WO2009040109A1

WO2009040109A1 - Method for producing wafers from ingots

Info

Publication number: WO2009040109A1
Application number: PCT/EP2008/008086
Authority: WO
Inventors: Christine Fugger; Edith Zimmermann
Original assignee: Schott Ag; Wacker Schott Solar Gmbh
Priority date: 2007-09-24
Filing date: 2008-09-24
Publication date: 2009-04-02
Also published as: DE102007045455A1; EP2205415A1

Abstract

A description is given of a method for producing wafers from ingots comprising adhesively bonding the ingot (4) to a first surface of an ingot carrier (3), dividing up the ingot into wafer slices and releasing the adhesive bond to free the wafer slices formed in this way. The method is distinguished by the fact that the first surface of the ingot carrier has an x layer rich in silanol groups (SiO).

Description

Process for the production of wafers from Ingots

description

The invention relates to a method for the production of wafers by dividing a material block mounted on a carrier.

Wafers are thin disks or carrier plates on which electronic, photoelectric or micromechanical devices are arranged. Such wafers usually consist of polycrystalline or monocrystalline material, such as silicon, gallium arsenide, indium phosphide or z. B. also sapphire or corundum in the LED technology. In addition, glass or plastic wafers are also used, such as in microlaboratory techniques. For the production of such wafer slices usually larger blocks of a raw material (one or polycrystalline or even a-morph) are cut into individual slices, in particular sawn. Such material blocks are also referred to as ingots or as bricks. The division itself is usually done with wire saws. Preference is given to multi-wire saws which divide a block into many wafers at the same time. For sawing usually the ingots are arranged on a support plate and then fixed in the dicing or sawing device. When sawing the Ingotblocks they must be completely, ie cut across its entire cross section away, which would lead to a sawing of the usually metal Sägegut- or Maschinenenträger or carrier plate in the sawing device, whereby the saw wire would break. It is therefore customary to arrange a further carrier plate (ingot carrier) of a mostly cheaper brittle material between the machine or Sägegutträger the sawing device and the ingot to be sawn, which can be discarded after use. A common material for this purpose is a glass plate. In this way, when sawing, the wafers can be completely sawn through the raw material blocks into this ingot carrier without causing a wire. In this way it is possible to complete the wafers Saw out of the ingot without injuring the machine support, the sawn wafers remain firmly connected to the glass Ingotträger over an edge or stuck firmly. Ie. after sawing, the wafers hang on the sawed ingot carrier. After the end of the sawing process, the wafers are usually detached from the glass ingot carrier by means of a so-called uncapping process. In this case, the adhesive bond with which the remaining edge of the wafer is bonded to the Ingotträger solved. After that, the glassy ingot or wafer carrier is removed from the most metal carrier of the sawing device. This Sägegutträger, also referred to as a machine carrier, must always be laboriously cleaned by hand before reuse according to the prior art, the glass plate is discarded. Usually, the metal Maschinenbzw. Saw material carrier and the glass ingot carrier are cemented from one another under different conditions than the wafer carrier from the ingot carrier.

The bonding of ingot or the subsequent wafers with the glass ingot carrier as well as the bonding of Ingotträger with the metal carrier part of the sawing device is usually carried out by means of adhesives or adhesives comprising a fully hardening epoxy resin, in particular an epoxy resin containing at least two components. It has been shown that after the Entkitten often a part of the adhesive adheres to the wafer edge or the metal machine carrier firmly, which means that both, as already described, the Sägegut- or machine support must be laboriously cleaned by hand also the wafers have to be cleaned by hand. Such a post-cleaning of the wafers creates an additional risk of breakage, which reduces the overall yield. It is therefore desirable to avoid such an effect. Adhesive residues adhering to the wafers prevent automatic wafer separation (also referred to as singulation of the wafers), so that this was not readily possible in the previous methods.

