WO2007063259A1 - Large-capacity high-temperature effusion cell - Google Patents

Abstract

The invention relates to a large-capacity high-temperature effusion cell intended for vaporizing materials for molecular beam epitaxy machines, comprising a crucible support (2) of elongate shape, at least one refractory crucible (1) also of elongate shape, a crucible heater (7) surrounding said crucible (1) and a thermal shield (6) surrounding the crucible support (1). According to the invention, the effusion cell comprises at least two crucibles (1) placed around the axis of symmetry (5) of the crucible support (2).

Description

 HIGH TEMPERATURE EFFUSION CELL WITH HIGH CAPACITY

The present invention relates to a high-capacity, high-temperature effusion cell for vaporizing materials for molecular beam epitaxy (MBE) machines.

In the semiconductor industry, the production of semiconductor wafers ("wafers") is obtained by depositing ultra-thin films of ferromagnetic materials (iron, cobalt, nickel, etc.) on silicon substrates.

In this industry, there are several semiconductor wafers on a tray having a size of 200 to 300 mm.

Therefore, high capacity EJM machines and therefore large effusion cells are required to enable ferromagnetic material deposits on such surfaces.

"Effusion cells known as" high temperature "(1600 ^° C.) are known, such as that of US Pat. No. 5,827,371. These cells use Joule heating means to evaporate the ferromagnetic materials.

However they are small capacities between 6 and 35 cm ³ . The future needs to equip the EJM production machines require the development of cells called "high temperature" (145O ⁰ C) and large capacity (about 1000 cm ³ ).

These cells comprise a conical refractory crucible. This shape makes it possible to direct the flow of sublimed materials towards the substrate in order to optimize the uniformity of the deposit. This flow takes the form of the crucible, it is therefore conical.

To cover surfaces of 200 to 300 mm, it is difficult to increase the diameter of the crucible to increase the capacity of the effusion cell.

Indeed, the thermal gradient in the material to be evaporated, from the edge of the crucible which is heated to the center of the crucible, is too high. The temperature of the material inside crucible is no longer uniform. The material has "cold" spots, resulting in non-uniform material deposition on the substrate.

EJM machines are known that use three effusion cells to increase the evaporation capacity of the machine. These cells are arranged at three different locations (or taps). They may contain the same material to evaporate.

However, the evaporation capacity of such an EJM machine is insufficient to meet current needs, it does not reach 1000 cm ³ and its manufacturing cost is high.

Therefore, the objective of the present invention is therefore to provide a high temperature effusion cell having a large capacity allowing the evaporation of ferromagnetic materials uniformly over a larger surface of the substrate, simple to implement and to lower cost with cells arranged at the same location.

To this end, the invention relates to a high-capacity high-temperature effusion cell for the vaporization of materials for molecular beam epitaxy machines comprising:

a crucible support of elongate shape with an axis of symmetry having an open upper face and a closed lower face; at least one refractory crucible of shape also elongated with an axis of symmetry, able to contain a material to be evaporated; the crucible being placed inside the crucible holder and having an opening in the vicinity of the upper face of the crucible holder, - a means for heating the crucible surrounding the crucible,

a thermal screening surrounding the crucible holder. According to the invention, the high temperature effusion cell comprises:

at least two crucibles arranged around the axis of symmetry of the crucible support forming a set of crucibles. In various possible embodiments, the present invention also relates to the features which will emerge during the following description, which should be considered in isolation or in all their technically possible combinations:

- the crucibles are of conical shape,

the crucibles are of cylindrical shape,

each cylindrical crucible comprises a conical insert inserted into the opening of said cylindrical crucibles,

the conical insert is made of alumina,

the conical insert is heated,

the heating means of the crucibles are flat filaments; the flat filaments are made of tantalum.

The invention also relates to an effusion source comprising:

at least one thermocouple in contact with a crucible, said thermocouple being connected to a thermocouple conductor, a thermocouple connector connected to the thermocouple conductor,

a power lead connected to the heating means of the crucibles,

at least one power connector connected to the power conductor.

According to the invention, the effusion source comprises an effusion cell as described above.

