CH705797A2 - Ceramic element e.g. lid, for cooperating with part to e.g. form cavity for encapsulation device encapsulating microelectromechanical systems, has metal layer protected by intermetallic layer, which is covered by material part - Google Patents

Abstract

The element e.g. lid (4), has an element body that is intended for forming a metal layer (15) for metallization, where the element is partially covered by the metallization. The metallization comprises a coating for protection against gold oxidation. The metal layer is protected by an intermetallic layer (19), which is covered by a non-diffused material part (12'), where melting point of material e.g. indium and tin, is lower than 250 degrees Celsius. The metal layer comprises a fixing layer (13) fixing against the body. Independent claims are also included for the following: (1) a method for manufacturing an element (2) an encapsulation device (3) a method for manufacturing an encapsulation device.

Description

Field of the invention

The invention relates to a method for manufacturing an encapsulation device for an electromicromechanical system (also known by the abbreviation MEMS from the English term "Micro Electro Mechanical System") and, in particular, for a MEMS of the quartz resonator type.

Background of the invention

The electronic components having a MEMS are generally formed by a hermetically sealed housing in which the MEMS is mounted. The MEMS may for example be a piezoelectric resonator, such as a quartz resonator intended to be connected to an oscillator circuit. Most small crystal resonators, which are used for example in electronic or electromechanical watches, are tuning fork type resonators.

Such quartz resonators are usually enclosed under vacuum in housings, in the case of the generation of low frequency signals provided by the oscillator circuit, or under an inert gas atmosphere. In addition, a portion of the cover may be transparent at a specific wavelength of a light beam to allow optical adjustment of the quartz resonator.

[0004] Generally, such resonators are mounted in housings, for example ceramic, which are relatively flat. These housings comprise a hollow main part of parallelepiped shape inside which is mounted the resonator, and a rectangular cover fixed on the main part.

To ensure the seal between the lid and the main part, currently uses a eutectic metal alloy gasket based on gold and tin which is reported between the two parts and the whole is heated. in order to permanently seal the housing under a controlled atmosphere.

These alloys based on gold and tin have the disadvantages of using intrinsically expensive materials and having a relatively low melting point, that is to say around 278 ° C. This last characteristic limits the possible methods during or after the connection of the housing on its support of use as a printed circuit, for example. It is understood in fact that no heat treatment greater than 280 ° C achieved later connection is possible under risk of loosening of the housing which, even partial, would lose the hermeticity of the device and therefore the performance of the resonator.

Summary of the invention

The object of the present invention is to overcome all or part of the disadvantages mentioned above by proposing a new type of hermetic encapsulation device and its manufacturing process.

In addition, the invention relates to an element arranged to cooperate with another part to form a device for encapsulating a component comprising the element at least partially coated with a metallization characterized in that said metallization comprises at least one layer of metal protected by an intermetallic which is covered by a non-diffused part of a material whose melting point is less than 250 ° C.

Advantageously according to the invention, said at least one metal layer is protected by the (or) intermetallic (s) which forms a protective barrier. In addition, there remains material whose melting point is below 250 ° C for the future formation of the sealing means.

According to other advantageous features of the invention: the element is a cover for closing said encapsulation device; the element is a main part intended to form a cavity (10) of the encapsulation device; the element is formed of ceramic or metal; said at least one metal layer comprises nickel and / or copper and / or gold; said at least one metal layer is formed by the body of the element; said at least one metal layer further comprises a bonding layer against said body of the element; the bonding layer comprises molybdenum and / or tungsten and / or titanium and / or chromium; the intermetallic contains gold; said material having a melting point of less than 250 ° C is indium or tin.

In addition, the invention relates to a method of manufacturing an element arranged to cooperate with another piece to form a device for encapsulating a component comprising the following steps: <tb> a) <sep> form the element; <tb> b) <sep> depositing a metallization comprising at least one layer of metal protected by a coating, characterized in that it further comprises the following steps: <tb> c) <sep> deposit a layer of material having a melting point of less than 250 ° C on the coating; <tb> d) <sep> partially diffuse the material having a melting point of less than 250 ° C into the coating to fully convert the coating into an intermetallic and leave an unexpanded portion of the material whose melting point is less than 250 ° C.

Advantageously according to the invention, the material whose melting point is less than 250 ° C which is deposited is a pure material and not a eutectic alloy based on gold for the future formation of the sealing means.