In addition, thinner wafers are being produced to meet the demand for high - performance materials due to rising demand due to increasing demand to satisfy previously described components. So z. B. for the photovoltaic currently produces wafers, which only have a thickness of down to 200 microns. However, solar wafers with a thickness of only 150 μm are already being planned for mass production, with even extremely thin thin-film wafers of about 80 μm being aimed for. However, such thin wafers require a very high adhesion of the adhesive used for the bonding of Ingoträger / ingot. An increased requirement for the strength of the bonding of Ingotträger and ingot is also due to the fact that the side surfaces of the ingots have a low surface roughness of Rz less than 5 microns, better Rz less than 3 microns and more preferably Rz must have less than 1 micron, the risk of breakage of the thin Do not increase wafers in the following process steps. The consequently no longer rough but smooth surfaces make it difficult for the adhesive to produce a good strength of the bond. There is therefore a need to use new adhesives which have a higher adhesive strength or to increase the strength of the bond by other measures in the case of further use of established adhesive. Therefore, many attempts have already been made to solve these problems. Thus, for example, commercially available two-component epoxy resins which consist of reacting resin components and a hardener, and later with special Entetizers, z. B. from alkaline solvents, which also contain detergents, are removed again. In order to increase the adhesion of the adhesive bond, the surface of the ingot carrier to be bonded to the ingot and also the surface of the ingot carrier to be glued to the machine carrier are roughened in all current methods for sawing wafer slices. In addition, it is customary to improve the adhesive behavior to degrease each of the surfaces to be joined together and coat with a primer. The adhesion promoters are usually applied in dilute form in a vaporizable organic solvent such as n-propanol. As such adhesion promoters, for example, in the case of epoxy resin adhesives of the company DELO, the bonding agent DELO-SACO® SIL E of the same company or, in the case of araldite adhesives, Huntsman the adhesive BETAWIPE TM VP 04604 from Dw Automotive AG used.

However, it has been found that the formation of such adhesives dissolved in a solvent does not readily lead to a uniform, efficient surface coating and thus to a non-homogeneous, non-uniform distribution of the adhesive applied thereto. Furthermore, the use of these primer requires the fulfillment of safety requirements of explosion protection, which require a great deal of effort when deciding on the use of a primer. Despite this expense, the flow behavior (wetting behavior) of the subsequently applied adhesive is insufficient, as a result of which the adhesive action is often insufficient, especially when gluing 6 "ingots and when sawing these ingots into thin wafers with glycol-based slurries.

In addition, according to the state of the art, the surface which has been degreased and, if appropriate, treated with adhesion promoter must be as promptly as possible, d. H. The adhesive can be applied within a few minutes and connected to the counterpart to be bonded. For this reason, a production of ready-to-paste ingots is not readily possible and the production must be coordinated with one another in terms of time.

From DE 3403894 C1 a method for coating metallic dental prostheses is known, in which in a flame hydrolysis burner an oxidizable silicon compound is burned together with a combustible gas, whereupon a layer of polymerized (SiO) χ Network separates. Such a layer can then be such. As described in DE 4012086 A1, coated with a silane as a primer for later applied coatings.

Moreover, it is known from US Pat. No. 4,364,731 to deposit silicon oxide of high-purity quartz glass on a dental prosthesis by means of a magnetron sputtering device. The invention therefore has the aim of providing a method for producing silicon wafers, which not only ensures the firm bonding of even extremely thin wafer slices after sawing with their carrier plate, but also allows this bond to be loosened again easily, it being ensured that the adhesive material essentially, in particular completely, remains on the ingot or wafer carrier.

In addition, when Entkitten of Ingotträger and Sägemaschinenträger preferably the entire adhesive material also adhere to Ingotträger or preferably on any of the glued surfaces, so that the machine frame does not have to be laboriously cleaned from adhering adhesive residues.

In addition, throughout the process to additional process steps such. B. elaborate roughening of support surfaces are dispensed in particular of the Intitute wearer.

Finally, a method is to be provided which allows the production of parts to be bonded in stock, so that at least a production of ready-to-glue parts is available for a short time before bonding.

This object is achieved by the method defined in the claims.

