WO2004113596A1 - Method and device for the drawing of single crystals by zone drawing - Google Patents

Abstract

The invention relates to the field of material technology and concerns a method and device for application to intermetallic compounds or semiconductors, for example. The aim of the invention is the disclosure of a method and device by means of which an improved quality for the single crystal may be achieved. Said aim is achieved by means of a method in which the flow, within the melt, is influenced by a volume force, generated by a phase shift between the electrical currents flowing in two induction coils, to give a radial/meridional flow in the melt which may be controlled in direction and strength and furthermore by a device in which a secondary coil is arranged above or below the primary coil, both coils being provided with a dedicated resonant circuit, which may be adjusted with a phase shift between the both coils.

Description

Method and device for pulling single crystals by pulling zones

The invention relates to the field of materials science and relates to a method and an apparatus for pulling single crystals by pulling zones, which are used for example for intermetallic compounds or semiconductors.

The zoning of single crystals is known in the prior art (J. Böhm, inter alia: "Handbook of Crystal Growth", Ed .: DTJ Hurle, Vol. 2, Part A, 213-257, 1994) and becomes on an industrial scale Production of single-crystal materials used. A basic diagram of zone melting is shown in Fig. 1. An induction coil 4 in which a high-frequency current flows is used to melt the starting material 3 in zone 2, which then solidifies as a single crystal 1 when the material is pulled in the vertical direction, the resulting single crystal usually being rotated. Depending on the execution of the process, the single crystal can be pulled up or down. The electromagnetic field of the induction coil produces a flow in the molten zone 2 with a double vortex structure, which is shown in FIG. 2. This flow is always directed inwards in the middle of the zone, while in the vicinity of the two ends of the melting zone the flow is always directed radially outwards. The resulting flow in the melting zone is next to electromagnetic forces are also generated by buoyancy and marangoni forces as well as by the rotation of rods or crystals. The geometry of the solidifying phase boundary is adjusted according to the temperature distribution prevailing in the rod, which in turn is influenced by the flow conditions.

Especially in the case of refractory materials, the heat radiation from the molten zone leads to a phase boundary that is always concave at the edge of the solidifying single crystal, which promotes polycrystalline growth. It prevents the cultivation of complex multicomponent intermetallic compounds across the entire cross-section in single-crystal form.

Studies have been carried out for flow control during zone pulling and the associated improvements in crystal quality and process stability (A. Mühlbauer, inter alia: Journal of Crystal Growth, Vol. 151, 66-79, 1995; S. Otani, inter alia: Journal of Crystal Growth , Vol. 66, 419-425, 1984; SY Zhang, inter alia: Journal of Crystal Growth, Vol.243, 410-418, 2002), in which an optimization of the process parameters geometry of the induction coil, current in the induction coil, rotation of rod or crystal and pull rate is suggested. Attempts have been made to achieve homogenization of the dopant distribution by varying the crystal rotation, by shifting the induction coil relative to the crystal axis, or by optimizing the shape of the induction coil. All these solutions have in common that the basic diagram of the process shown in FIG. 1 is only modified geometrically, but is not changed further. In particular, in all of these proposals the flow structure essentially consisting of a double vortex according to FIG. 2 is not changed qualitatively.

Work is also known in which the flow is subjected to an influence via additional magnetic fields. DE 197 04 075 C2 describes a combination of a rotating and static magnetic field for the production of single crystals in closed ampoules, and DE 195 29 381 A1 describes the use of combined magnetic fields for Czochralski growth. Due to the free liquid surfaces that occur during zone pulling, these types of flow influencing cannot be used for zone pulling. The application of a rotating magnetic field when pulling zones is described in DD 263 310 A1, but with the aim of completely eliminating forced convection in the melt. DE 100 51 885 A1 describes a solution for flow control during zone pulling, in which the superposition of crystal rotation and rotating magnetic field is used, both being rotated in opposite directions of rotation. The significant improvement in the homogeneity of the dopant distribution found in this way is described in DE 100 51 885 A1 primarily as a result of the change in the flow structure resulting from the interaction of crystal rotation and rotating magnetic field from a double vortex structure to a single vortex, which in the center of the melt becomes the starting material. ie directed away from the single crystal, led back. To do this, however, a rotating magnetic field must be added externally to the breeding process. The rotating magnetic field alone primarily generates a flow in the azimuthal direction. A high azimuthal rotation is usually required to generate a significant radial-meridional flow, which clearly limits the application of this solution. A primary flow drive in the radial-meridional direction would be required for the desired transition from a double vortex structure to a single vortex.

The object of the present invention is to provide a method and a device for pulling single crystals by pulling zones, with which an improved stability of the growth process and an improved quality of the single crystal as well as a targeted, well controllable influencing of the shape of the solid-liquid phase boundary is achieved ,

The object is achieved by the invention specified in the claims. Further training is the subject of the subclaims.