According to other advantageous features of the invention: the element is formed of ceramic or metal; said at least one metal layer comprises nickel and / or copper and / or gold; said at least one metal layer is formed by the body of the element; the method comprises, between step a) and step b), a step of depositing a bonding layer for said at least one layer of metal; the bonding layer comprises molybdenum and / or tungsten and / or titanium and / or chromium; the coating has gold.

In addition, the invention relates to an encapsulation device arranged to receive a component comprising a housing comprising a main part forming a cavity which is hermetically closed by a cover by means of sealing means characterized in that the sealing means comprise an intermetallic formed by at least one metal with a material whose melting point is less than 250 ° C to allow its interdiffusion in the liquid state with said at least one metal.

According to other advantageous features of the invention: the sealing means comprise a second intermetallic adjacent to said first intermetallic formed by at least one second metal with the material whose melting point is less than 250 ° C; said at least one second metal comprises gold; the sealing means comprise a third intermetallic of substantially identical nature to the first intermetallic, the first and the third intermetallic being located on each side of the second intermetallic; the sealing means comprise at least one attachment layer against the housing; the sealing means comprise a layer of said at least one metal between the cover and said intermetallic and between the main part and said intermetallic; the sealing means comprise a layer of said at least one metal between the main part and said intermetallic and in the lid; said material having a melting point of less than 250 ° C is indium or tin; said at least one metal comprises nickel and / or copper and / or gold; the housing is formed of ceramic and / or metal; the cavity is under vacuum or controlled atmosphere.

Finally, the invention relates to a method of manufacturing a device for encapsulating a component characterized in that it comprises the following steps: <tb> e) <sep> forming said component; <tb> f) <sep> fabricating a main portion having a first metallization and forming a cavity, and a lid having a second metallization, the main portion or the lid being made according to the method according to one of the preceding variations; <tb> g) <sep> mount the component in the cavity; <tb> h) <sep> assemble the non-diffused part of the material whose melting point is less than 250 ° C during step d) of the main part or the lid against respectively the metallization of the lid or the part main; <tb> i) <sep> completely diffuse the non-diffused portion of the material having a melting point of less than 250 ° C into said adjacent metallization to fully convert the material having a melting point of less than 250 ° C into a second intermetallic able to seal said component in the encapsulation device.

From the current housings whose metallizations already include nickel, it is therefore understood that only the low melting point material is necessary to be reported to achieve hermeticity of the housing. In addition, the nickel base is substantially less expensive than the gold base and also makes it possible to obtain at least one intermetallic whose melting point is located at a higher temperature than the current sealing means and therefore compatible with the temperatures used in standard methods of mounting the device, without risk of loss of hermeticity.

In addition, compared to the current sealing means, it has appeared that the second (or) intermetallic (s) formed (s) from nickel has slower growth kinetics which allows advantageously to better control their formation. Finally, the second intermetallic (s) is formed solely from the said at least one nickel layer of the main part by means of the first (s) intermetallic (s) which blocks any other diffusion. .

According to other advantageous features of the invention: the method comprises, between step f) and step g), the step of depositing a protective layer to protect said formed metallization not covered by the non-diffused portion; the main part and the lid are formed of ceramic and / or metal; step i) is carried out under vacuum or in a controlled atmosphere; said component is a quartz tuning fork resonator; the material whose melting point is below 250 ° C is indium or tin.

Brief description of the drawings

Other features and advantages will become apparent from the description which is given below, for information only and in no way limitative, with reference to the accompanying drawings, in which: <tb> - fig. 1 <sep> is a top view of the electronic component according to the invention; <tb> - fig. 2 <sep> is a view according to section A-A of FIG. 1of the electronic component according to the invention; <tb> - figs. 3 and 4 <sep> are enlarged views located on the lid before and after the first diffusion according to the invention; <tb> - fig. <Sep> is an enlarged view located on the main part before the second diffusion according to the invention; <tb> - fig. 6 <sep> is an enlarged view located on the interface between the main part and the cover after the second diffusion according to the invention; <tb> - fig. 7 <sep> is a block diagram of the manufacturing process according to the invention <tb> - fig. 8 <sep> is a sectional view of an example of sealing means obtained according to the invention; <tb> - fig. 9 <sep> is a partial and enlarged view of FIG. 8; <tb> - figs. 10 and 11 <sep> are enlarged localized views on a first cover variant before and after the first diffusion according to the invention; <tb> - figs. 12 and 13 <sep> are enlarged localized views on a second cover variant before and after the first diffusion according to the invention.