It has been found that by forming a thin reactive silicate layer rich in silanol groups, activation of the surface to be bonded can be achieved. Such a layer is also referred to as a polymeric (SiO) _x network. In principle, such a layer is also by entry of hydrogen, z. Example, as a surface treatment in the manufacture of the glass, or by treatment with a hydrogen plasma possible. Another option is sandblasting with silane. It has been shown that in this way the surface energy of the surface to be bonded can be increased from less than about 35 mN / m to 55 mN / m or even further. The contact angle α formed between the adhesive and the surface to be bonded is therefore approximately 0 °, ie a maximum of 2 ° or a maximum of 3 °, in particular a maximum of 5 °, and is thus much lower than it can be achieved merely by cleaning, degreasing and using liquid adhesion promoters is.

Thus, the flow behavior of the adhesive is significantly improved, whereby a homogeneous distribution and full-surface wetting is ensured.

The coating according to the invention of the surface to be bonded with a reactive silicate layer can take place both by means of a plasma deposition and for the sake of simplicity by means of a thermally activated reaction (flame hydrolysis) of an Si-containing organic or inorganic compound in the flame of a combustible gas, which is usually more accurate than flaming Flammensilikatisierung, is called.

Suitable Si-containing compounds are inorganic silanes, organosilicon compounds such as those of the structure

(R ¹ ) ₃ SiNHSi (R ¹ ) ₃ (1a)

in which R ¹ or R ^{2 are} identical or different alkyl groups. Furthermore, organosilicon compounds of the formula

(R ¹ ) _n Si (OR ² ) ₄ n (1 b)

suitable in which R ¹ and R ^{2 are the} same or different monovalent aliphatic hydrocarbon groups and n integer from 0 to 3. Further suitable organosilicon compounds are those of the structure

wherein R ^{3 is} hydrogen or a monovalent aliphatic hydrocarbon group m integer of at least 1, in particular 1 or 2 and p integer of 3 to 5.

Examples of the monovalent aliphatic hydrocarbon groups are methyl, propyl, n-butyl, tertiary butyl, cyclic alkyl groups, AVinyl and allyl groups.

Examples of the compounds represented by the formulas are Si (OCH3) 4, Si (OCH2CH3) 4, CH3Si (OCH3) 3, hexamethyldisiloxane (HDMS), hexamethylcyclotrisiloxane, octamethylcyclotetrasiloxane and decamethylcyclopentasiloxane. It is also possible to add further additives to the flame which increase the reactivity of the reactive silicate layer.

In this case, the surface to be coated or flamed is guided past the flame at a defined distance, with the reactive silicate layer depositing on the preheated surface to be coated. The surface must not thereby be heated in the manner described in the prior art temperature of more than 110 ⁰ C. It is sufficient a temperature of max. 60 ° C, especially max. 50 ° C, and preferably from 45 ⁰ C +/- 2 ⁰ C completely off. This temperature is easily reached by an infrared heater or the To ensure flame. With the flame, the warm-up is particularly easy, because the burner needs to sweep the surface to be burned only once, without the flame was added to the Si-containing compound.

The distance to be selected from the burner front to the flaming surface depends on the operating mode of the burner. The fuel gases can already be mixed inside the burner, optionally even with the Si-containing compound or all components can only be mixed outside the burner. In the latter case, of course, the distance to be chosen is greater than in the former. Preferably, the burner design and the operating mode is selected so that the distance is selected at least 10 mm and less than 150 mm. This distance is minimally greater than the length of the inner flame cone. Distances in the range of 25-50 mm are preferred if surfaces of the size approx. (400-800) mm x approx. 130 mm or (400-800) mm x approx. 160 mm are to be coated for the application. An optimal distance can be easily determined by a few experiments and depends on the selected flame cone length and the respective concentration of the oxidizable silicon compound. But there are also distances still possible, as described for example in DE 3403894 C.

