EP2777078A1

EP2777078A1 - Production of a semiconductor device having at least one column-shaped or wall-shaped semiconductor element

Info

Publication number: EP2777078A1
Application number: EP12794633.3A
Authority: EP
Inventors: Oliver Brandt; Lutz GEELHAAR; Vladimir KAGANER; Martin Wölz
Original assignee: Forschungsverbund Berlin FVB eV
Current assignee: Forschungsverbund Berlin FVB eV
Priority date: 2011-11-11
Filing date: 2012-11-09
Publication date: 2014-09-17
Also published as: US20140312301A1; WO2013068125A1; WO2013068125A8; DE102011118273A1; US9184235B2

Abstract

Described is a method for producing a semiconductor device (100), in which at least one column-shaped or wall-shaped semiconductor device (10, 20) extending in a main direction (z) is formed on a substrate (30), wherein at least two sections (11, 13, 21, 23) of a first crystal type and one section (12, 22) of a second crystal type therebetween are formed in an active region (40), each section with a respective predetermined height (h₁, h2), wherein the first and second crystal types have different lattice constants and each of the sections of the first crystal type has a lattice strain which depends on the lattice constants in the section of the second crystal type. According to the invention, at least a height (h2) of the section (12, 22) of the second crystal type and a lateral thickness (D) of the active region (40) is formed perpendicular to the main direction, in such a manner that the lattice strain in one of the sections (11) of the first crystal type also depends on the lattice constants in the other section (13) of the first crystal type. A semiconductor device (100) is also described, having at least one column-shaped or wall-shaped semiconductor element (10, 20) on a substrate (30), which can be produced in particular by means of the stated method.

Description

Production of a semiconductor device with at least one columnar or wall-shaped semiconductor element

The invention relates to a method for producing a semiconductor device, such as. B. a light-emitting device, with at least one columnar or wall-shaped semiconductor element, in particular a method for producing a semiconductor device whose at least one semiconductor element in at least one cross-sectional direction has a lateral thickness less than 1 μπι, in particular less than 500 nm. Furthermore, the invention relates to a semiconductor device having at least one columnar or wall-shaped semiconductor element, in particular a semiconductor device having at least one nanopillar and / or at least one nanowind, which is arranged on a substrate. Applications of the invention are given in the production of optical, in particular light-emitting, electrical, electromechanical and / or electrothermal components.

It is generally known to produce semiconductor elements (nanostructured semiconductor elements) on a substrate which have characteristic dimensions in the sub-micrometer range. For the structuring of a substrate and the production of the semiconductor elements are "top-down" methods such. As the selective etching of planar semiconductor, or "bottom-up" method, such. As the epitaxial growth of nanostructured semiconductors known.

With the mentioned methods z. B. columnar semiconductor elements (nanowires, nanopillars, English: nanowire) (see, for example, US 2011/0127490 AI or US 2007/0257264 AI) or wall-shaped semiconductor elements (nanowalls, nanoplates, nano- Disks, English: nanowall) on a substrate. Typically, nano-column heterostructures are produced which along a major direction of the semiconductor elements have sections of different crystal types, e.g. B. with different chemical composition or different

Doping, to provide the semiconductor element with certain optical, electrical, mechanical and / or thermal properties. It is furthermore known that these properties of nanostructured semiconductors differ from those of planar or voluminous semiconductors, since the structuring has an effect on the conduction properties and band progressions of the semiconductor. It is pointed out in US 2011/0127490 A1 that the nanowires are characterized by a negligible number of dislocations compared to planar semiconductors because of an effective stress relaxation. It has been proposed to produce light-emitting components (light-emitting diodes, LEDs) from nanostructured semiconductors. For example, K. Kishino et al. ("Proceedings of SPIE", Vol. 6473, 2007, p. 6473T-1 - 64730T-12) and by A. Kikuchi et al. ("Japanese Journal of Applied Physics", Vol. 43, 2004, pp. L1524-L1526) describe LEDs consisting of (In, Ga) N / GaN nanocolumns on sapphire or silicon substrates and light in the visible Emit spectral range. The nanopillars are formed as heterostructures by self-assembly, alternating in the main direction of the nanocolumns sections of a crystal type with a smaller band gap (quantum well sections) and sections of a crystal type with a larger band gap (barrier sections). The wavelength of the emitted light is determined in particular by the band structure of the Quantum well sections and specifically determines their In content. By B. Guo et al. (see "Nanoletters", Vol. 10, 2010, p. 3355) describes an LED made of (In, Ga) / GaN nanopillars on a silicon substrate which, by varying the semiconductor composition along the nanopillars, has different wavelengths in one broad spectral range (white light) emitted.

