DE102008038946A1 - A method of fabricating a semiconductor-based circuit and semiconductor circuit-based circuit having a three-dimensional circuit topology - Google Patents

Abstract

The present invention relates to a method for producing a semiconductor circuit with a three-dimensional circuit topology, in which at least one hole (11) is produced in a first semiconductor substrate (1), while at least one metallic projection (4) is formed on a surface of a second semiconductor substrate (2). in which an adhesive layer (6) is applied to a wall (5) of the at least one hole (11) in the first semiconductor substrate (1), after which the semiconductor substrates (1, 2) are joined together in such a way that the at least one metallic projection ( 4) to form a via at the adhesive layer (6) abutting in the at least one hole (11) in the first semiconductor substrate (1) comes to rest. The invention further relates to a corresponding semiconductor-based circuit having a three-dimensional circuit topology.

Description

The The invention relates to a method for producing a semiconductor-based Circuit with three-dimensional circuit topology and a corresponding Circuit with three-dimensional circuit topology. The invention in particular relates to a method for three-dimensional integration of semiconductor components based on silicon vias, with the very compact electronic circuit with relatively complex Make the circuit topology.

The Realization of silicon vias is typically done so far through two different process flows in so-called pre-CMOS or post-CMOS manufacturing processes for semiconductor components (Silicon semiconductor technology). In this case, by means of suitable etching (Dry etching, wet-chemical etching, Laser etching) holes (Vias) in silicon formed substrates of fully or partially processed Silicon wafers introduced, which then isolated inside and metallized become. The design of the vias can take different forms accept (tapered, straight wall). In most cases will be so-called blind holes used that does not completely pass through the substrate. The metallization of the vias is usually done with methods such as CVD processes, sputtering or electrochemical deposition (electroplating). These processes are technical limitations in terms of geometric relationships the vias to be isolated and metallized subjected (concerning diameter, depth, aspect ratio). In addition will in particular the production of holes with very high aspect ratios complicates that z. T. physical process limits, z. In sputtering, RIE (reactive ion etching) and CVD can be or very long process times are required.

Of the The present invention is therefore based on the object, a method for producing a semiconductor-based circuit with three-dimensional Circuit topology to propose, in which with relatively low Overloading realized in a semiconductor substrate of the circuit be, with these vias with respect to their geometric properties should be designed largely arbitrary. The invention is Further, the object of a correspondingly easy to produce and freely configurable semiconductor-based circuitry within wide limits to propose with a three-dimensional circuit topology.

These The object is achieved by a method having the features of the main claim and by a Semiconductor-based circuit with the features of the independent claim. advantageous Embodiments and further developments of the invention will become apparent with the features of the subclaims.

The proposed method thus provides for the production of at least one Holes in a first semiconductor substrate and the production at least a corresponding metallic projection on a surface of a second semiconductor substrate, wherein on a wall of at least a hole is applied in the first semiconductor substrate an adhesive layer and the first semiconductor substrate and the second semiconductor substrate subsequently put together like that Be that at least one metallic survey for education a via on the adhesive layer adjacent in the at least a hole in the first semiconductor substrate comes to rest. advantageously, Needless This is a particular case of relatively narrow and / or relatively long Vias very elaborate and tedious deposition of metal within the Holes. Instead, the metal forming the respective through-hole becomes as a survey on a surface deposited another semiconductor substrate, which is much easier and faster possible is. In particular, thin and long vias can be so much less Realize effort.

A in this way advantageously easy to produce semiconductor-based Circuit with three-dimensional circuit topology includes accordingly a first semiconductor substrate and a parallel thereto oriented second semiconductor substrate, wherein the first semiconductor substrate at least has a via formed by a metallic one Elevation on a surface of the first semiconductor substrate facing the second semiconductor substrate and the one hole in the first semiconductor substrate fills wherein a lateral surface the metallic survey by an adhesive layer with a Wall of the hole is connected.

typically, At least one of the two semiconductor substrates is replaced by a Semiconductor wafer to be formed, which is a pronounced low-complexity Making a big one Number of corresponding semiconductor-based circuits allowed. there Silicon is preferably used as material for the semiconductor substrates, that for the formation of semiconductor based circuits is particularly suitable.