According to the present invention, a burner with a round burner front side can be used, which is guided by hand over the surface to be flamed. For the o. G. However, to flare surfaces, it is advisable to use a narrow burner of width about the width of the surface to be flamed. This can be slowly and automatically led to warm up and flaming over the surface to be flamed. Moving speeds of 100 to 500 mm / s are preferably selected, with 150 to 300 mm / s or 180 to 250 mm / s and especially 200 +/- 10 mm / s being preferred.

It has also been shown that flaming brings advantages for glued glass surfaces. In particular, these advantages occur when the glass is stuck together with epoxy resins as is the case with the bonding of ingot carrier / ingot or ingot carrier / machine carrier. Namely, an improved adhesion between adhesive and glass plate was found according to the invention. It has been found that form chemical bonds between reactive silicate layer and epoxy resin, whereby the adhesion is improved, in particular improves the resilience to train and shear.

The thickness of the thin (SiO) χ layer is preferably at least 2 nm, in particular at least 3 or 4 nm, with at least 5 or 6 nm being preferred. The maximum thickness is preferably at most max. 20 nm or 18 nm, with max. 15 nm and 13 nm are preferred. Typical max. Thicknesses are 12 and 10 nm, respectively.

Typical fuel gases suitable for flaming are, in particular, hydrocarbon gases, C1-C5 gases, in particular C1-C4 gases, being preferred. A most preferred fuel gas is propane. The combustion oxygen needed for combustion can be supplied as pure gas or air. In addition, it is possible by choosing the firing conditions, d. H. by the targeted supply of oxygen or of higher-chain hydrocarbons, which optionally have reactive functions, to deposit a silicon oxide layer which contains organic radicals covalently.

In the method according to the invention is preferably in addition to the support side, which is glued to the raw material block or ingot, and the second surface facing away from it coated with a polymeric (SiO) χ network, ie that side which with the machine support Trennbzw. Sawing device is connected. Thereby, the compression shear strength of the adhesive bond is increased, and the usability secured by adhesives entkitten below 100 ⁰ C, preferably below 95 ^0C. Furthermore, it is ensured by the flaming of the machine carrier to be bonded to the surface of the ingot carrier that adhesives can be used for this adhesive bond, which at temperatures below 150 ⁰ C and 130 ⁰ C. soften, with the help of mechanical aids (eg spatula) can be easily solved and remain after loosening the adhesive bond completely on the Ingotträgerplatte. In the latter, it is achieved that, in the case of a decoction of ingot carrier and machine carrier, the adhesive likewise likewise remains on the ingot carrier, which is to be used anyway only once.

An advantage of the procedure according to the invention is also that a longer time between flaming and the subsequent gluing, d. H. without further notice several days, in particular up to 2 days and in principle up to 24 hours, may pass. According to the prior art, according to which either only degreased or degreased and an adhesion promoter is applied, the maximum time allowed for bonding is 1 h. This also shows the particular advantages of the method according to the invention.

In an embodiment which is particularly suitable in the process according to the invention, the epoxy resin which is an at least 2-component resin is an amino-substituted silicic acid, in particular the general formula H ₂ N-Ri-Si (OH) ₃ or H ₂ NR ₁ -Si ( OR ₂ ) S is admixed as an adhesion promoter, wherein Ri is an alkyl or alkoxy group of 1-20, preferably 1-10, in particular 1-5 C atoms and R _{2 is} an organic radical which is a methyl, ethyl, propyl - or isopropyl group can be. Most preferably, Ri contains one, two or three C atoms. If such a coupling agent is added to the epoxy resin or a corresponding amino resin, then the respective amino group reacts with the epoxy group already in the adhesive. When the appropriate resin is then applied to the flame-silicated surface, the silane-alkoxy groups react with the SiOH groups on the flame-silicate surface to form a covalent bond formed between the adhesive and the surface. Then the adhesion-promoting effect can be ensured by a continuous chemical bond, starting from the SiO ₂ in the glass over the reactive (-O-Si) _X -OH layer. In principle, it is also possible to apply the amino-substituted silicic acid first to the silanol-rich silicate layer of the surface and only then to the adhesion promoter-free resin. Commercially available adhesives of the prior art can be used in the process according to the invention, adhesives composed of epoxy resins, in particular two-component epoxy resins, being preferred.