Although the fabrication of LEDs with nanostructured semiconductors offers advantages in terms of growth conditions (possible use of silicon as substrate) compared to conventional GaN-based LEDs, the quantum efficiency of light emission and the adjustment of spectral properties (use of higher In concentrations). In the Pra ^¬ tice, however, only a few process parameters for setting specific emission properties previously used, which are also used in conventional LEDs such. B. the composition of the semiconductor. In particular, the setting of the emission to a specific spectral range, z. As the setting of a white light emission, represents a major challenge for the control of process parameters in the production of nanostructured semi ^¬ conductor.

The problems mentioned not only affect the production of LEDs, but also in other applications of nanostructured semiconductors, for. B. as electronic components, as electro-thermal devices or e-lektro mechanical components (MEMS devices).

The object of the invention is to provide an improved method for producing a semiconductor device comprising a patterned semiconductor, with which

Disadvantages of conventional methods can be avoided. The object of the invention is in particular to provide a method for producing a semiconductor device with nanostructured semiconductor elements, which is characterized by a simplified process control. The method should also enable increased accuracy and / or reproducibility in the adjustment of optical, electrical, mechanical and / or thermal properties of the semiconductor elements. Another object of the invention is to provide an improved semiconductor device comprising a patterned semiconductor which avoids the disadvantages of conventional semiconductor devices with patterned semiconductors. The semiconductor device should be particularly suitable for a simplified production and / or an accurate and reproducible adjustment of physical or chemical properties.

These objects are each achieved by a method or a semiconductor device having the features of the independent claims. Advantageous embodiments and applications of the invention will become apparent from the dependent claims.

According to general aspects of the invention, the stated objects are achieved in each case by a method for producing a semiconductor device or by a semiconductor device, wherein the semiconductor device comprises a substrate and at least one semiconductor element which has an elongate shape and in a main direction which depends on the extent of the Surface of the substrate deviates extends. The semiconductor element transversely to the main direction has a Lateraldicke which is less than the Hö ^¬ he (length) of the semiconductor element in the main direction. The elongated shape of the semiconductor element is formed so that the semiconductor element in at least one sectional plane has an aspect ratio (quotient of lateral thickness and Length) is less than 1, preferably less than 0.1, more preferably less than 0.05. Basic forms of the semiconductor element are z. The shape of a column (or: needle, wire or rod) or the shape of a wall (or: disc). In the columnar form, the main direction is formed by the longitudinal direction of the column and in the wall shape by a direction perpendicular to the thickness direction of the wall. Typically, the main direction is oriented perpendicular to the surface of the substrate, but alternatively, a tilt angle less than 90 ° may be present. The semiconductor element may have a substantially constant lateral thickness along its entire length or, alternatively, a varying lateral thickness. For example, the columnar shape may have a diameter decreasing or increasing from the substrate to the free end of the semiconductor element. Accordingly, the semiconductor element may also have the shape of a pyramid or truncated cone or a more complicated geometric shape. Along the main direction, ie the direction in which the at least one semiconductor element extends from the surface of the substrate, the semiconductor element has an active region with sections of different crystal types. At least two sections of a first crystal type are provided, between which a section of a second crystal type is arranged. In practical applications of the invention, there is preferably a series of the first crystal type portions separated by second crystal type portions. The first and second types of crystals characterized by different lattice constants and un ^¬ terschiedliche optical, electrical, mechanical and / or thermal properties such. B. by different line properties and band gaps, from. Depending on the application of the invention, the sections of the different crystal types different functions. For example, in an LED, the portions of the first crystal ^¬ type quantum well portions and the portions of the second crystal type barrier sections.

The first and second types of crystals have different Git ^¬ terkonstanten. The difference in the lattice constants causes a lattice strain to occur in the sections of the first crystal type, which depends on the lattice constant in the section of the second crystal type. Furthermore, the at least one portion of the second crystal type also has a lattice strain that depends on the lattice constant in the adjacent portions of the first crystal type. For both types of crystal the strain is laterally inhomogeneous.