The invention also relates to a molecular beam epitaxy machine. According to the invention, it comprises at least one effusion source as described above.

The invention will be described in more detail with reference to the accompanying drawings in which:

FIG. 1 is a schematic representation of an effusion cell according to the prior art; FIG. 2 is a schematic representation of a high-capacity high-temperature effusion cell according to a particular embodiment of the invention;

FIG. 3 is a schematic representation of the high-temperature high-capacity effusion cell seen from above according to a particular embodiment of the invention;

FIG. 4 is a schematic representation of a high-temperature high-volume effusion cell seen from above according to another particular embodiment of the invention;

FIG. 5 is a schematic representation of an EJM machine according to a particular embodiment of the invention;

FIG. 1 represents an effusion cell 23 according to the prior art comprising a crucible support 2 of elongate shape with an axis of symmetry 5. This crucible holder 2 has an upper face 3 open and a bottom face 4 closed.

In Figure 1, the crucible holder 2 is elongate and cylindrical. It has an axis of symmetry 5. This effusion cell 23 comprises a refractory crucible

1 also elongated with an axis of symmetry January 1 which is superimposed on the axis of symmetry 5 of the crucible holder 2.

In Figure 1, the crucible 1 is conical. This crucible 1 is able to contain a material to evaporate 24. It is placed inside the crucible holder 2 and has an opening 10 in the vicinity of the upper face 3 of the crucible holder 2.

A means of heating the crucible 7 surrounds the crucible 1. This heating means 7 is commonly of the electric type (Joule effect). The cell 23 operates by thermal process.

A thermal screening 6 surrounds the crucible holder 2.

The material to be evaporated or sublimed 24 is introduced into the refractory crucible 1 whose geometry corresponds to the deposition parameters. This crucible 1 is heated by radiation of a metal carried at high temperature by passage of a current electric. The capacity of such a cell is limited to about 35 cm ³ .

According to one embodiment of the invention, the high-capacity high-temperature effusion cell 23 comprises at least two crucibles 1 arranged around the axis of symmetry 5 of the crucible holder 2 forming a set of crucibles.

Figures 2 and 3 show a particular embodiment of the invention for which the crucible holder 2 comprises three crucibles 1. Figure 3 shows a view from above.

The crucibles 1 may be arranged symmetrically with respect to the axis of symmetry 5. They may also be arranged in a non-symmetrical manner.

They can be conical or cylindrical. In Figures 2 and 3, they are cylindrical.

In this case, a conical insert 9 is inserted into the opening 10 of each crucible 1 to improve the uniformity of the deposit on the substrate 20. It may be of alumina and may be heated by a heating element. The conical shape of the insert 9 makes it possible to orient the flow of sublimed materials, which then takes on a conical shape. These inserts 9 are inserted into crucibles 1 of cylindrical shape.

For reasons of efficiency, it is preferable to use crucibles of slightly conical shape without insert. It is also possible to combine crucibles 1 of conical shape with crucibles 1 of cylindrical shape.

These crucibles 1 may contain the same material to sublimate 24 or different materials.

It is possible to insert more than three crucibles 1, of suitable size, into the crucible holder 2 in order to increase the capacity of the effusion cell. The crucible support 2 is of variable size.

The crucibles 1 may each be surrounded by a flat tantalum filament 7 for heating the material 24 incorporated in each crucible 1. Other types of filament and heating means are possible.

Each crucible 1 can have its own food.

These crucibles 1 make it possible to increase the evaporation diameter while limiting the thermal losses. The temperature of the material to sublimate 24 inside each crucible 1 is almost uniform. The temperature in the center of the crucibles 1 is almost equal to that at the edges of the crucibles 1. The "cold" spots have almost disappeared. The filaments 7 are fed in series by a power supply connected to the power connectors 15.

Each crucible 1 comprises a thermocouple 17. The temperature can be regulated on a single crucible 1.

A single heat shield 6 surrounds the set of crucibles. This thermal screening 6 may consist of different screens that may be composed of tantalum.

The form of the thermal screening surrounding the set of crucibles is variable. It can be optimized as for example in FIG. 4 where it is triangular by surrounding three crucibles 1. The shape of the crucible holder 2 is, in this example, cylindrical.