In adhesives that are usable in the invention and cement below 100 ⁰ C corresponds, preferably in hot water, it is ensured that the adhesive adheres to neither of the two initially bonded surfaces. In this case, the machine support plate can even be removed from the hot water bath, for example by a robotic arm.

A typical ingot carrier used is preferably glass, but other typically suitable brittle-hard materials may be used. The ingot carrier is used only once. In suitable cases, however, it has also proven to be expedient, simultaneously or instead of the side of the ingot carrier facing the saw machine carrier, to also fire the side of the machine carrier to be glued according to the invention. In a particularly preferred embodiment, however, all the parts to be joined together are subjected to a conventional degreasing treatment, in particular before flaming.

The advantage that adhe- sive to the ingot carrier / ingot as well as to the decoating of the bond ingot carrier / machine carrier, adhesive residues always adhere to the ingot carrier, has been achieved with all examined adhesives, in which the decoating of the bond ingot carrier / ingot below 70 ° C and the decoating of the bonding Ingotträger / machine carrier below 150 ⁰ C, possibly already below 130 ⁰ C, takes place.

The flaming according to the invention, preferably the flaming of the intradent carrier plate, can be used for sawing with all known sawing slurries. That is, glycol-based saw slurries, oil-based saw slurries, as well as water-based saw slurries are usable. This even Sägeslurries can be used, which cause the cured adhesive to swell during the sawing process. Sources in this case means that the cured adhesive substance undergoes an increase in mass by absorption of the carrier liquid. The use of oil-based Sägeslurries is generally not critical, since in these the cured adhesive undergoes no mass increase. However, when using glycol based sawing slurries, which are available for production typically have a 1-4% mass intake during sawing, the solution of the present invention has particular application potential. Adhesives which have particularly desirable properties, but can not be readily used due to insufficient adhesive force (shear compressive strength) under glycol glycol saw blade application conditions, are applicable when the glass ingot support plate is flame-treated because the compressive shear strength of the adhesive bond is therefore less than 3 5 MPa is increased to values of greater than 3.5 MPa.

In a preferred embodiment for the bonding of Ingotträgerplatte with the machine support plate, the epoxy resin contains a filler material, which may be particulate, in particular a filler, which swells in a suitable environment, especially under the action of temperature. Such adhesives are z. B. from Valtech Corporation / USA or DE-LO / Germany available, but either not yet or only limited to the state of the art suitable for production. Such fillers are particularly finely divided and can be both organic and mineral fillers, such as silicates or silicate mixtures. Organic materials include cellulose or its derivatives or polyvinylpyrolidone. In a further suitable embodiment according to the invention, the adhesive contains as filler a blistering agent which can be blistered thermally and / or by a suitable reagent, depending on the agent chosen. Such agents are the expert z. B. known as alkyleneamines or can be determined by simple experiments.

In a preferred embodiment for the bonding of ingot and inert resin, it has proved expedient to use an adhesive material, in particular an epoxy material, which is not thermally but in the Acidic or alkaline at low temperatures, ie below 50 ⁰ C or below 45 ⁰ C, preferably in an acidic or alkaline medium entkittet. However, minimum temperatures above room temperature, especially above 30 ^° C., preferably above 35 ^° C., are preferred. Typical pH values in acidic are less than 4, in alkaline at least 9, preferably at least 10 and especially at least 12.

After sawing the ingot into wafers, the following process steps are carried out according to the present invention:

First, the formed wafers are usually washed with a prior art washing solution to remove adherent sawing slurries. Such commercially available washing solutions contain water, at least one cleaner and surfactants. Second, they are entkittet in an acidic or alkaline immersion bath, wherein supportive ultrasound can be coupled into the dipping bath to mechanically assist the chemical release of the adhesive bond. It has been shown that, as a result of the flame-proofing of the ingot carrier, the adhesive bond does not dissolve already during the sawing process, but always only during the de-cementing process. In this Entkittungsprozess the inventively achieved decisive new advantage that all adhesive residues adhere to the glass plate. This succeeds particularly well when the ingot support was not roughened to a roughness of Rz> 20 microns as in the prior art, but was left completely smooth. Only a degreasing of the surface is required. The fact that all adhesive residues remain on the glass plate, they do not get into the or the cleaning baths. These adhesive residues, which usually occur in the form of threads according to the prior art, do not occur in the procedure according to the invention and therefore do not have to be laboriously and manually removed. A fully automatic cleaning process without the need for manual intervention is therefore possible according to the invention.