According to the invention, the active region of the at least one semiconductor element is geometrically dimensioned such that the lattice strain in the at least two sections of the first crystal type is not only dependent on the lattice constant of the first crystal type

Section of the second crystal type, but also mutually dependent on the lattice constant of the other portion of the first crystal type. The geometrical dimensions of the active area means that the height (thickness in the main direction) of the portion of the second crystal type and / or the Lateraldicke is (thickness transversely to the main direction) of the semiconducting ^¬ terelements, in particular of the active region is selected so that superimpose or influence the grating stresses of the first crystal type portions.

The inventors have found that with the height of the portion of the second crystal type, ie with the distance of at least two portions of the first crystal type in the main direction, and with the lateral thickness of the active region two new degrees of freedom, which are not available in conventional methods, can be created with which physical or chemical properties of the at least one semiconductor element can be set. In the conventional nanostructuring z. B. in an LED, the quantum well portions are so far apart that they do not affect each other. In contrast, according to the invention, a mutual dependence of the lattice strain of the sections of the first crystal type is set in a targeted manner. The inventors have further found, in contrast to the findings described in US 2011/0127490 AI, that the geometric dimensioning of the active region and therefore with the lattice strain optical, electrical, mechanical and / or thermal properties of the semiconductor element in contrast to the conventional approach To change the composition can be varied in a simplified way. The geometric dimensioning of the active region, especially when properties of the quantum wells are to be changed within the nano-column, places lower demands on the process management than, for example, Example, the conventional variation of the composition of a semiconductor in the longitudinal direction of the nanocolumn. The change in vapor composition and temperature in the crystal growth process to vary the crystal composition can be replaced by the variation of the column geometry, which greatly simplifies the manufacturing process. Furthermore, the reproducibility of the process ^¬ leadership can improve.

The invention is based in particular on the following considerations of the inventors. Two coherently bonded crystals with different lattice constants are mechanically stressed. The stress influences essential properties of the semiconductor, such as. B. its electronic band structure, the charge carrier Agility, heat capacity or thermal conductivity. Although the strain already occurs in conventional semiconductor devices with layered (unstructured) heterostructures of contiguous or interrupted thin layers, the lattice mismatch determines the state of stress of the layer. This would be adjustable only by the introduction of defects. By contrast, in the case of conventional semiconductor devices with nanostructured semiconductor elements, the mutual influence of the physical or chemical properties of the ^{sections of} the first crystal type and thus of the semiconductor elements due to the lattice strain has hitherto been disregarded. The invention is now based on the idea of arranging crystallites with mismatch, ie different sections of different crystal types, in such a way that a relaxation takes place at the free surfaces of the semiconductor elements. For this purpose, it is advantageous if the semiconductor elements have a high aspect ratio. The remaining stress in the sections can be set in particular by the mentioned geometric dimensions, such as the quotients of the heights of the adjacent sections of the first and second crystal types and / or the quotient of the height of the active area and the lateral thickness of the active area. According to a particularly preferred embodiment of the invention, a targeted adjustment of physical and / or chemical properties of the semiconductor element, in particular of optical, electrical, mechanical and / or thermal properties of the semiconductor element, by adjusting at least one height quotient of adjacent sections and / or heights -Laterdicken- quotient predetermined, material-dependent reference values are used. In the production of at least a semi-conductor element ^¬ the process conditions are such. B. at a "top-down" - or in a "bottom-up" method using the given reference values selected. The reference values are z. As determined by theoretical simulations depending on the materials used, from existing table values or by simple experiments.

Advantageously, different variants exist in the geometric dimensioning of the active region of the at least one semiconductor element. According to a first variant, the active region can be dimensioned such that all sections of the first crystal type have the same lattice strain along the main direction of the semiconductor element. As a result, all portions of the first crystal type have the same optical, electrical, mechanical and / or thermal properties. On the other hand, the inventors have found that, for example, in an LED, the lattice strain of the quantum well portions in the longitudinal ^¬ direction of a columnar semiconductor element can vary when all barrier sections have the same height. Accordingly, the spectral range of the emission would broaden. By setting the same grating tension in all sections according to the first variant, a spectral broadening of the light emission is thus minimized in the LED application. Conversely, according to a second variant, it can be provided that at least two of the sections of the first crystal type have targeted different grid stresses along the main direction of the semiconductor element. As a result, z. For example, in the LED application, the grating strains are set so that light of different wavelengths is emitted from all the quantum well portions, so that the at least one semiconductor element can be used as a broadband light source. According to a further advantageous embodiment of the invention, the lattice strain can be adjusted in at least one of the sections of the first crystal type by embedding the respective section on all sides in the material of the second crystal type. The first crystal type portion has an interface with the second crystal type portion not only in the main direction of the semiconductor element but also in the thickness direction transverse to the main direction. Advantageously, this provides an additional degree of freedom in the adjustment of the physical or chemical properties of the relevant section or of the entire semiconductor element. A semiconductor device according to the invention can with a single semiconductor element, for. As a single nanocolumn or nanowire, be prepared on the substrate. This variant may have advantages, for. B. ben in the use of the semiconductor ^¬ element as an electronic component in a circuit ben. According to a preferred embodiment of the invention, however, it is provided that a plurality of the semiconductor elements are arranged projecting from the substrate surface on the substrate. Depending on the desired application of the semiconductor device according to the invention, the method may be carried out so that all semiconductor elements of the same shapes and sizes or that the semiconductor elements are produced with different shapes and / or sizes. For example, even columns and wall shapes may be combined on a common sub ^¬ strat.