In the method according to the invention for pulling single crystals by pulling zones, the flow in the area of the melt is driven by an electromagnetically generated volume force to form a radial-meridional flow which can be controlled in direction and strength. This electromagnetic volume force arises through the use of a second induction coil, which is arranged above or below the primary induction coil, and a phase shift between the electrical currents in the two induction coils. The secondary coil can be connected to a power supply, including that of the primary coil, but it can also advantageously have no connection to a power source.

The phase shift of the electrical currents is advantageously generated in the resonant circuits of the two induction coils, the phase shift of the electrical currents advantageously being realized by regulating the capacitive force in the secondary resonant circuit and particularly advantageously a phase shift of the electrical currents of 90 °. Such a phase shift of 90 ° can advantageously be achieved by setting the capacitive force in the secondary resonant circuit in the amount of C ₂ = (ω ² L ₂ ) ^"1 with GF2πf as the frequency of the electrical current in the primary circuit and L ₂ as the inductance of the secondary coil.

It is also advantageous if the amplitude of the currents is limited by an ohmic resistor, with the same amplitude of the currents being advantageously set in both circuits.

It is also advantageous if the electromagnetically generated volume force is influenced by regulating the frequency of the currents and / or the current strength and / or the vertical spacing of the coils and / or the inner diameter of the coils and / or the capacitance and the ohmic resistance in the secondary resonant circuit, wherein a vertical distance between the two coils is particularly advantageously set, which corresponds to the radius of the single crystal and / or a penetration depth δ of the magnetic field into the single crystal belonging to the frequency ω of the primary current, δ = (2 / μσω) ^{"1/2 is} set, which corresponds to the radius of the crystal, where μ is the magnetic permeability and σ is the electrical conductivity of the single crystal material. In the device according to the invention for pulling single crystals by pulling zones, a secondary coil is arranged above or below the primary coil.

The secondary coil advantageously has no connection to a current source.

The secondary coil is likewise advantageously integrated into a resonant circuit with adjustable capacitance and adjustable ohmic resistance.

A further advantageous embodiment of the invention is if the secondary coil is arranged above the primary coil for realizing a melt flow upward on the free surface of the melt zone or if the secondary coil is arranged under the primary coil for realizing a melt flow downward on the free surface of the melt zone ,

The solution according to the invention makes it possible to influence the geometry of the phase interface in a targeted manner and to improve the homogeneity of the dopant distribution when pulling zones of single crystals by influencing the flow. The flow structure in the molten zone is changed from a double vortex structure to a predominant single vortex of adjustable strength and direction.

The solution specified in DE 10051885 A1 does not achieve this, since the radial-meriodinal flow is influenced only indirectly via the primary rotation of the melt. According to the solutions of the prior art, a high azimuthal rotation would be required to generate the required radial-meridional flow, which significantly limits the application of this solution. With the solution according to the invention, the influencing of the flow structure can be controlled in a wide range, in particular without the detour via the azimuthal flow.

The flow conditions in the zone have a decisive influence on the distribution of dopants in the single crystal, which should be as homogeneous as possible. The distribution of the dopants and the shape of the solid-liquid phase boundary on solidifying single crystals are both dependent on the flow conditions in the zone. A targeted influencing of these variables is consequently possible through a targeted control of the flow.

The function of the device according to the invention in which a second induction coil is added to the induction coil present in the device according to the prior art is as follows.

The flow in the area of the melt is driven by an electromagnetically generated volume force to form a radial-meridional flow. The volume force is generated by the phase shift of the currents flowing through the two induction coils.

It is particularly advantageous if the secondary coil is not connected to a power supply and this circuit of the secondary coil has a capacitor with adjustable capacitance and an adjustable ohmic resistance. The current in the secondary coil is then induced solely by the primary current in the primary coil. By regulating the capacitor in the secondary circuit, a phase shift is generated between the two resonant circuits, which leads to a flow-driving volume force in the molten zone.

Figures 1 and 2 show the principle of zone pulling according to the prior art and the dominant, electromagnetically driven flow in the molten zone with the associated shape of the resulting phase boundaries liquid-solid.

The solution according to the invention is shown schematically in principle in FIG. 3. A secondary coil 5 is added to the primary coil 4. An advantageous electrical scheme for the method according to the invention is shown in FIG. 4. The electrical current in the secondary coil is only generated inductively between the primary coil Li and the secondary coil L ₂ ; the secondary circuit has no direct connection to a power supply. The secondary circuit contains a controllable ohmic resistor R ₂ and a controllable capacitor C ₂ .

The effect of this device according to the invention and the method according to the invention consists essentially in the following. Due to the phase shift of the electrical currents in the two circles with the two coils, a volume force is generated electromagnetically, which drives the flow within the melting zone.

The phase shift of the currents can advantageously be adjusted by regulating the capacitance C _{2 of} the secondary circuit. The or the ohmic resistors Ri, R ₂ only have the function of limiting the currents in their amplitude. The phase shift between the two circles provides a volume force in the melted zone that directly and directly drives a radial-meridional flow. This flow drive is strongest when the phase shift between the electrical currents in the two coils is exactly 90 °, which can be achieved by choosing C ₂ = (ω ² L ₂ ) ^"1 with ω = 2πf as the frequency of the electrical current The resulting flow in the melting zone as a result of the device according to the invention essentially consists of a toroidal single vortex. Depending on the strength of this flow, the shape of the phase boundary can be influenced in a solid-liquid manner. Figure 5 shows this single vortex structure of the electromagnetically driven flow as The result of a numerical simulation for the growth parameters specified in embodiment example 1. The change in the shape of the phase boundary from a shape that is predominantly concave over the radius of the crystal to a predominantly convex geometry can be clearly seen, thereby considerably reducing the occurrence of polycrystalline growth.