For bonding of Ingotträger and machine carrier adhesives are preferably used, which auskitten due to elevated temperature, but in the lower Entkittungstemperaturen the bonding Ingot / Ingotträger still retain their complete adhesive effect. According to the invention adhesives are used for this purpose, which preferably have a softening point above 60 ⁰ C, especially above 70 ⁰ C, with adhesives having a softening point above 80 ⁰ C are particularly preferred. Suitably are adhesives which are sufficiently strong in both the prevailing during sawing temperatures and at the prevailing during the Entkittung the bonding of Ingotträger and Ingot temperatures and soften preferably at temperatures below 150 ⁰ C, in particular below 130 ⁰ C, with such adhesives are preferred with a softening point of less than 100 ⁰ C, very particularly preferred are adhesives having a softening point of less than 97 ⁰ C.

These adhesives entkitten in a way in the smallest homogeneously distributed filler particles swell under the influence of temperature and break the bonds prevailing within the adhesive layer bonds. According to this mechanism, especially adhesives work between 150 ⁰ C and 100 ⁰ C auskitten.

Particularly preferred fillers for another type of higher temperature detackifying adhesives are those which swell in hot water and thereby kitted off. With these adhesives is the formation of bubbles in the Entkitungstemperaturbe- range from 100 ⁰ C to 80 ⁰ C to observe that accompanies the breaking open of the adhesive bond. Entkittung in hot water has the advantage over the Entkittung in a furnace that the machine support plate automated, z. B. by a robotic arm incl. Gripper, can be removed from the hot water.

In the case of a softening of the adhesive in an oven and subsequent release of the adhesive bond by means of mechanical aids (eg spatula), flaming the surface of the ingot carrier makes it possible for the adhesive to adhere completely to the ingot carrier plate. This is achieved particularly well if the surface of the ingot carrier plate made preferably of glass does not roughen but remains smooth, but has been degreased and flamed according to the invention. After decoating of ingot carrier and machine carrier Adhere to the machine carrier no more adhesive residues. However, before reuse of the machine base plate, it is preferably cleaned to ensure unrestricted reuse of the machine base plate and to ensure reproducibly good surface quality from reflame. Only by the procedure according to the invention, this cleaning no longer has to be done manually by spatula u. Like. And chemically done but it is sufficient for a dry cleaning. However, this dry cleaning is possible automatically in a cleaning plant (eg Miele industrial cleaning plant).

Machine support plates are typically made of aluminum or stainless steel.

If flaming according to the invention is used when using a machine support plate made of aluminum, aluminum silicates are formed on the surface, which form a very good adhesion transition of aluminum and epoxy resin adhesive. The required according to the prior art mechanical removal of an AI ₂ O ₃ layer of the surface of the aluminum plate in particular before re-bonding can be omitted by the invention Flammen.

If a machine base plate made of stainless steel, a high-alloy steel is suitably used, for. With a Si content of 0.5 to 3% (eg a steel with the standard No. 1.2085, or the DIN designation X33CrS 16). Thus, the molecules of the polymeric (SiO) x network have the possibility of forming bridge bonds to the Si of the high-alloy steel, thus improving the adhesive properties.

1 shows a typical structure of the bonds of a composite to be cut from the machine or Sägegutträger 1, which is bound by means of a first adhesive 2 to the upper side of the Ingotträgers 3, to which in turn the Ingotträger 4 glued by means of a second adhesive 5 is. 2 shows the process steps required according to the prior art using the example of the use of a machine support plate made of aluminum.