A circuit with advantageously high integration density can be realized if in at least one of the semiconductor substrates, an electronic circuit is integrated, which is directly or indirectly contacted by the at least one metallic survey or by the through hole formed thereby. It can be in the manner described realize very short conductor paths given given circuit complexity, which is advantageous in terms of the lowest possible external fields and minimized power losses and signal propagation times.

Yet more complex, extremely compact circuits can be realized in the manner described a stack of more than two with each other connected semiconductor substrates is formed.

A advantageous embodiment of the proposed method sees in that the at least one hole in the first semiconductor substrate first as Blind hole executed is, wherein the first semiconductor substrate after joining the both semiconductor substrates on a second semiconductor substrate far away until one end of the metallic Survey on this page is free. The first semiconductor substrate is thinned so far that the at least one metallic survey ultimately a completely overlaps the remaining layer thickness of the first semiconductor substrate, to form a via in the first semiconductor substrate.

The at least one hole in which the via can be realized should, in an advantageous simple manner, for example, by etching or be prepared by laser structuring.

The at least one metallic projection on the second semiconductor substrate let yourself realize in an advantageous simple manner by galvanic metal and / or de-energized deposited on the second semiconductor substrate is typically on a contact pad of the second semiconductor substrate. To form the metallic survey, for example, copper or another as possible good conductive metal can be used. To ensure, that the survey the desired Form receives, which matches the corresponding hole in the first semiconductor substrate, The metal may be used to form the elevation in a recess of a correspondingly structured masking layer are deposited. A such masking layer may be formed of photoresist, for example become.

A good and resilient Connection of the semiconductor substrates or the via forming metal with the wall of the corresponding hole in the first Semiconductor substrate can be achieved by forming the adhesive layer from a polymeric adhesive will, after the joining the two semiconductor substrates cured. At the time of curing choose freely can, the process can be designed so that the resulting Circuit after assembly the two semiconductor substrates is heated or cooled, to a setting or curing to induce the adhesive layer.

The Adhesive layer, which is also at least over parts of the second Semiconductor substrate facing side of the first semiconductor substrate can extend may additionally for connecting the metallic elevations to the walls of the corresponding holes for the electrical insulation of the vias against the serve the first semiconductor substrate. In addition, however, too even before the application of the adhesive layer, an insulating layer and / or barrier layer at least partially on the first Semiconductor substrate are applied, in particular on the walls of the Holes. Such an insulation layer may also be passivated a surface of the first semiconductor substrate are formed.

A Continuing the proposed procedure, which is both a more stable Connection of the semiconductor substrates as well as a more complex circuit topology allowed, provides that at least one more conductive connection between the second semiconductor substrate and a semiconductor substrate this facing surface of the first semiconductor substrate is formed. These can z. B. opposite each other Contact pads of the first semiconductor substrate and the second semiconductor substrate by solder or conductive Adhesive are joined together.

Finally will typically facing away from the second semiconductor substrate surface of the first semiconductor substrate, a conductor track plane for contacting applied by the at least one survey formed via are used to form interconnects and / or pads can be structured to realize the desired circuit.

An embodiment of the invention will be described below with reference to the 1 and 2a to 2g described. Show it

1 a section of a cross section through a semiconductor-based circuit in an embodiment of the invention and

2a - 2g in a corresponding representation, different method steps of a method for producing the circuit 1 ,

In the 1 shown semiconductor-based circuit has a first semiconductor substrate 1 formed by part of a silicon wafer. Over this first semiconductor substrate 1 is a second semiconductor substrate 2 arranged, which is formed from a semiconductor active wafer, typically also made of silicon. At least in the second Semiconductor substrate 2 an electronic circuit is integrated, for which the second semiconductor substrate 2 contact pads 3 and 3 ' the latter also being referred to as Under Bump Metallizations.

The contact pads 3 ' are with there grown up columnar elevations 4 made of copper, the through holes in the first semiconductor substrate 1 fill and so vias in the first semiconductor substrate 1 form. There are walls 5 said through holes, as well as large parts of the second semiconductor substrate 2 facing surface of the first semiconductor substrate 1 , with an adhesive layer 6 covered by which lateral surfaces of the metallic elevations 4 with the walls 5 the through holes are connected. Between the adhesive layer 6 and the first semiconductor substrate 1 forming silicon is also a thin barrier layer 7 to recognize that acts as an electrically insulating barrier. At a second semiconductor substrate 2 opposite side are the metallic elevations 4 with connection pads 8th connected, which are realized in a conductor track plane and on which solder bumps 9 are arranged to facilitate contacting the semiconductor-based circuit. Furthermore, parts of the connection pads 8th and in the same interconnect level realized interconnects in an insulator layer 10 embedded.

