The present disclosure relates to the field of power electronics. It relates in particular to a method for bonding electronic components.
In the document (Silver-Indium joints produced at low temperature for high temperature devices by Chuang et al., IEEE Transactions on components and packaging technologies vol. 25, 2002, p. 453-458) a method is described for bonding a silicon die to a silicon substrate. On the silicon die and silicon substrate multilayer films are introduced by evaporation in a thermal evaporation chamber at a vacuum of about 0.1 mPa. On the substrate first a 0.03 μm chromium layer is introduced to improve the joint adhesion, then a 0.05 μm gold layer, followed by a 5.0 μm silver layer and on top of it a 0.06 μm gold layer are evaporated. The silver layer on the silicon die is used as a protection layer for the indium layer below. On the silicon die a 0.025 μm chromium layer is introduced, followed by a 1.9 μm indium layer and then a 0.21 μm silver layer. The die and substrate are aligned against each other with the metal layers facing each other. Afterwards a static pressure of 0.5 MPa is applied to the arrangement of the die and the substrate with the multi structure layers in between in order to ensure an intimate contact between the die and the substrate. This arrangement is introduced into a tube furnace. First the furnace is filled with nitrogen, followed by hydrogen to purge the arrangement from oxygen. Then, the furnace is heated to a temperature of 206° C. for 7 min in a hydrogen atmosphere to inhibit indium oxidation at the enhanced temperature, because the silver layer alone is not sufficient for a protection against indium oxidation under these ambient conditions. Afterwards the temperature is reduced to an annealing temperature below 145° C. for 26 h. The silver-indium joint converts to a silver rich silver-indium alloy, resulting in a melting temperature of the joint of 765 to 780° C. Such joints are nearly void-free. However, the method is complex in that it involves the need of inert gas atmosphere and the necessity to use a furnace which is intended for operation with inert gas inside the furnace. Furthermore, the high pressure required to get an intimate contact is usually achieved by a clamped load, which needs very precise machine tolerances, because otherwise voids and incomplete bonding will be the result. High-precision fixtures are used to align the multi structure layers between the die and the substrate against each other. If the silicon die or the substrate do not have a planar surface it is difficult to apply the required pressure to the arrangement without getting cracks in the components.
EP 0416 847 also describes a method for joining a silicon die to a component of molybden or tungsten by soldering, using a silver layer and an indium layer as a soldr material. The bonding process is performed at 175° C. for about 2 hours at a pressure of 0.3 MPa in a vacuum furnace.
In the document (A fluxless process of producing tin-rich gold-tin joints in air by Chuang et al., IEEE Transactions on components and packaging technologies vol. 27, 2004, p. 177-181) a method is described for bonding a silicon wafer to a silicon substrate with a tin-gold joint. The silicon wafer has a chromium metallization followed by a gold metallization, whereas the silicon substrate has first a chromium metallization, followed by a tin and above a tin-gold metallization. The substrate and wafer with the metal layers in between are compressed with a pressure of about 0.6 MPa. This arrangement is inserted into a furnace maintained at 1000° C. The temperature at the metal layers is measured. When reaching a bonding temperature of 220° C. at the metal layers, which needs about 30 s, the arrangement is cooled down. As the heat has to penetrate through the substrate and wafer, in order to get to the metal layers, the substrate and wafer are heated to very high temperatures in this method. The high temperature, at which the furnace is maintained, is necessary to achieve a very high ramp rate and thus a short bonding time. This method is not very practible, because the sensitive electronic components are heated to a much higher temperatures than the bonding temperature. Even small variances of the measuring point, a time delay between the temperature measurement and the begin of the cooling step or variations of the thicknesses of the electronic components and/or metal layers have a great influence on the local bonding temperature, so that the probability of having an inhomogeneous heat distribution, which can lead to inhomogeneous melting and bonds with voids is very high.