3 shows a schematic representation of a wafer sawing process using the procedure according to the invention.

The present invention will be explained in more detail by the following examples.

Example 1 :

In a prior art glycol-based sawing process, the glycol swells the cured adhesive present between Si ingot and the ingot carrier. The reason for this is the presence of glycol-like compounds in the cured epoxy resin, which are loosened by glycol.

Table 1 shows the change in the compressive shear strength of a bonding of a roughened by the prior art glass plate surface with a silicon surface using the commercial adhesive Araldit 2101 or LMD 2684 depending on the storage time in glycol at 40 ⁰ C. A storage of 4 h at 40 ⁰ C. simulates the operating conditions to which the bonding would be exposed in the real process.

It was a degreased, but not roughened glass plate, with a silane-containing propane gas flame continuously, that flames the entire surface evenly. With such flame treatment, the respective glass plate was passed at a speed of 200 mm / sec at the sharp cone of the flame at a distance of 35 mm. Subsequently, these glass plates were bonded both to a silicon block and to a stainless steel or aluminum plate and the respective compressive shear strength was determined in accordance with the method described in Delo Test Standard 5 (DELO Industrie Klebstoffe, D-86899 Landsberg). In this case, this bonding according to the invention was compared with bonding according to the prior art, in which the each surface to be bonded was roughened and degreased. The results are shown in the following table.

Table 1 shows the comparison of a bonding of a rough glass sample according to the prior art for bonding a glass sample according to the invention smooth and flamed (flame-silicate) with a silicon sample.

Table 1

It turns out that by eliminating the roughening of the glass plate and instead carrying out a flame treatment, an increase in the strength of the bond is achieved.

This improvement effect is achieved not only in the adhesive used in Example 1. In particular, it is particularly evident in the adhesives which contain a bonding agent. Already a content of 1% is completely sufficient.

The increased compressive shear strength is mainly due to the strength of the adhesive on the glass plate. For this reason, it can be observed that, when a gluing of ingot and glass plate, which has been carried out according to Experiment 2, has been removed, all adhesive residues remain hanging on the glass plate after wafer sawing has taken place. Hardly any remnants of the adhesive penetrated into the Entkittungs- bath with pH <4.

It should be emphasized that the increased compressive shear strength is sufficient to bond insects with a ground surface with a surface roughness of less than 1 μm to the ingot support so firmly that neither the ingot nor individual wafers unintentionally detach from the ingot support during sawing and fall off. Example 2:

Example 2 relates to the bonding of ingot carrier plate with the machine carrier plate. Table 2 shows the comparison between the prior art and a first variant of the solution according to the invention.

The flame treatment of the glass plate is carried out as described in Example 1.

It is considered the bonding of a smooth or rough glass plate using the commercially available adhesive Valtron 1230 with a metal plate made of aluminum, wherein the adhesive was cured according to the manufacturer and the burden of the sawing process by incorporation over 4 h in glycol at 40 ⁰ C were simulated , The softening of the filler-containing adhesive takes place in an oven at 110 ⁰ C (30 min.) And by manual Ent Kittung using a spatula.

Table 2

The application of the conditions according to the invention according to Experiment 4 in the practical production process has the effect that after the removal of adhesive all the adhesive adheres to the glass plate. Example 3:

Example 3 relates to the bonding of ingot carrier plate with the machine carrier plate. Table 3 shows how an adhesive that is available according to the prior art but can not be used in production in the case of bonding according to the prior art can still be used by applying a first variant of the process according to the invention. The flame treatment of the glass plate is carried out as described in Example 1.

The prior art shown in experiment 6 shows that the compressive shear strength of the bonding of a plate made of high-alloy steel with DIN designation X33CrS16 with the rough glass plate achieved with the adhesive Valtron 4110 remains below the required 3.5 MPa and thus only limited in production is usable. The curing conditions of the adhesive were chosen as recommended by the manufacturer. Prior art experiment 6 used the manufacturer's recommended primer. The burden of the sawing process by storage for 4 h in glycol at 40 ⁰ C was in turn simulated. The softening of the filler-containing adhesive takes place in an oven at 110 ⁰ C (30 min.). The use of a spatula may assist the peeling process but is not mandatory. The machine carrier comes off so easily and cleanly that an automated removal of the machine carrier plate is possible.