In addition, there are electrical connections between the semiconductor substrates 1 and 2 provided by small amounts of solder or conductive adhesive between each opposing contact pads 3 are realized.

In same way for more complex designs corresponding semiconductor-based circuits also more than two parallel to each other arranged semiconductor substrates to be interconnected and so a higher one Make pile.

The 2a to 2g illustrate a method of fabricating the semiconductor-based circuit 1 , In this case, recurring features are provided with the same reference numerals.

2a shows the first semiconductor substrate 1 formed by a silicon wafer after a first processing step in which holes 11 in the semiconductor substrate 1 are produced, which are initially designed as blind holes and later form the already mentioned through holes. Also in 2a recognizable are already applied at this stage contact pads 3 , The holes 11 be through a conventional silicon patterning process, such. As reactive ion etching, laser structuring or wet chemical etching produced. In this case, a masking process suitable for the respective structuring process is used.

In a further process step, the result in 2 B is shown, an insulating layer and / or barrier layer 7 on the first semiconductor substrate 1 deposited, which forms a barrier. This can be done by a suitable method such as CVD (chemical vapor deposition), oxidation or sputtering.

On the in 2c pictured second semiconductor substrate 2 that already has the contact pads 3 and 3 ' has, the already mentioned metallic surveys are 4 by depositing copper on a surface of the second semiconductor substrate 2 arranged contact pads 3 ' , These surveys 4 , also referred to as Cu-Pillar bumps, which are desirably designed in height, diameter and shape to fit into the holes 11 in the first semiconductor substrate 1 fit into it, z. B. be formed by electrodeposition in a correspondingly structured photoresist. In order to facilitate the galvanic deposition, metal may already be electrolessly on the second semiconductor substrate beforehand 2 have been deposited.

In a further process step, a thin adhesive layer 6 in the holes 11 of the first semiconductor substrate 1 introduced and there on the walls 5 the holes 11 applied. This covers the adhesive layer 6 also the later the second semiconductor substrate 2 facing surface of the first semiconductor substrate 1 except only the released contact pads 3 , In order to keep these free for a later contacting step, the adhesive layer is applied 4 after a corresponding masking of the first semiconductor substrate 1 or of this semiconductor substrate 1 forming wafers. A result of this process step is in 2d shown.

Subsequently, the two semiconductor substrates 1 and 2 put together so that the metallic elevations 4 to form the vias on the adhesive layer 6 lying in the holes 11 in the first semiconductor substrate 1 to come to rest. This process step, the result in 2e is shown, happens in the present embodiment, for example, when the semiconductor substrates 1 and 2 are still present in the form of the wafer, so before any subsequent separation of the semiconductor wafer into individual chips or chip stack. The adhesive layer 6 , which is formed from a polymeric adhesive, cures after joining the two semiconductor substrates 1 and 2 from what is achieved by setting a suitably adapted temperature profile, z. B. by so-called polymer curing. When assembling the two semiconductor substrates 1 and 2 will also be the further conductive connections between the semiconductor substrates 1 and 2 made by the opposing contact pads 3 be joined together by small amounts of solder or conductive adhesive applied there. The contact pads serve here 3 also as mechanical connecting elements between the semiconductor substrates 1 and 2 ,

In a further process step, the result in 2f is illustrated, the first semiconductor substrate 1 at a second semiconductor substrate 2 opposite side so far removed and thereby thinned, to ends of the metallic elevations 4 on this side are exposed and there Durchkontaktierungsflächen 12 form.