Detailed Description of the Preferred Embodiments

In the following description, all parts of the component that are well known to those skilled in this technical field, will not be explained in detail.

The electronic component 1 is shown in a simplified manner in FIGS. 1 and 2. It mainly comprises an encapsulation device 3 for receiving a MEMS 5 hermetically. The encapsulation device 3 comprises a housing 7 formed by a hollow main part 2 and a cover 4 intended to close the hollow part 2 by means of sealing means 6.

In the example illustrated in FIGS. 1 and 2, the MEMS 5 shown is a quartz tuning fork resonator, however other types of MEMS requiring encapsulation under vacuum or controlled atmosphere are also applicable.

The hollow portion 2 is generally of parallelepipedal shape and has a bearing 8 in the inner cavity 10 for fixing the MEMS 5 cantilevered. The free ends of the walls surrounding the cavity 10 are intended to receive the lid 4 of substantially rectangular shape by means of the sealing means 6 in order to hermetically seal the MEMS 5 in the encapsulation device 3.

By way of example, the housing 7, that is to say the hollow portion 2 and the cover 4, may be 5 mm long, 3.2 mm wide and 1.08 mm high. . In addition, the housing 7 is preferably made of ceramic according to a usual technique.

The sealing means 6 are formed by a succession of layers for adhering to the ceramic and forming the layer allowing the hermeticity. Advantageously according to the invention, the sealing means 6 comprise a nickel-based alloy associated with a material whose melting point is low, that is to say much lower than that of nickel such as for example order of 250 ° C maximum. Preferably, the material used may be indium or tin.

These alloys In-Ni or Ni-Sn, which may comprise several intermetallic, are obtained by a weld involving a solid-liquid interdiffusion, that is to say that the melting point difference between indium or tin relative to that of nickel melts one of these first materials and spread it in the solid nickel layer to form intermetallic.

These welds can be made at "low" temperature, that is to say below 250 ° C while accepting subsequent heat treatments at much higher temperatures induced by the melting points of the resulting intermetallic, that is to say between 400 ° C and 800 ° C.

Advantageously according to the invention, the ceramic casings 7 currently marketed include metallizations 9, 11 which already include at least one layer of nickel as visible in FIGS. 3and 5.

Typically as shown in FIG. 3, the metallization 9 of the lid 4 comprises several layers. A first optional bonding layer 13 formed with, for example, molybdenum or tungsten and at least one metal layer 15 such as nickel. The metallization 9 may also include a coating 17 for protection against oxidation, for example gold. The bonding layers 13 and metal 15 have thicknesses of 10 μm and 5 μm, respectively, while the protective coating 17 is approximately 0.75 μm.

Similarly, as can be seen in FIG. 5, the metallization 11 of the main part 2 also comprises several layers. A first optional adhesion layer 14 formed with, for example, molybdenum or tungsten and at least one metal layer 16 such as nickel. The metallization 11 may also include a layer 18 for protection against oxidation, for example gold. The adhesion layers 14 and the metal layers 16 have thicknesses of 10 μm and 5 μm respectively while that of the protection layer is approximately 0.75 μm.

Therefore, it is understood that, to form the sealing means 6 in an intermetallic indium-nickel or nickel-tin, a single layer 12 of pure indium or pure tin is necessary to achieve the interdiffusion weld solid-liquid according to the invention.

Therefore, the MEMS 5 can, using the sealing means 6, be sealed under vacuum or controlled atmosphere in the cavity 10 of the encapsulation device 3 with less expensive materials and at least obtaining an intermetallic whose melting point is at a higher temperature than the current sealing means.

In the example illustrated in FIGS. 1 and 2, the MEMS 5 is a conventional quartz tuning fork consisting of two parallel branches 14, 16 for vibrating in bending mode, the common base 13 of which is fixed on the bearing surface 8. The metallization layers of the MEMS 5 necessary for actuation piezoelectric as well as the connection pads to an integrated circuit 15 having, for example, an oscillator stage are not presented in detail because these elements are not critical for the application of the invention.

