the columnar structures 20 at least partially or completely destroyed. For separation of the substrate 1 a shear force is applied, such as by lateral mechanical forces acting on the substrate 1 and / or on the layer sequence 3 or on the carrier network 90 , Due to the shear force, for example due to lateral mechanical force, the columnar structures 20 broken. The substrate 1 can thereby non-destructive of the layer sequence 3 be separated and reused.

For producing a plurality of components 100 becomes the carrier composite 90 with the layer sequence arranged thereon 3 after removing the substrate 1 isolated, creating a plurality of isolated components 100 arises, each one a carrier 9 from the carrier network 90 and have an associated layer sequence. Such a device is for example in the 5 shown schematically.

The component 100 in the 5 is free from a growth substrate. In this case, the device is 100 free from the substrate 1 epitaxial wafer 10 , The active layer 33 the sequence of layers 3 can be designed so that these in the operation of the device 100 emits an electromagnetic radiation in the visible range, in the ultraviolet range or in the infrared range. Alternatively, it is also possible that the active layer 33 during operation of the device 100 absorbs electromagnetic radiation and converts it into electrical energy or electrical signals.

The component 100 has a the carrier 9 facing away, in particular exposed surface with partially removed columnar structures 20 on. Under partially removed columnar structures 20 In particular, columnar structures are understood that on their the layer sequence 3 opposite side has separation marks. In particular, the surface forms with the partially removed columnar structures 20 a radiation passage area 101 such as a radiation exit surface or a radiation entrance surface of the device 100 , wherein the columnar structures 20 are formed as Strahlungsauskoppel- or as Strahlenseinkoppelstrukturen. The columnar structures 20 act in particular as radiation coupling-out structures or as scattering structures that scatter the radiations emerging from the component in particular uniformly in different directions. In particular, the radiation passage area 101 columnar structures 20 with separation traces originating from a mechanical separation process in which the columnar structures 20 to be broken.

In 6 is another embodiment of a device 100 shown schematically. The component 100 this embodiment substantially corresponds to that in connection with the 5 described embodiment of a component. In contrast to this, the component 100 a mirror layer 5 on that between the carrier 9 and the layer sequence 3 is arranged. In the 6 is the radiation passage area 101 a surface of the transition layer 30 , wherein the surface of the transition layer 30 structured, but free from the columnar structures 20 is. In other words, the columnar structures 20 compared to the one in the 5 completely removed embodiment described.

In 7 an embodiment of a method for producing a plurality of components is shown in a schematic sectional view. This embodiment corresponds essentially to that in the 3 described embodiment.

In contrast to this is a digging 23 through the layer sequence 3 and through the separation layer 2 through to the substrate 1 formed before the layer sequence 3 on the carrier composite 90 is attached. The substrate 1 is in a subsequent process step of the layer sequence 3 in particular so removed that the ditch 23 is exposed. It is also possible that a plurality of trenches 23 be formed. For separating the plurality of components 100 becomes the carrier composite 90 along the dike 23 or along the trenches 23 sporadically.

In 8th is another embodiment of a method for producing a plurality of components 100 shown schematically. This embodiment corresponds essentially to that in the 7 described embodiment.

In contrast, in the formation of the separation layer 2 first a sacrificial layer 21 , such as aluminum arsenide (AlAs) on the substrate 1 , deposited from gallium arsenide (GaAs). The separation layer 2 has another layer 22 on, for example, by means of an epitaxial process on the sacrificial layer 21 is applied. In particular, the further layer has 22 the separation layer 2 a material that is more etch-resistant than a material of the sacrificial layer 21 is. The separation layer 2 with the between the other layer 22 and the substrate 1 arranged sacrificial layer 21 is then used to form a plurality of columnar structures 20 structured by means of an etching process. The columnar structures 20 thus each have a share of the sacrificial layer 21 and another part from the further layer 22 the separation layer 2 on. It is also possible that such columnar structures 20 directly structured, for example by a mask made of silicon oxide, on the substrate 1 be applied.

According to the embodiment in the 8th can the substrate 1 by a mechanical separation process, for example by lateral mechanical forces acting on the substrate or on the carrier composite 90 or on the layer sequence 3 , from the layer sequence 3 be separated. Due to the presence of the trench 23 the shear force can be reduced because part of the material to be scrapped is the release layer 2 already been removed.

Alternatively or additionally, in the separation of the substrate 1 an etching process applied. An etchant, for example a hydrofluoric acid such as hydrofluoric acid (HF), can enter the trench 23 or in the majority of trenches 23 be supplied. Due to the capillary effect, the etchant may laterally on the substrate 1 and vertically within the separation layer 2 spread. It is also conceivable that the etchant may be guided or drawn into the trenches in addition to the capillary effect by generating a negative pressure. The sacrificial layer 21 can be etched away partially or completely. For a complete path etching of the sacrificial layer 21 becomes the substrate 1 solely due to the etching process of the layer sequence 3 separated. By forming the columnar structures 20 and / or the trenches 23 becomes the amount of the material to be etched of the sacrificial layer 21 significantly reduced. Compared to an unstructured sacrificial layer 21 For example, the amount of material to be etched can be reduced by up to 50% or more. It is also possible that the columnar structures 20 only partially etched and for separating the substrate additionally a shearing force to the substrate 1 and / or to the carrier network 1 or to the layer sequence 3 is created. In an etch, the shear force can be further reduced.