U.S. Pat. No. 4,810,672 shows a thyristor, on which a silver layer is applied, and a substrate, on which layers of aluminum and titanium, followed by a silver layer. The components are aligned against each other and then the arrangement is inserted into a compression press. The compression is performed at a pressure of 15 MPa at minimum at a temperature of 230° C. and for less than 1 min. The pressure sintering is performed at ambient air atmosphere. The method uses a silver paste, which is applied on the electronic components prior to pressure sintering.
Exemplary embodiments disclosed herein can provide a reliable and robust method for bonding electronic components, which is easy to perform and to avoid the necessity to perform the bonding process in inert gas atmosphere.
A method for bonding electronic components is disclosed, in which a first electronic component, in particular a semiconductor die, and a second electronic component, in particular a substrate, are fixed to each other in a bonding process, each of the electronic components having a main surface, and the method comprising the following steps: at least one metal layer comprising an indium layer is applied on each of the main surfaces of said electronic components, the first and second electronic components are aligned against each other with their main surfaces facing each other, the first and the second electronic components together with the at least one metal layer in between forming an arrangement, and the arrangement is introduced into a compression means, wherein the arrangement is compressed at a pressure in a range of 10 to 35 MPa, in that the compression process is performable in oxygeneous gas atmosphere inside the compression means, and in that heat in a range of 230 to 275° C. is applied to the arrangement.
The subject matter of the disclosure will be explained in more detail in the following text with reference to the attached drawings, in which:
Generally, alike or alike-functioning parts are given the same reference symbols. The described realizations are meant as examples and shall not confine the disclosure.
In the method for bonding electronic components according to the disclosure a first electronic component, e.g., a semiconductor die, and a second electronic component, e.g., a substrate, are attached to each other in a bonding process. Each of the electronic components have a main surface. The method comprises following steps:
The method is characterized in that the arrangement is compressed at a pressure in a range of 10 to 35 MPa, and heat in a range of 230 to 275° C. is applied to the arrangement. The compression process is performable in oxygeneous gas atmosphere inside the compression means. During the bonding process, i.e. during compression and heating of the arrangement oxygeneous gas atmosphere can available inside the compression means, i.e. no special precautions have to be taken to avoid that the arrangement may get into contact with oxygen during the bonding process.
At such a high temperature and such a high pressure the bonding process, comprising the steps of heating and compressing, can be performed without the necessity to perform the process in inert gas atmosphere. Due to the high temperature and high pressure, the time for the heating and compression process is shortened and the metal layers form a stable joint before an oxidation of the indium layer can occur. The bonding method can be performed in air atmosphere, i.e. more generally in an oxygeneous gas atmosphere, so that no sophisticated bonding apparatuses, which have to be operated with inert gas atmosphere inside, are needed, but a standard bonding apparatus with oxygeneous gas atmosphere inside, especially air atmosphere, can be used. Thus a robust method is provided, which results in firm and nearly void-free solder joints. Different kind of materials can be bonded, as long as they can be metallized and if they can withstand the necessary temperature and pressure during the bonding process. No parts of the arrangement are heated beyond the temperature, which is applied to the arrangement and which temperature corresponds to the bonding temperature.
In an exemplary embodiment at least one of the electronic components is protected by an elastically deformable protection layer on the side opposite to the main surface of at least one electronic component prior to being compressed. Advantageously, the protection layer comprises rubber, which is a soft material and has good elastical and compression properties. Such a protection layer is inexpensive and does not have to be preformed according to the outer form of the arrangement. As the elastical deformable protection layer adapts itself to the outer form of the arrangement, the danger of cracks is reduced and even variations in the outer form of the arrangement can be compensated.
The metal layers 3, 3′ are applied to the electronic components 1, 2 by placing the first electronic component 1 in a thermal evaporation chamber and then evaporating at least one metal layer 3 on the main surface of the first electronic component 1. The second electronic component 2 is then placed in the thermal evaporation chamber and at least one metal layer 3′ is evaporated on the main surface of the second electronic component 2. Alternatively, the metal layers 3, 3′ can be sputtered on the main surfaces of the electronic components 1, 2.
It is also possible to exchange the at least one metal layer 3 arranged on the main surface of the first electronic component 1 with the at least one metal layer 3′ arranged on the main surface of the second electronic component 2. It is also possible to use other metal layers 3, 3′ in order to form the joint.