The method according to the invention permits flexible and controllable influencing of the flow in the melt in a wide range. Variables and parameters to be optimized for the respective breeding arrangement are frequency and current strength of the primary circuit, the vertical distance between the two coils, the inner diameter of the coils and capacitance C ₂ and ohmic resistance R _{2 of} the secondary circuit. If the secondary coil is arranged above the primary coil, the direction of flow of the individual vortex on the free surface of the melting zone is directed upwards. The opposite flow direction results when the primary coil is located above the secondary coil. The flow drive as a result of the device according to the invention is strongest when the vertical distance between the two coils corresponds to the radius of the crystal. It is also strongest when the Frequency ω of the primary current, penetration depth δ of the magnetic field into the crystal, δ = (27μσω) ^"1/2 , corresponds to the radius of the crystal, where μ denotes the magnetic permeability and σ the electrical conductivity of the crystal material.

The invention is explained in more detail using several exemplary embodiments.

example 1

A nickel single crystal with a diameter of 6 mm is produced by zone pulling with the device according to the invention. The secondary coil is arranged above the primary coil. The design of the electromagnetic parameters was based on numerical simulations. The frequency of the primary current is 250 kHz, its amplitude is 130 A. The vertical distance between the two coils is 3 mm. The capacitance of the secondary circuit is 446 nF, its ohmic resistance is 51.2 mΩ. As a result of the use of the method and the device according to the invention, the flow in the melted zone is directed upwards on the free surface of the melt. As a result, the phase boundary made visible by doping with 5 at% Si shows a significant improvement in its shape. While in the comparative cultivation with a device according to the prior art, the phase boundary of the melt single crystal predominantly has concave edge regions, an almost flat, slightly convex phase boundary is achieved by means of the solution according to the invention. The stability of the breeding process was significantly increased compared to conventional technology.

Example 2

In accordance with the conditions in Example 1, a Ce-Pd-Co-Si single crystal of 6 mm in diameter was produced by zone pulling with the device according to the invention. Until now, single crystals could not be produced from these materials by means of zone pulling according to the prior art method. A stable breeding regime was achieved with the solution according to the invention. Here too, an improved form of the phase boundary could be achieved.

Claims

claims 1. A method of pulling single crystals by zone pulling, in which the flow in the region of the melt is driven by a volume force, which is generated by means of a phase shift between the electrical currents flowing through two induction coils, to form a directionally and strength-controllable one , radial-meridional flow of the melt. 2. The method according to claim 1, wherein the phase shift of the electrical currents is generated in resonant circuits of the two induction coils. 3. The method according to claim 2, wherein the phase shift of the electrical currents is realized by regulating the capacitance in the secondary resonant circuit. 4. The method according to claim 2, wherein a phase shift of the electrical currents of 90 ° is set. 5. The method of claim 4, wherein the capacitance in the secondary resonant circuit C ₂ = (ω ² L ₂ ) ^"1 with ω = 2πf as the frequency of the electric current in the primary circuit and L ₂ as the inductance of the secondary coil is calculated and set. 6. The method according to claim 1, wherein the amplitude of the electrical currents is limited by an ohmic resistor. 7. The method according to claim 6, in which an equal amplitude of the currents is set in both circuits. 8. The method according to claim 1, wherein the electromagnetically generated volume force by regulating the frequency of the currents and / or the current intensity and / or the vertical distance of the coils and / or the inner diameter of the coils and / or the capacitance and ohmic resistance in the secondary resonant circuit being affected. 9. The method of claim 1, wherein a vertical distance between the two coils is set, which corresponds to the radius of the single crystal. 10. The method of claim 1, wherein a penetration depth δ of the magnetic field into the single crystal belonging to the frequency ω of the primary current is set, δ = (2 μσω) ^"12 , which corresponds to the radius of the crystal, where μ is the magnetic permeability and σ the electrical conductivity of the single crystal material. 11. Device for pulling single crystals by pulling zones, in which a secondary coil is arranged above or below the primary coil, both coils having their own resonant circuit, by means of which a phase shift between the two coils can be set. 12. The apparatus of claim 11, wherein the secondary coil has no connection to a power source. 13. The apparatus of claim 11, wherein the secondary coil is arranged above the primary coil to realize a melt flow upward on the free surface of the melting zone. 14. The apparatus of claim 11, wherein the secondary coil is arranged below the primary coil to realize a melt flow down on the free surface of the melting zone. 15. The apparatus of claim 11, wherein the secondary coil is integrated in a resonant circuit with adjustable capacitance and controllable ohmic resistance.