With the formation of a plurality of columnar structures in the separation layer, a particularly cost-effective method for producing a plurality of components can be specified, in which the growth substrate is simplified and reliably separated from the components to be manufactured non-destructively and thus can be reused. Such a separation method is also applicable to any growth substrate, so that, for example, a sapphire substrate can be reliably removed from the layer sequence without the use of the laser lift-off process or a GaAs substrate without the use of etchants nondestructive.

The invention is not limited by the description of the invention based on the embodiments of these. Rather, the invention encompasses any novel feature as well as any combination of features, which includes in particular any combination of features in the claims, even if this feature or combination itself is not explicitly stated in the claims or exemplary embodiments.

Claims (17)

Method for producing a component ( 100 ) comprising the following steps: a) forming or providing an epitaxial wafer ( 10 ), which is a substrate ( 1 ) and one on the substrate ( 1 ) separating layer ( 2 ), wherein the separating layer ( 2 ) a plurality of columnar structures ( 20 ) of a semiconductor material; b) forming a layer sequence ( 3 ) with an active layer ( 33 ) on the epitaxial wafer ( 10 ); and c) removing the substrate ( 1 ) of the layer sequence ( 3 ) at the separating layer ( 2 ) by the columnar structures ( 20 ) are at least partially destroyed. Method according to the preceding claim, in which the layer sequence ( 3 ) directly onto the epitaxial wafer ( 10 ), wherein the layer sequence ( 3 ) and the separating layer ( 2 ) have only semiconductor layers. Method according to one of the preceding claims, in which the separating layer ( 2 ) initially flat on the substrate ( 1 ) and then to form the columnar structures ( 20 ) is structured. Method according to one of claims 1 to 2, wherein a mask on the substrate ( 1 ) and the columnar structures ( 20 ) through the mask on the substrate ( 1 ) are structured. Method according to one of the preceding claims, in which a transition layer ( 30 ) of a semiconductor material directly on the columnar structures ( 20 ) is applied, so that the columnar structures ( 20 ) from the transition layer ( 30 ) are completely covered. Method according to one of the preceding claims for producing a plurality of components ( 100 ), in which - the layer sequence ( 3 ) before removal from the substrate ( 1 ) on a carrier composite ( 90 ), and - the carrier composite ( 90 ) after removing the substrate ( 1 ) is singulated for separating the plurality of components, so that the separated components each have a carrier ( 9 ) and an associated layer sequence. Method according to the preceding claim, in which - at least one trench ( 23 ) through the layer sequence ( 3 ) is formed through before the layer sequence ( 3 ) on the carrier composite ( 90 ), - the substrate ( 1 ) of the layer sequence ( 3 ) is removed so that the trench ( 23 ), - the carrier network ( 90 ) for separating the plurality of components along the trench ( 23 ) is isolated. Method according to the preceding claim, in which the at least one trench ( 23 ) is formed so that this through the separation layer ( 2 ) through to the substrate ( 1 ). Method according to one of claims 1 to 8, in which for the separation of the substrate ( 1 ) the columnar structures ( 20 ) are broken by lateral mechanical forces. Method according to one of claims 7 to 9, wherein for the separation of the substrate ( 1 ) an etchant into the at least one trench ( 23 ) is fed to the columnar structures ( 20 ) at least partially etched away. Method according to one of claims 1 to 10, wherein the substrate ( 1 ) is a gallium-containing substrate or is formed of sapphire. Method according to one of claims 1 to 11, wherein the substrate ( 1 ) GaAs and the columnar structures ( 20 ) are formed at least partially of AlAs. Epitaxial wafers ( 10 ), which is a substrate ( 1 ), a release layer ( 2 ) and a transition layer ( 30 ), wherein - the transition layer ( 30 ) and the separating layer ( 2 ) Semiconductor layers are, - the separating layer ( 2 ) between the substrate ( 1 ) and the transition layer ( 30 ), - the separating layer ( 2 ) a plurality of columnar structures ( 20 ) of a semiconductor material, wherein the columnar structures ( 20 ) for separating the substrate ( 1 ) from the transition layer ( 30 ) are made breakable by means of a mechanical separation process. Epitaxial wafer according to the preceding claim, in which the columnar structures ( 20 ) so on the substrate ( 1 ) are formed such that a distribution density of the columnar structures ( 20 ) as a function of a distance from an edge of the substrate ( 1 ) varies. An epitaxial wafer according to any one of claims 13 to 14, wherein spacings of adjacent columnar structures ( 20 ) from a first edge of the substrate ( 1 ) to a second edge opposite the first edge or to a central region of the substrate ( 1 ) vary at least regionally steadily. Component ( 100 ) comprising a support ( 9 ) and one on the carrier ( 9 ) arranged layer sequence ( 3 ) with an active layer ( 33 ), the device being free from a growth substrate, and a carrier ( 9 ) facing away, exposed surface with partially removed columnar structures ( 20 ) of a semiconductor material. Component according to the preceding claim, in which the active layer ( 33 ) during operation of the device ( 100 ) emits an electromagnetic radiation, the exposed surface as a radiation exit surface ( 101 ) of the component is formed and the partially removed columnar structures ( 20 ) are formed as radiation coupling-out structures.

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