Table 3 The application of the conditions according to the invention according to Experiment 7 in the practical production process has the effect that after the removal of adhesive, all the adhesive adheres to the glass plate. A mechanical removal of adhesive from the metallic machine base plate is not required.

Example 4:

Example 4 relates to the bonding of ingot carrier plate with the machine carrier plate. Table 4 shows the comparison between the adhesive obtainable with the prior art and a second variant of the procedure according to the invention.

The flame treatment of the glass plate or additionally the machine support plate in Experiment 7 is carried out as described in Example 1.

Both Experiments 6 and 7 are experiments according to the invention. They show how an increase in compression shear strength can be achieved by flame-treatment of the glass ingot support surface and high-alloy steel machine base surface.

The curing conditions have been previously optimized and found to be different than recommended by the manufacturer of the adhesive. The burden of the sawing process by storage for 4 h in glycol at 40 ⁰ C was in turn simulated. The softening of the adhesive was carried out by storage in 85 ⁰ C warm water for 20 min.

Surprisingly, it was found that in Experiment 7 too, the adhesive dissolved from both sides of the bonded surfaces and would not adhere to the glass plate as would be expected from Experiments 4 and 7.

Table 4

The application of the conditions according to the invention according to Experiment 7 in the practical production process makes it possible to automate the decarburization. For example, the non-adherence of the adhesive to the machine frame allows this z. B. by means of a robotic arm to lift from the hot water. He should also automatically go through an automatic cleaning before re-use.

* * *

Claims

claims

Anspruch [en] A process for producing wafers from ingots comprising bonding the ingot to a first surface of an ingot carrier, dividing the ingot into wafer slices and dissolving the bond to release the wafer slices so formed, characterized in that the first surface of the ingot carrier is a (SiO) _x Layer has.

2. The method according to claim 1, characterized in that the (SiO) _x - layer is applied by means of a reactive Si compound.

3. The method according to any one of the preceding claims, characterized in that the cutting of the ingot takes place with a Mehrfachdrahtsägevorrichtung having a Sägegutträger.

4. The method according to any one of the preceding claims, characterized in that the ingot carrier has a second surface which is fixedly connected to a Sägegutträger.

5. The method according to any one of the preceding claims, characterized in that Ingotträger and Sägegutträger are glued together.

6. The method according to any one of the preceding claims, characterized in that the second surface of the ingot carrier and / or the first surface of the Sägegutträgers an (SiO) _x layer applied.

7. The method according to any one of the preceding claims, characterized in that the (SiO) _x layer is produced by flame silicization of the first surface with a mixture of a combustible gas / fuel oxygen and an oxidizable Si compound.

8. The method according to claim 3, characterized in that the gas is a hydrocarbon gas.

9. The method according to any one of the preceding claims, characterized in that the ingot carrier is a glass plate.

10. The method according to any one of the preceding claims, characterized in that the bonding takes place by means of a softenable epoxy resin.

11. The method according to claim 10, characterized in that components of the epoxy resin swell under the influence of temperature.

12. The method according to any one of claims 10 - 11, characterized in that the epoxy resin softenable at a temperature of below 150 ⁰ C.

13. The method according to any one of claims 6-12, characterized in that ingot and Ingotträger are connected by means of an adhesive having a different softening temperature, as the adhesive used for the bonding of ingot and Sägutgutträger.

14. The method according to any one of claims 6 to 13, characterized in that the adhesive adheres better to the ingot carrier, in particular, than to injured / wafer and / or to the sawmill carrier.

15. The method according to any one of the preceding claims, characterized in that the adhesive used for bonding ingot and Ingotträger has a higher adhesiveness than the adhesive used to connect Sägegutträger and Ingotträger.

16. Wafer obtainable by the method according to one of claims 1-15.

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