Finally, on a second semiconductor substrate 2 facing surface of the first semiconductor substrate 1 a Anschlußmetallisierungsebene or conductor track level for contacting by the surveys 4 formed vias, which are used to form interconnects and the connection pads 8th is structured. The wiring and pad metallization thus formed eventually becomes largely in the already mentioned insulator layer 10 a bed. The stage of the manufacturing process thus achieved is in 2g displayed. After the standard application of the solder bumps 9 , which serve as a connection to a next stack level or to a substrate, on the connection pads 8th Finally, one obtains the finished semiconductor-based circuit already with reference to 1 has been described and forms a microelectronic component three-dimensional structure with electrical feedthroughs.

variations of the described embodiment can arise z. B. with additional Contact surfaces, which can be provided with solder bumps, as well as by a use different individual processes (eg laser structuring, electroless Separation of seed bearings and other process steps known per se).

The method described makes electrical connections between the two semiconductor substrates 1 and 2 or produced between the corresponding semiconductor wafers, which are extremely short by the described measures compared to other construction methods and thus realize advantages in terms of the electronic characterization of a total system thus obtained, namely in particular short signal propagation times, a loss of power reduction and an advantageously low external field.

The described method forms an alternative technology to currently used methods, let yourself realize relatively inexpensive and also brings high process integration compatibility. In particular, no high-temperature processes are necessary, which at the other, already used procedures z. T. an exclusion criterion for the used semiconductor components can form. In addition, the procedure can be applied to different types of wafers and thus allows a flexible way of three-dimensional integration of semiconductor wafers or parts of semiconductor wafers or chips.

Of the proposed approach is that the process of making vias is split on two semiconductor wafers. Be on a part Metallization structures produced with high aspect ratios and on the second wafer is carried out exclusively the realization of holes, u. U. with additional Insulation (passivation layer).

By adjusted joining of both wafer parts, the metallization structures are inserted into the holes (vias) sunk in advance by suitable materials which act as adhesive and insulation layer, for. T. be filled. When merging the Both wafer parts become the adhesive layer, which on the one hand serves as insulation and on the other hand serves as a compound adhesive layer displaced. For this can z. As polymers are used.

By then thin of the wafer composite from the back of the wafer, which with holes was provided takes place in the described embodiment by grinding and etching and subsequent Planarization process (eg CMP, which means chemical mechanical polishing stands) an exposure of the inserted metallization structures. Subsequently is by usual Process of semiconductor technology the processing on the wafer side, in particular for applying the thin-film wiring plane and a contact metallization for the connection of the semiconductor component to a substrate, continued.

The Procedure has no restrictions on the Use of the selected Materials for via-fills, to form the necessary diffusion barrier layers and insulation. So can the Barrier layers z. B. by sputtering on the raised metallization layers (Copper columns) or other procedures before joining the two preprocessed Wafers are realized.

The advantage of this method is that the raised metallization structures (eg, copper pillarbumps) are replaced by standard methods of semiconductor technology, e.g. As wafer bumping, by means of photolithographic structuring and electrodeposition, herge completely separate can be made. For this, no high-temperature process is necessary, which could adversely affect the functionality and yield of the functional components. Metallization structures with elevations of up to several 100 μm can be realized with this method.

The Preparation of the wells or holes (vias) can be active on and passive silicon wafers. The same applies to the production of raised metallization structures. With this approach can Three-dimensional arrangements of semiconductor wafers can be realized. By alternating changes of "holes" and "elevations" can in principle an unlimited Number of levels (wafers) are joined together.

The Method allows a cost-effective production of so-called coaxial conductor passages through silicon. In In this case, metallization layers are formed on the wafer with the recesses on the sidewalls deposited. This can be z. B. by the combination of sputtering and galvanic deposition or "electroless seed layer "and galvanic deposition take place. Made in this way Coaxial via structures have particular advantages thereby on that between signal and mass no silicon bulk material available and the manufacturing process is relatively easy to implement.

Of the inventive proposal is independent of which, in what way and with what methods the wells or metal elevations (eg copper columns) can be realized. Also is it for the inventive approach irrelevant which materials are used. The embodiment represents only an exemplary example of the realization of a via with so-called copper pillar bump structures which is of particular interest in the field of 3D system integration (Stacking) of semiconductor components.

It is also irrelevant whether the active or passive wafer with the elevations or depressions is provided or for multiple stacks a corresponding combination is executed.

Of the inventive proposal also has no restrictions in terms of the geometries used. Thus, the inventive approach is independent of whether the elevations or depressions are round, square or other have geometric shapes.