First, the provision of a plurality of semiconductor elements on a common substrate has the advantage that the Effect of the inventive setting of the electrical, optical, mechanical and / or thermal properties of the semiconductor elements is summed. For example, LEDs can be created with a significantly increased brightness. Furthermore, the provision of a plurality of semiconductor elements offers further possible variations for the design of the semiconductor device. For example, the active regions of all semiconductor elements can be dimensioned the same, so that the physical and / or chemical properties of all semiconductor elements are identical. Alternatively, the active regions of the semiconductor elements can be dimensioned differently, so that correspondingly a variation of the physical and / or chemical properties of the semiconductor elements within the semiconductor device is achieved.

Advantageously, the invention with a variety of semiconductors can be realized. Preferably, the portions of the first and / or second crystal types are made of a nitride-based semiconductor, in particular a gallium nitride-based semiconductor, an arsenide-based semiconductor, in particular a gallium arsenide-based semiconductor, an antimonide-based semiconductor, in particular a gallium antimony-based semiconductor , a phosphide-based semiconductor, in particular a gallium phosphide-based semiconductor, a silicon-based semiconductor and / or a germanium-based semiconductor.

According to particularly preferred embodiments of the invention, the at least one semiconductor element is produced with the following geometric dimensions. Column-shaped semiconductor element: lateral thickness <1 μm, preferably <500 nm, particularly preferably <50 nm; Length:> 100 nm, preferably> 500 nm, more preferably> 1 μιτι; Length of the active rich:> 50 nm, preferably> 100 nm, more preferably> 150 nm; Number of sections of the first crystal type: at least 2, preferably at least 4, more preferably at least 6; Height (hi) of the portions of the first crystal type: <100 nm, preferably <10 nm, more preferably

<5 nm; Height (h ₂ ) of the section of the second crystal type:

<100 nm, preferably <10 nm, more preferably <5 nm. Wall-shaped semiconductor element: Dimensioning such as the columnar semiconductor element, with a freely selectable extension in the longitudinal direction of the plate.

In addition to the exemplary highlighted application of the semiconductor device according to the invention as a light-emitting component (LED) further preferred applications include the provision of an electronic component, eg. B. in an integrated circuit, an opto-electronic device, for. As a solar cell, an electro-mechanical device or a thermoelectric device.

Further details and advantages of the invention will be described below with reference to the accompanying drawings. Show it:

FIG. 1 shows schematic sectional views of various variants of columnar semiconductor elements according to the invention;

FIG. 2 shows a schematic perspective view of a variant of a wall-shaped semiconductor element according to the invention;

Figure 3 is a schematic perspective view of an embodiment of the semiconductor device having a plurality of columnar semiconductor elements; Figure 4 is a further schematic sectional view of a säu ^¬ lenförmigen semiconductor element; and

FIG. 5: Room temperature photoluminescence spectra for the active zone of an LED according to the invention.

Preferred embodiments of the semiconductor device according to the invention and the method for their production are described below in particular with reference to the geometric dimensioning of the active region of the semiconductor elements. Details of the processes for fabricating the semiconductor elements by patterning thin layers ("top-down") or by self-organized growth of the semiconductor elements ("bottom-up") are not described here, since they are known per se from the prior art. It is emphasized that the inventive geometric Dimension ^¬ dimensioning of the active area of the semiconductor elements with conventional techniques for adjustment of optical, electrical, mechanical and / or thermal properties in the production of semiconductor elements, z. B. by changing the composition can be combined.