The method 21 for manufacturing the encapsulation device 3 will now be explained with reference to FIGS. 3 to 7. The method 21 comprises a first step 23 intended to manufacture, independently, during phases 22, 24 and 26, respectively the MEMS 5, the cover 4 and the hollow portion 2.

Thus, if the MEMS 5 is a quartz diapason resonator, the phase 22 may consist of etching a wafer in a quartz monocrystal, then engraving the body of the tuning fork in the thickness of this wafer to finally instrument the tuning fork, that is to say deposit the electrically conductive layers necessary for its operation.

The lid 4 is preferably formed using a ceramic during phase 24. To do this, usually, one or more ceramic sheets are machined, stacked and fixed on each other. Then, the cover 4 is partially metallized to allow future cooperation with the main part 2. According to the invention, after the formation of the cover 4, is therefore deposited at least one layer 15 of metal protected by a coating 17.The cover 4 thus comprises several layers of metals. A first optional bonding layer 13 formed with, for example, molybdenum and / or tungsten and / or titanium and / or chromium and at least one metal layer such as nickel.

The attachment layers 13 and metal 15 may have thicknesses of respectively 10 microns and 5 microns while the protective coating 17 is about 0.75 microns.

The main part 2 is preferably formed using a ceramic during phase 26. To do this, in the usual manner, several ceramic sheets are machined, stacked and fixed on each other. Then, the main part 2 is partially metallized to allow future cooperation with the cover 4.

According to the invention, after the formation of the main portion 2, is therefore deposited at least one metal layer 16 as nickel optionally protected by a coating 18 which may for example be made of gold. In addition, prior to the deposition of layer 16, for example nickel, an intermediate step for depositing an adhesion layer 14 for the layer 16 can be performed.

As explained above, the main part 2 thus comprises several layers of metals. A first optional adhesion layer 14 formed with, for example, molybdenum and / or tungsten and / or titanium and / or chromium and at least one layer of metal 16. The layer 16 may comprise a protective coating 18 against oxidation for example in gold as shown in FIG. 5.

The adhesion layers 14 and nickel 16 may have thicknesses of respectively 10 microns and 5 microns while the protective coating 18 optional is about 0.75 microns. These deposits can be made, for example, by screen printing, electroplating or physical vapor deposition.

Advantageously according to the invention, the phase 24 or the phase 26 of the process 21 continues with a step intended to deposit a layer 12 of a material whose melting point is less than 250 ° C. on the coating 17, 18 for example formed in gold cover 4 or the main part 2. As explained above, the material whose melting point is less than 250 ° C may be indium or tin. A representation in which the layer 12 is deposited on the cover 4 is visible in FIG. 3.

The thickness of the layer 12 is important because, at first, it is used to form a first intermetallic with one of the protective layers 17, 18 and, in a second step, it is used to form a second intermetallic with at least one of the metallization layers 11, 9 of the main part 2 or the cover 4 as explained below.

Thus, the phase 24 or 26 ends with a step intended to partially diffuse the material whose melting point is less than 250 ° C. in the coating 17, 18 in order to completely transform the coating 17, 18 into a coating. intermetallic capable of forming a protective layer 19 of said at least one layer 15 of metal. A representation in which the layer 19 is formed on the cover 4 is visible in FIG. 4.

It is therefore understood that a portion of the layer 12 is used and that at the end of the phase 24 or 26, the layer 12 becomes the layer 12 less thick but still of the same nature. Advantageously according to the invention, the diffusion step can be carried out at ambient temperature, but it is possible to accelerate it by heating the assembly.

The thickness of said at least one layer 15, 16 of metal used for the final diffusion is also important because it is used to "consume" the entire layer 12 by forming a second intermetallic for sealing the housing 7 The nature of the other at least one layer 16, 15 of metal present during the first diffusion is less important in that it will little or no interaction.

At the end of step 24 or 26, it is understood that said at least one layer 15, 16 comprises a coating 19 of protection against oxidation for example gold-indium or gold-tin alloy and the layer 12 Which is the non-diffused remainder of the indium or tin layer 12 as illustrated in FIG. 4. The layer 12 may have a thickness of between 15 and 60 microns.

After diffusion, the layers 13, 14 and 15, 16 remain unchanged. On the other hand, a protection layer 19 of the order of 5 μm and a layer 12 of between 13.5 and 58.5 μm are obtained. These deposits can be made, for example, by screen printing, electroplating or physical vapor deposition.