The Method is particularly suitable for the three-dimensional integration of semiconductor components which process independently of each other can be. The three-dimensional system architecture can be especially for the production of microelectronic systems, such. B. stacking memory devices, Microprocessors, ASICs, transceivers and other electronic elements, be used.

Claims (16)

Method for producing a semiconductor circuit with a three-dimensional circuit topology, comprising the following steps: - producing at least one hole ( 11 ) in a first semiconductor substrate ( 1 ), - manufacture of at least one metallic survey ( 4 ) on a surface of a second semiconductor substrate ( 2 ), - applying an adhesive layer ( 6 ) on a wall ( 5 ) of the at least one hole ( 11 ) in the first semiconductor substrate ( 1 ), - joining the first semiconductor substrate ( 1 ) and the second semiconductor substrate ( 2 ) such that the at least one metallic survey ( 4 ) to form a via on the adhesive layer ( 6 ) lying in the at least one hole ( 11 ) in the first semiconductor substrate ( 1 ) comes to rest. Method according to claim 1, characterized in that at least one of the semiconductor substrates ( 1 . 2 ) is formed by a semiconductor wafer, preferably of silicon. Method according to one of claims 1 or 2, characterized in that in at least one of the semiconductor substrates ( 1 . 2 ) an electronic circuit integrated by the metallic survey ( 4 ) is contacted directly or indirectly. Method according to one of claims 1 or 2, characterized in that the at least one hole ( 11 ) in the first semiconductor substrate ( 1 ) is first executed as a blind hole, wherein the first semiconductor substrate ( 1 ) after assembling the two semiconductor substrates ( 1 . 2 ) on a second semiconductor substrate ( 2 ) far away until one end of the metallic elevation ( 4 ) is free on this page. Method according to one of claims 1 to 3, characterized in that the at least one hole ( 11 ) is produced by etching or by laser structuring. Method according to one of claims 1 to 5, characterized in that the at least one metallic survey ( 4 ) is formed by galvanic and / or electroless deposition of metal. Process according to claim 6, characterized records that the metal forming the survey ( 4 ) is deposited in a recess of a correspondingly structured masking layer. Method according to one of claims 6 or 7, characterized in that the at least one survey ( 4 ) on a contact pad ( 3 ' ) of the second semiconductor substrate ( 2 ) is formed. Method according to one of claims 1 to 8, characterized in that the adhesive layer ( 6 ) is formed from a polymeric adhesive, which after the joining of the two semiconductor substrates ( 1 . 2 ) hardens. Method according to one of claims 1 to 9, characterized in that the resulting circuit after joining the two semiconductor substrates ( 1 . 2 ) is heated or cooled to prevent setting and / or curing of the adhesive layer ( 6 ). Method according to one of claims 1 to 10, characterized in that prior to the application of the adhesive layer ( 6 ) an insulation layer and / or barrier layer ( 7 ) on the first semiconductor substrate ( 1 ) is applied. Method according to one of claims 1 to 11, characterized in that at least one further conductive connection between the second semiconductor substrate ( 2 ) and a semiconductor substrate ( 2 ) facing surface of the first semiconductor substrate ( 1 ) is provided. Method according to one of claims 1 to 12, characterized in that on a second semiconductor substrate ( 2 ) facing away from the surface of the first semiconductor substrate ( 1 ) a conductor track plane for contacting by the at least one survey ( 4 ) is applied to the formation of printed conductors and / or connection pads ( 8th ) is structured. Method according to one of claims 1 to 13, characterized in that in this way a stack of more than two interconnected semiconductor substrates ( 1 . 2 ) is formed. Semiconductor-based circuit with three-dimensional circuit topology, comprising a first semiconductor substrate ( 1 ) and a second semiconductor substrate oriented parallel thereto ( 2 ), wherein the first semiconductor substrate ( 1 ) has at least one via, which is formed by a metallic elevation ( 4 ) on a first semiconductor substrate ( 1 ) facing surface of the second semiconductor substrate ( 2 ) and the one hole ( 11 ) in the first semiconductor substrate ( 1 ), wherein a lateral surface of the metallic elevation ( 4 ) by an adhesive layer ( 6 ) with a wall ( 5 ) of the hole ( 11 ) connected is. Semiconductor-based circuit according to claim 15, can be produced by a method according to any one of claims 1 to 14.