In the exemplary embodiment of the method shown in
Afterwards the arrangement is compressed by a static pressure in the range of 10 to 35 MPa. In an exemplary realization a pressure in the range of 30 to 35 MPa is applied. Such a high pressure ensures a good contact over the whole area between the metal layers 3, 3′ of the first and second electronic components 1, 2. Afterwards the arrangement is heated up by heating the hot plate 53. The heat penetrates through the platen 52 and is transmitted to the metal layers 3, 3′ on the main surfaces of the first and second electronic components 1, 2 which are bonded by the heating. This heating process is performed at a temperature between 230 to 275° C., in an exemplary realization heat in a range between 230 to 250° C. is applied to the arrangement. If the temperature is too low, the bonding process would take longer and thereby the probability of oxidation of the indium layer would increase. Also at low temperatures inhomogeneous heat distribution can lead to inhomogeneous melting and bonds with voids. If the temperature was too high, it could result in an irregular and poor bonding joint because of squeezing out of molten metal layers and resulting in an oxidation of the indium layer.
The heat is applied to the arrangement for a period of 3 to 5 min, the heating time period depending on the applied temperature and the size and thickness of the electronic components 1, 2 and metal layers 3, 3′. Afterwards the arrangement is cooled down to ambient temperature. The heating over such a short period, in connection with the high pressure and high temperature leads to a nearly void-free silver-indium joint without the danger of oxidation of the indium layer, even if the bonding process, i.e. the compression process and heating process, is performed in oxygeneous gas atmosphere, in particular in air atmosphere.
In an exemplary realization, not shown in a figure, the arrangement is introduced into a preform with the relative positions of the components of the arrangement predetermined by one or more alignment means prior to the compression and heating process. Such a preform helps to avoid unintentional displacements of the components, especially lateral displacements. The preform may either be made of a stiff or an elastically deformable material. If the preform is made of a stiff material, the preform can be constructed very accurately, so that the relative positions of the components 1, 2 are very well defined, when they are introduced into the preform. If the preform is made of a elastically deformable material, expansions due to the raised temperature, deviations or inaccuracies of the form of the components can be compensated. The preform may also comprise a bottom and/or top layer, e.g., of an elastically deformable material like rubber, so that the different parts of the arrangement are protected against lateral displacement and against cracks in the components, which may be caused by the pressure applied during the bonding process.
Instead of using at least one plain protection layer 6, 6′ the at least one protection layer 6, 6′ may also be preformed with a recess, in which the arrangement can be positioned to apply a more uniform pressure to all parts of the arrangement during the bonding process and also to avoid lateral displacements of the parts of the arrangement, i.e. to avoid displacements between any of the electronic components 1, 2 and/or any of the metal layers 3, 3′. If two protection layers 6, 6′ are used, these layers can also be one common protection layer, which is laid around the arrangement in a u-shaped form, or a common protection bag, which is open to one side, at which side the arrangement can be introduced.
If two separate protection layers 6, 6′ are used, which embed the arrangement from two opposite sides, the thickness and elasticity of the protection layers 6, 6′ can be chosen in such a way that in a compressed stage the protection layers 6, 6′ touch each other (as shown in
It will be appreciated by those skilled in the art that the present disclosure can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The presently disclosed embodiments are therefore considered in all respects to be illustrative and not restricted. The scope of the disclosure is indicated by the appended claims rather than the foregoing description and all changes that come within the meaning and range and equivalence thereof are intended to be embraced therein.
Number | Date | Country | Kind |
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05405617.1 | Nov 2005 | EP | regional |
This application claims priority under 35 U.S.C. §119 to EP Application 05405617.1 filed in Europe on Nov. 2, 2005, and as a continuation application under 35 U.S.C. §120 to PCT/CH2006/000610 filed as an International Application on Oct. 31, 2006 designating the U.S., the entire contents of which are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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Parent | PCT/CH2006/000610 | Oct 2006 | US |
Child | 12149410 | US |