The invention will be described in particular with regard to the adjustment of the lattice strain in the sections of the first crystal type. Depending on the specific application of the invention, it may alternatively or additionally be provided that the lattice strain in the sections of the second crystal type is specifically adjusted.

Although reference is made in the following to GaN-based semiconductors by way of example, it should be emphasized that the implementation of the invention is not restricted to these semiconductors but is instead speaking with other doped or non-doped semiconductors is possible.

The invention will be described below by way of example with reference to the production of an LED in which the at least one nanostructured semiconductor element comprises a heterostructure of quantum well sections and barrier sections. The sections of the first and second crystal types in the at least one semiconductor element are accordingly drawn in the following as quantum well sections and as barrier sections. Since the implementation of the invention is not limited to the manufacture of an LED device, the sections of the first and second crystal types have different functions than the quantum well sections and the barrier sections in other applications.

FIG. 1 illustrates, in a schematic sectional view, a semiconductor device 100 according to the invention with various variants of columnar semiconductor elements 10 arranged on a substrate 30. The semiconductor elements 10 have an elongated columnar shape with a main direction that is perpendicular to the surface of the substrate 30 in FIG. 1 as a z-direction in the plane of the paper. The semiconductor elements 10 have z. B. a circular, elliptical or polygonal cross-section with a characteristic cross-sectional dimension (lateral thickness) D in the x direction in the range of z. B. 10 nm to 200 nm. The length of the semiconductor elements 10 in the z direction is selected for example in the range of 30 nm to 500 nm.

A sequence of quantum well portions 11, 13, ... which are separated by barrier portions 12, 14, ..., forms an active region 40 whose length in the z direction is selected, for example, in the range from 30 nm to 200 nm. The quantum well sections 11, 13, ... have a height hi, which in the range of z. B. 1 nm to 5 nm is selected, while the barrier sections 12, 14, ... a height have, the z. B. is selected in the range of 1 nm to 20 nm.

The quantum well portions 11, 13, ... are z. B. from (In, Ga) N, while the barrier sections 12, 14, ... are made of GaN. Correspondingly, the quantum well sections 11, 13,... Have a narrower band gap than the barrier sections 12, 14, the emission wavelength of the light emitted by the semiconductor elements 10 depending on the band gaps in the quantum well sections 11, 13,. The substrate 30 is z. B. of sapphire or silicon. The thickness of the substrate 30 is z. B. selected in the range of 250 μιη to 1 mm.

According to the invention, the quotient are from the heights h _x and h ₂ (hi: h ₂₎ and / or the quotient of the height H and the Lateraldicke D (H: D) selected such that the lattice tension in the quantum well sections 11 , 13, ... influence each other as described below with reference to FIG. For example, the variants I and II differ by the lateral thickness D. As the lateral thickness D increases, the influence of adjacent quantum well portions is reduced. Furthermore, variants III and IV show that in the active region 40, the heights h _{2 of} the barrier sections can vary. Accordingly, the emission wavelengths of the quantum well portions differ. According to further variants, alternatively or additionally, the heights hi of the quantum well portions could be varied in the z direction. Finally, variant V shows a structure in which the quantum well sections 11, 13,... Are completely embedded in the material of the barrier sections 12, 14,. The extension of the quantum well sections 11, 13,... In x- Direction can be selected, for example, about 1 nm to 3 nm smaller than the lateral thickness D.

FIG. 2 schematically illustrates an embodiment of a semiconductor device 100 according to the invention with a wall-shaped semiconductor element 20 which is arranged on the substrate 30. The wall-shaped semiconductor element 20 has a substantially two-dimensional extent in the z and y directions, which is selected in the range of 200 nm to 2 μπι. By contrast, the lateral thickness D in the x direction is chosen to be much smaller in the range from 20 nm to 200 nm. In the z-direction, a series of quantum well portions 21, 23, ... and barrier portions 22, 24, ... form the active region 40 with a height H selected in the range of 30 nm to 200 nm.