In a second step 25, the MEMS 5 is mounted in the cavity 10 of the hollow portion 2, and then, during the third step 27, the housing 7 is assembled by placing the metal layers opposite each other in order to put them in contact. Finally, the method 21 includes a final step 29 of welding the metal layers to form the sealing means 6 and thus permanently seal the encapsulation device 3. As explained above, according to the MEMS 5 to be encapsulated, the step 29 and, optionally, step 27 is (are) carried out under vacuum or in a controlled atmosphere.

Step 29 is intended to completely diffuse the remainder 12 of the material whose melting point is less than 250 ° C in said at least one layer 15, 16 facing it in order to fully transform the material which the melting point is less than 250 ° C in a second intermetallic 20 able to seal said component in the encapsulation device 3 even for temperatures between 400 and 800 ° C. Step 29 may consist in pressing the lid 4 against the hollow portion 2 while liquefying by heating the layer 12.

It is therefore understood that the layer 12 is completely "consumed" by the layers 16 and / or 15 forming a layer 20 of a second intermetallic for example based on indium-nickel or nickel-tin. However, there remain layers 16 and / or 15 which are the non-diffused remainder of the layer 16 and / or 15 as illustrated in FIG. 6.

Therefore, after diffusion, it remains the layers 15 and 16 of metal such as nickel and optionally layers 13 and 14 which remain unchanged. In the case where a protective layer 18 is used, it would migrate by thickening the layer 19 which would become 19 as illustrated in FIG. 6.

Another example of sealing means 6 obtained according to the invention is shown in FIGS. In this variant, the material whose melting point is less than 250 ° C is indium, the protective layers of gold and said layers of nickel-cobalt metals. As shown in figs. 8 and 9, there is obtained from top to bottom, a fastening layer 33 (W), a first metal layer (NiCo), a first intermetallic layer 40 (InNiAu), an intermetallic layer 39 (Auln2), a second layer 40 of intermetallic (InNiAu), a layer 36 (NiCo) and a layer 33 of attachment (W). Advantageously according to the invention, the cover 4 can be indifferently above the layer 33 or below the layer 34.

It is also understood from the example of FIG. 9 with respect to that of FIG. Both of the at least one layer of metal may interact with one another to form two intermetallics 40 surrounding the intermetallic 39 formed in phase 24 or 26 without departing from the scope of the invention.

Advantageously according to the invention, compared to current sealing means, it appeared that the intermetallic formed from nickel in addition to their lower cost have slower growth kinetics which advantageously allows better control of their properties. training.

As an optional feature, if the MEMS 5 is a quartz tuning fork resonator, it may be necessary to adjust or adjust it. This adjustment can be performed after step 25 or after step 29. In the latter case, that is to say when the lid 4 has already sealed the hollow portion 2 of the casing 7 under vacuum, the lid 4 should comprise at least one transparent portion at a given wavelength of a light beam, such as a laser beam, used to make said adjustment.

With the aid of the present method 21, the electronic component 1 formed is thus configured as an SMD type component (abbreviation of the English term "Surface Mounting Device"). As such, it can be mounted and connected by brazing for example on a printed circuit board.

Of course, the present invention is not limited to the example shown but is susceptible to various variations and modifications that will occur to those skilled in the art. In particular, the electronic component 1 may comprise only the resonator element 5 or, alternatively, the method 21 could be adapted to perform a process of the "wafer level packaging" type, that is to say a series encapsulation from two plates against each other which are subsequently cut to form the electronic component 1.

In addition, the lid and / or the main part may be metal and not ceramic. By way of example, FIGS. 10 to 13 show two variants with a lid 44, 64 of metal. Typically, the metallizations 49, 69 completely encase the lid and / or the main part when they are made of metal. However, it is understood that the coating can also be partial without any negative effect on the sealing means 6.

In a first variant visible in FIGS. 10 and 11, the lid 44 made of metal, for example based on kovar, comprises a metallization 49 with several layers. The metallization 49 comprises at least one layer of metal 55 such as nickel or copper. The metallization 49 may also include a coating 57 for protection against oxidation, for example gold. The metal layer 55 has a thickness of substantially 5 microns while the protective coating 57 is about 0.1 microns.