The effusion cells as described above, allow to reach capacities of 300 cm ³ to 1000 cm ³ .

The invention also relates to an effusion source 19. The crucible holder 2 of the effusion source 19 is supported by a crucible support holder 27. This crucible support holder 27 is fixed to support rods 14 themselves. Connected to a connector flange 13. The effusion source 19 advantageously comprises three support rods 14 as shown in FIG. 2. They make it possible to move the connector flange 13 away from the crucible holder 2, which can reach very high temperatures ( 145O ⁰ C).

A thermocouple 17 measures the temperature of the crucible 1. This thermocouple 17 is connected to a thermocouple conductor 12. The thermocouple lead 12 is connected to a thermocouple connector 16.

The heating means of the crucible 7 is connected to a power conductor 8 which is itself connected to a power connector 15.

The thermocouple connector 16 and the power connector 15 are attached to the connector flange 13.

The effusion source 19 comprises an effusion cell 23 comprising at least two crucibles 1 arranged around the axis of symmetry 5 of the crucible holder 2 forming a set of crucibles.

The invention also relates to EJM machines comprising at least one effusion source 19 as defined above. This type of EJM machine makes it possible to evaporate large molecular flows 18 in enclosures 22 having a vacuum of 10 ^-9 torr and temperatures up to 145 ^° C. With such an effusion source 19, capacity is reached. ranging from 300 cm ³ to 1000 cm ³ , as mentioned above, This effusion source 19 makes it possible to produce uniform deposits on the surface of trays 20 comprising semiconductor wafers and having diameters of up to more than

500 mm.

As shown in the example of Figure 5, combinations of effusion sources are possible by integrating into the EJM machine both a "classical" shedding source.

21 with an effusion source 19 comprising at least two crucibles 1 arranged around the axis of symmetry 5 of the crucible holder (2). EJM machines with high sublimation capacity are obtained, simple to implement and at a low cost.

Claims

1. A high-capacity, high-temperature effusion cell for spraying materials for molecular beam epitaxy machines comprising:

a crucible support (2) of elongate shape with an axis of symmetry (5) having an upper face (3) open and a bottom face (4) closed,

at least one refractory crucible (1) of shape also elongated with an axis of symmetry (1 1), capable of containing a material to be evaporated, said crucible (1) being placed inside the crucible holder (2) and having an opening (10) in the vicinity of the upper face (3) of the crucible holder (2),

a means for heating the crucible (7) surrounding said crucible (1),

a thermal screening (6) surrounding the crucible holder (2), characterized in that it comprises:

- At least two crucibles (1) arranged around the axis of symmetry (5) of the crucible holder (2) forming a set of crucibles.

2. Effusion cell according to claim 1, characterized in that a single heat shield (6) surrounds the set of crucibles.

3. effusion cell according to claim 1 or 2, characterized in that the crucibles (1) are conical.

4. effusion cell according to claim 1 or 2, characterized in that the crucibles (1) are cylindrical.

5. effusion cell according to claim 4, characterized in that each crucible (1) of cylindrical shape comprises a conical insert (9) inserted into the opening (10) of said crucibles (1) of cylindrical shape.

6. effusion cell according to claim 5, characterized in that the conical insert (9) is alumina.

Effusion cell according to claim 5 or 6, characterized in that the conical insert (9) is heated.

8. effusion cell according to any one of claims 1 to 7, characterized in that the heating means crucibles (7) are flat filaments.

9. effusion cell according to claim 8, characterized in that the flat filaments are tantalum.

10. Effusion source comprising:

at least one thermocouple (17) in contact with a crucible (1), said thermocouple (17) being connected to a thermocouple conductor (12),

a thermocouple connector (16) connected to the thermocouple conductor (12),

a power conductor (8) connected to the crucible heating means (7),

- At least one power connector (15) connected to the power conductor (8), characterized in that it comprises an effusion cell (23) according to any one of Claims 1 to 9.

1 1. A molecular beam epitaxy machine characterized in that it comprises at least one effusion source (19) according to claim 10.