FIG. 3 shows, in a schematic perspective view, an embodiment of the semiconductor device 100 according to the invention, in which a multiplicity of columnar semiconductor elements 10, each having an active region 40 of quantum well and barrier sections, are arranged on the substrate 30. The semiconductor elements 10 cover on the substrate 30 a surface which z. B. 100 pm ² to 4 mm ² . The at least one semiconductor element, in particular the columnar semiconductor elements 10 according to FIG. 3, can be produced by the following methods. First, a self-organized crystal growth process can be realized in which the growth in length is greater than the width growth, such. In molecular beam epitaxy of GaN (0001) and (In, Ga) N (0001) under nitrogen-rich conditions. The lateral thickness D of the columnar semiconductor elements 10 can be adjusted by the selection and / or structuring of the substrate 30. The columnar shape is used during waxing maintain the quantum well sections and barrier sections. The heights of the quantum well sections and barrier sections are adjusted by the material feed in molecular beam epitaxy. The complete embedding of the quantum well sections in the material of the barrier sections (variant E in FIG. 1) can be achieved by a variation of the process parameters. Alternatively, it is possible to produce the semiconductor elements 10 by etching planar heterostructures. First layers of the quantum well materials and barrier sections are placed ^¬ forth be where then columnar by an etching areas exposed. When etching, a masking can be applied, with which the cross-sectional shape of the columnar semiconductor elements 10 can be adjusted.

In Figures 1 and 2, only the semiconductor elements and the substrate are shown. In practice, further components are provided depending on the specific application of the semiconductor device. For example, approximately purposes (shown gestri ^¬ smiles in Figure 3) in the LED application of contact electrodes to the substrate and a top electrode plate for Kontaktie- provided. The contact electrodes are z. B. connected to a control device and power supply. The semiconductor elements 10 can be shaped according to FIG. 3 so that they fuse together at their upper end, as described by A. Kikuchi et al. (see above), whereby a contact of the semiconductor elements 10 is simplified.

Figure 4 illustrates schematically the effect of the inventively provided geometric dimensioning of the active area on the example of a single pillar-shaped semiconducting ^¬ terelements 10. In the upper part of Figure 4 is a sequence of two sections 11, 13 of the first crystal type with the height hi, which are separated by a barrier section 12 of the second crystal type with the height h ₂ . In addition to the semiconductor element 10, the average lateral stress is shown schematically in the case in which the unstressed lattice constant of the first crystal type (11, 13) is greater than that of the material of the second crystal type. The lattice strain due to the mismatch between sections 11/12 and 12/13 causes a stress, which in this example is compressive (-) in sections 11, 13 and (+) in the adjacent section 12 and the remainder of the semiconductor material (see solid line on the right side of the semiconductor element 10). The unstrained reference state is indicated by the dashed straight line. With the relatively low quotient hi: h ₂ in the upper part, the stresses in the sections 11, 13 of the first crystal type do not or only slightly, ie the stress is mainly determined by the section 12 and the remaining semiconductor material. This situation is typically given in conventional semiconductor elements, but according to the invention also z. B. be set using predetermined, material-dependent reference values targeted. On the other hand, if the quotient hi: h _{2 is} larger in accordance with the lower part of Figure 4, the strain in one of the first crystal type portions (eg 11) will affect the strain in the second of the first crystal type portions (e.g. B. 13) and vice versa, it is reduced overall. Accordingly, the geometrical dimensioning of the heights hi and h ₂ sets the grating tension in the sections 11, 13 of the first crystal type. Alternatively or additionally, this effect can be influenced by the choice of the lateral thickness D of the semiconductor element 10. The influence of the stress on the band structure of a semiconductor crystal illustrated in FIG. 4 is preferably used in light-emitting components (LEDs). Given the composition of the crystal types, the energy of the resulting photons for each individual column can be influenced by the strain. Thus, multi-color light can be generated with a small number of quantum well portions (crystal layers). For example, three quantum well sections are provided.

In an alternative application of the invention in electronic components is exploited that the strain in semiconductors leads to increased mobility of charge carriers. This allows z. As a reduction of the channel of field effect transistors and thus a higher switching speed or packing density in integrated circuits.

According to another application of the invention, the semiconductor element can be used in a thermally active device. Since crystals under compression have an improved thermal conductivity, the thermal conductivity can become anisotropic due to the strain of individual crystal axes. A high thermal conductivity allows the dissipation of heat loss from electronic components, while a low heat conductivity ^{¬ can} increase the efficiency of thermoelectric systems.

FIG. 5 illustrates an experimental result which illustrates the shift of the emission wavelength of an LED test structure according to the invention as a function of the size h _{2 of} the barrier sections. As the height h _{2 of} the barrier sections decreases in the range of 23 nm to 1 nm, it changes the wavelength of the light emission from 600 nm to 650 nm (intensity I, relative units). This effect can be ^¬ uses to set selectively, depending on the geometric dimensions of the active area of the semiconductor elements, a light emission having a desired spectral distribution.