Advantageously according to the invention, a layer 52 of a material whose melting point is less than 250 ° C is deposited on the coating 57, for example formed of gold. As explained above, the material whose melting point is less than 250 ° C may be indium or tin. A representation in which the layer 52 is deposited on the cover 44 is visible in FIG. 10.

The thickness of the layer 52 is important because, at first, it is used to form a first intermetallic with one of the protective layers and, in a second step, it is used to form a second intermetallic with the least one of the layers of the metallization of the main part or the lid as explained below.

Thus, after the diffusion step intended to partially diffuse the material whose melting point is less than 250 ° C in the coating 57 in order to completely transform the coating 57 into an intermetallic capable of forming a layer 59 of protecting said at least one layer 55 of metal. A representation in which the layer 59 is formed on the cover 44 is visible in FIG. 11.

It is therefore understood that a portion of the layer 52 is used and that at the end of the phase 24 or 26, the layer 52 becomes the layer 52 less thick but still of the same nature. At the end of step 24 or 26, it is understood that the said at least one layer 55 comprises a coating 59 for protection against oxidation, for example made of gold-indium or gold-tin alloy, and the layer 52 which is the remainder. non-diffused layer 52 indium or tin as shown in FIG. 11. The layer 52 may comprise a thickness of between 15 and 60 μm and extend over all or part of the cover 44 and / or all or part of the metallization 49.

After diffusion, the layer 55 remains unchanged. On the other hand, a protection layer 59 of the order of 5 μm and a layer 52 of between 13.5 and 58.5 μm are obtained. These deposits can be made, for example, by screen printing, electroplating or physical vapor deposition.

In a second variant visible in FIGS. 12 and 13, the cover 64 made of metal, for example based on nickel or copper, comprises a metallization 69 with a single layer. It is therefore clear that the cover 64 forms part of the metallization compared to the previous explanations. The metallization 69 thus comprises at least one layer of metal 75 such as gold. The metallization 69 therefore always forms a protective coating against the oxidation of the cover 64. The metal layer 75 has a thickness of approximately 0.1 μm.

Advantageously according to the invention, a layer 72 of a material whose melting point is less than 250 ° C is deposited on the layer 75 for example formed of gold. As explained above, the material whose melting point is less than 250 ° C may be indium or tin. A representation in which the layer 72 is deposited on the cover 64 is visible in FIG. 12.

The thickness of the layer 72 is important because, at first, it is used to form a first intermetallic with the lid 64 and, in a second step, it is used to form a second intermetallic with at least one layers of the metallization of the main part as explained below.

Thus, after the diffusion step intended to partially diffuse the material whose melting point is less than 250 ° C in the layer 75 in order to completely transform the coating 75 into an intermetallic capable of forming a layer 79 of protecting said at least one layer 55 of metal. A representation in which the layer 79 is formed on the cover 64 is visible in FIG. 13.

It is therefore understood that a portion of the layer 72 is used and that at the end of the phase 24 or 26, the layer 72 becomes the layer 72 less thick but still of the same nature. At the end of step 24 or 26, it is understood that the cover 64 comprises a layer 79 for protection against oxidation, for example made of gold-indium or gold-tin alloy, and the layer 72 which is the non-diffused remainder of the layer 72 of indium or tin as illustrated in FIG. 13. The layer 72 may comprise a thickness of between 15 and 60 μm and extend over all or part of the cover 64 and / or all or part of the metallization 69.

After diffusion, the body of the lid 64 remains unchanged. On the other hand, a protection layer 79 of the order of 5 μm and a layer 72 of between 13.5 and 58.5 μm are obtained. These deposits can be made, for example, by screen printing, electroplating or physical vapor deposition.

It may also be envisaged to mount the oscillator circuit in the same cavity 10 as the quartz resonator 5. This oscillator circuit may also include a real-time clock function (RTC) or other functions.

It may be envisaged also to mount one or more MEMS 5 in each housing 7 or alternatively to use alternative materials for the housings 7 such as metal or glass, without departing from the scope of the invention. Similarly, the shape of the metallizations 9, 11 can not be limited to that of FIGS. 1 and 2.

It is also possible that the phases 22, 24 and 26 are not completely independent depending on the technology of the MEMS used. It is thus conceivable that the phase 26 of forming the hollow portion 2 is made before the phase 22 of forming the MEMS 5 in the case where the latter 5 is etched directly in this first 2.

Finally, a material of the "getter" type may be disposed in the encapsulation device 3 to serve as a vacuum pump, that is to say perfect the vacuum in the device 3 already manufactured, when it is activated for example by means of a laser or during the thermal sealing / diffusion process, simply by means of temperature and time.

Claims (37)

1. Element (2, 4, 44, 64) arranged to cooperate with another piece (4, 2) to form an encapsulation device (3) of a component (5) comprising the element (2, 4 , 44, 64) at least partially coated with a metallization (11, 9, 49, 69) characterized in that said metallization comprises at least one layer (15, 16, 55, 64) of metal protected by an intermetallic (19, , 59, 79) which is covered by a non-diffused portion (12, 52, 72) of a material having a melting point of less than 250 ° C. 2. Element (2, 4, 44, 64) according to the preceding claim, characterized in that the element is a cover (4, 44, 64) for closing said encapsulation device (3). 3. Element (2, 4, 44, 64) according to claim 1, characterized in that the element is a main part (2) intended to form a cavity (10) of the encapsulation device (3). 4. Element (2, 4, 44, 64) according to one of the preceding claims, characterized in that the element (2, 4, 44, 64) is formed of ceramic or metal. 5. Element (2, 4, 44, 64) according to one of the preceding claims, characterized in that said at least one layer (15, 16, 55, 75) of metal comprises nickel and / or copper and / or gold. 6. Element (2, 4, 44, 64) according to one of claims 1 to 4, characterized in that said at least one metal layer is formed by the body of the element (64). 7. Element (2, 4, 44, 64) according to one of the preceding claims, characterized in that said at least one metal layer (15, 16) further comprises a layer (13, 14) for hooking against said body of the element (2, 4). 8. Element (2, 4, 44, 64) according to the preceding claim, characterized in that the layer (13, 14) of attachment comprises molybdenum and / or tungsten and / or titanium and / or chromium. 9. Element (2, 4, 44, 64) according to one of the preceding claims, characterized in that the intermetallic (19, 59, 79) comprises gold. 10. Element (2, 4, 44, 64) according to one of the preceding claims, characterized in that said material whose melting point is less than 250 ° C is indium. 11. Element (2, 4, 44, 64) according to one of claims 1 to 9, characterized in that said material whose melting point is less than 250 ° C is tin. 12. A method (24, 26) for manufacturing an element (2, 4, 44, 64) arranged to cooperate with another piece (4, 2) to form an encapsulation device (3) of a component (5) comprising the following steps: a) forming the element (2, 4, 44, 64); b) depositing a metallization (9, 11, 49, 69) comprising at least one layer (15, 16, 55) of metal protected by a coating (17, 18, 57, 75); characterized in that it further comprises the following steps: c) depositing a layer (12, 52, 72) of a material having a melting point of less than 250 ° C on the coating (17, 18, 57, 75); d) partially diffusing the material having a melting point of less than 250 ° C into the coating (17, 18, 57, 75) to fully convert the coating (17, 18, 57, 75) to an intermetallic and leave a non-diffused portion (12, 52, 72) of the material having a melting point of less than 250 ° C. 13. Method (24, 26) according to the preceding claim, characterized in that the element (2, 4, 44, 64) is formed of ceramic or metal. 14. Process (24, 26) according to claim 12 or 13, characterized in that said at least one layer (15, 16, 55) of metal comprises nickel and / or copper and / or gold. 15. Process (24, 26) according to claim 12 or 13, characterized in that said at least one metal layer is formed by the body of the element (64). 16. Process (24, 26) according to one of claims 12 to 15, characterized in that the process comprises, between step a) and step b), a step of depositing a layer (13, 14). , 33, 34) for said at least one layer (15, 16) of metal. 17. Process (24, 26) according to the preceding claim, characterized in that the layer (13, 14) of attachment comprises molybdenum and / or tungsten and / or titanium and / or chromium. 18. Process (24, 26) according to one of claims 12 to 16, characterized in that the coating (17, 18, 57, 75) comprises gold. Encapsulating device (3) arranged to receive a component (5) comprising a housing (7) comprising a main part (2) forming a cavity (10) which is hermetically closed by a cover (4, 44, 64) by means of sealing means (6) characterized in that the sealing means (6) comprise an intermetallic (20, 40) formed by at least one metal (15, 16, 15, 16, 55 , 64) with a material (12, 52, 72) whose melting point is less than 250 ° C to allow its interdiffusion in the liquid state with said at least one metal. 