The features of the invention disclosed in the foregoing description, drawings and claims may be significant to the realization of the invention in its various forms both individually and in combination.

Claims

CLAIMS 1. A method of manufacturing a semiconductor device

(100) comprising forming on a substrate (30) at least one columnar or wall-shaped semiconductor element (10, 20) extending in a main direction (z), wherein

- Along the main direction in an active area (40) at least two sections (11, 13, 21, 23) of a first

Crystal type and between which a portion (12, 22) of a second crystal type are respectively formed at predetermined heights (hi, h ₂ ), the first and second crystal types having different lattice constants, and

each of the sections (11, 13, 21, 23) of the first crystal type has a lattice strain which depends on the lattice constant in the section (12, 22) of the second crystal type,

characterized in that

- A targeted adjustment of optical, electrical, mechanical and / or thermal properties of the semiconductor element (10, 20) takes place by at least one of the height (h ₂ ) of the portion (12, 22) of the second crystal type and a lateral thickness (D) of the active region (40) perpendicular to the main direction (z) is formed in such a way that the lattice strain in one of the sections (11) of the first crystal type additionally depends on the lattice constant in the other section (13) of the first crystal type.

2. The method according to claim 1, wherein

at least one quotient of the heights (hi, h ₂ ) of adjacent sections (11, 12, 13, 21, 22, 23) of the first and second crystal types and / or a quotient of the height (H) and the lateral thickness (D) of the active region (40) is formed in this way in that the lattice strain in one of the first crystal type portions (11) depends on the lattice constant in the other portion (13) of the first crystal type.

3. The method according to claim 2, wherein

- If the controlled adjustment of optical, electrical, me ^¬ chanical and / or thermal properties of the semiconductor element (10, 20) by adjusting the at least one quotient of the heights (h _x, h ₂₎ of adjacent exhaust sections (11, 12, 13, 21, 22, 23) of the first and second

Crystal type and / or the quotient of the height (H) and the lateral thickness (D) of the active region (40) predetermined, mate ^¬ rialabhängige reference values are used.

4. The method according to any one of claims 2 or 3, wherein

- The at least one quotient of the heights (hi, h ₂ ) of adjacent portions (11, 12, 13, 21, 22, 23) of the first and second crystal type and / or the quotient of the height (H) and the lateral thickness (D ) of the active region (40) are formed such that the optical, electrical, mechanical and / or thermal properties of all sections (11, 21, 13, 23) of the first crystal type are the same.

5. The method according to any one of claims 2 or 3, wherein - the at least one quotient of the heights (h _a , h ₂ ) Benach ^¬ barter sections (11, 12, 13, 21, 22, 23) of the first and second crystal type and / or the quotient of the height (H) and the Lateraldicke (D) of the active region (40) in such a way ge ^¬ forms that the optical, electrical, mechanical and / or thermal properties of at least two of the

Sections (11, 21, 13, 23) of the first crystal type are different.

6. The method according to any one of the preceding claims, wherein

- The portions (11, 21, 13, 23) of the first crystal type in a thickness direction (x) perpendicular to the main direction (z) of the semiconductor element (10, 20) in the material of the second crystal ^¬ type are embedded.

7. The method according to any one of the preceding claims, with the step

- Forming a plurality of semiconductor elements (10, 20) on the substrate (30).

8. The method according to claim 7, wherein

- The quotients of the heights (h _x , h ₂ ) of adjacent sections (11, 12, 13, 21, 22, 23) of the first and second

Crystal type and / or the quotients of the heights (H) and the lateral thicknesses (D) of the active regions (40) of the semiconductor elements (10, 20) are formed such that the optical, electrical, mechanical and / or thermal properties of the own First crystal type portions (11, 13, 21, 23) of all the semiconductor elements (10, 20) are the same.

9. The method according to claim 7, wherein

- the quotients of the heights (hi, h ₂ ) of adjacent sections (11, 12, 13, 21, 22, 23) of the first and second

Crystal type and / or the quotients of the heights (H) and the lateral thicknesses (D) of the active regions (40) of the semiconductor elements (10, 20) are formed such that the semiconductor elements (10, 20) by each optically different see , electrical, mechanical and / or thermal properties of the sections (11, 13, 21, 23) of the first crystal type.