20. Encapsulation device (3) according to the preceding claim, characterized in that the sealing means (6) comprise a second intermetallic (19, 19, 39, 39, 59, 79) adjacent to said first intermetallic ( 20, 40) formed by at least one second metal (17, 18, 57, 75) with the material (12, 52, 72) having a melting point of less than 250 ° C. 21. Encapsulation device (3) according to the preceding claim, characterized in that said at least one second metal (17, 18, 57, 75) comprises gold. 22. encapsulation device (3) according to claim 20 or 21, characterized in that the sealing means (6) comprise a third intermetallic (40) of substantially identical nature to the first intermetallic, the first and third intermetallic being located on each side of the second intermetallic (39). 23. Encapsulation device (3) according to one of claims 19 to 22, characterized in that the sealing means (6) comprise at least one attachment layer (13, 14, 33, 34) against the housing (7). 24. Encapsulation device (3) according to one of claims 19 to 23, characterized in that the sealing means (6) comprise a layer of said at least one metal (15, 16, 15, 16, 55, 64) between the cover (4, 44, 64) and said intermetallic (20, 40) and between the main part (2) and said intermetallic (20, 40). 25. Encapsulation device (3) according to one of claims 19 to 23, characterized in that the sealing means (6) comprise a layer of said at least one metal (15, 16, 15, 16, 44) between the main portion (2) and said intermetallic (20, 40) and in the cover (64). 26. Encapsulation device (3) according to one of claims 19 to 25, characterized in that said material whose melting point is less than 250 ° C is indium. 27. Encapsulation device (3) according to one of claims 19 to 25, characterized in that said material whose melting point is less than 250 ° C is tin. 28. Encapsulation device (3) according to one of claims 19 to 27, characterized in that said at least one metal (15, 16, 15, 16, 55, 64) comprises nickel and / or copper and / or gold. 29. encapsulation device (3) according to one of claims 19 to characterized in that the housing (7) is formed of ceramic and / or metal. 30. Encapsulation device (3) according to one of claims 19 to characterized in that the cavity (10) is under vacuum or controlled atmosphere. 31. A method (21) for manufacturing an encapsulation device (3) for a component (5), characterized in that it comprises the following steps: <tb> e) <sep> forming said component (5); <tb> f) <sep> fabricating a main portion (2) having a first metallization (11) and forming a cavity (10), and a cover (4, 44, 64) having a second metallization (9, 49, 69 ), the main part (2) or the cover (4, 44, 64) being produced according to the method (24, 26) according to one of claims 12 to 17; <tb> g) <sep> mounting (25) the component (5) in the cavity (10); <tb> h) <sep> assembling (27) the non-diffused portion (12, 52, 72) of the material having a melting point of less than 250 ° C in step d) of the main portion (2) or the cover (4, 44, 64) respectively against the metallization (9, 11) of the cover (4, 44, 64) or the main part (2); <tb> i) <sep> diffuse (29) completely the non-diffused portion (12, 52, 72) of the material having a melting point of less than 250 ° C in said metallization (11, 9, 49, 69) to fully convert the material having a melting point of less than 250 ° C into a second intermetallic (20) capable of sealing said component in the encapsulant (3). 32. Method (21) according to the preceding claim, characterized in that it comprises, between step f) and step g), the step of depositing a layer (18, 17, 57, 75) of protection to protect said formed metallization not covered by the non-diffused portion (12, 52, 72). 33. Method (21) according to claim 31 or 32, characterized in that the main part (2) and the cover (4, 44, 64) are formed of ceramic and / or metal. 34. Process (21) according to one of claims 31 to 33, characterized in that step i) is carried out under vacuum or in a controlled atmosphere. 35. Process (21, 24, 26) according to one of claims 12 to 17 and 31 to 34, characterized in that said component (5) is a quartz tuning fork resonator. 36. Process (21, 24, 26) according to one of claims 12 to 17 and 31 to 35, characterized in that the material whose melting point is less than 250 ° C is indium. 37. Process (21, 24, 26) according to one of claims 12 to 17 and 31 to 35, characterized in that the material whose melting point is less than 250 ° C is tin.