10. The method according to any one of the preceding claims, wherein the at least one semiconductor element (10) is made of at least one semiconductor selected from the following group:

Nitride-based semiconductors, in particular gallium nitride-based semiconductors,

Arsenide-based semiconductors, in particular gallium arsenide-based semiconductors,

Antimonide-based semiconductors, in particular gallium antimonide-based semiconductors,

Phosphide-based semiconductors, in particular gallium phosphate-based semiconductors,

- Silicon-based semiconductors, and

- germanium-based semiconductors.

A semiconductor device (100) comprising at least one columnar or wall-shaped semiconductor element (10, 20) on a substrate (30), said semiconductor element (10, 20) extending in a main direction (z), wherein

at least two sections (11, 13, 21, 23) of a first crystal type are provided along the main direction in an active area (40) and between these a section (12, 22) of a second crystal type each having a predetermined height distinguish first and second crystal types with respect to their lattice constants, - and

- each of said sections (11, 13, 21, 23) of the first type having a crystal lattice strain, which depends on the Gitterkon from ^¬ ^¬ constants in the section (12, 22) of the second crystal type,

characterized in that

- At least one of the height (h2) of the portion (12, 22) of the second crystal type and a lateral thickness (D) of the active region (40) perpendicular to the main direction (z) is selected such that the grid strain in one of the Abschnit - te (11) of the first crystal type additionally depends on the lattice constant in the other section (13) of the first crystal type. 12. The semiconductor device according to claim 11, wherein

at least a quotient of the heights (hi, h2) of adjacent portions (11, 12, 13, 21, 22, 23) of the first and second crystal types and / or a quotient of the height (H) and the lateral thickness (D) of the active region (40) is selected such that the lattice strain in one of the first crystal type portions (11) depends on the lattice constant in the other portion (13) of the first crystal type, and / or

- at least one quotient of the heights (hi, h2) of adjacent sections (11, 12, 13, 21, 22, 23) of the first and second crystal type and / or a ratio of the height (H) of the acti ^¬ ven area (40 ) and the lateral thickness (D) of the semiconductor element (10) is selected to be equal to predetermined, material-dependent reference values. 13. The semiconductor device according to claim 11 or 12, wherein

the at least one quotient of the heights (hi, h ₂ ) of adjacent sections (11,

12, 13, 21, 22, 23) of the first and second crystal types and / or the quotient of the height (H) and the lateral thickness (D) of the active region (40) is selected such that the optical, electrical, mechanical and / or thermal properties of all sections (11, 21,

13, 23) of the first crystal type are the same.

14. A semiconductor device according to claim 11 or 12, wherein - the at least one quotient of the heights (hi, h ₂ ) of adjacent portions (11, 12, 13, 21, 22, 23) of the first and second crystal types and / or the quotient from the height (H) and the lateral thickness (D) of the active region (40) is selected such that the optical, electrical, mechanical and / or thermal properties of at least two of the portions (11, 21, 13, 23) of the first crystal type are different.

15. A semiconductor device according to any one of claims 11 to 14, comprising

a plurality of the semiconductor elements (10) disposed on the substrate (20).

16. The semiconductor device according to claim 15, wherein

the quotients of the heights (hi, h2) of adjacent portions (11, 12, 13, 21, 22, 23) of the first and second crystal types and / or the quotients of the heights (H) and lateral thicknesses (D) of the active ones Regions (40) of the semiconductor elements (10, 20) are selected such that the optical, electrical, mechanical and / or thermal properties of the quantum well sections (11) of all semiconductor elements (10, 20) are the same.

17. A semiconductor device according to claim 15, wherein

the quotients of the heights (hi, h ₂ ) of adjacent sections (11, 12, 13, 21, 22, 23) of the first and second crystal types and / or the quotients of the heights (H) and the lateral thicknesses (D) of active regions (40) of the semiconductor elements (10, 20) are selected such that the semiconductor elements (10, 20) are distinguished by respectively different optical, electrical, mechanical and / or thermal properties of at least two of the quantum well sections (11).

18. A semiconductor device according to one of claims 11 to

17, at the

- The at least one semiconductor element (10) comprises at least one semiconductor, which is selected from the following group:

- Nitride-based semiconductors, in particular gallium nitride-based semiconductors

- Silicon-based semiconductors, and

- germanium-based semiconductors.

19. A semiconductor device according to one of claims 11 to

18, the

- Is a light-emitting, electronic, opto-electronic, electro-mechanical or thermoelectric device.