DE10107405A1 - Semiconductor film which can be directly processed on conveyor belt production line comprises semiconductor tape formed by ion implantation - Google Patents

Abstract

A single-crystal semiconductor film in the form of a tape (1) is manufactured from a single crystal (2) by ion implantation (5,6,7), and the top layer is mechanically separated to form a continuous tape. The semiconductor tape can be wound on rollers (8), to enable further processing (27) without a support substrate material. Independent claims are also included for: (a) a method of using the product (b) a bonding method (c) a conveyor belt production method

Description

The present invention relates to a single-crystalline semiconductor film in the form of a tape that passes through Ion implantation is made from a single crystal, without the need for a silicon wafer production necessary is. The semiconductor tape can be wound into rolls, it enables further processing without supporting substrate material and it enables new continuous manufacturing processes of construction elements.

The production of semiconductor films from a single crystal (ingot) in the form of tapes wound on rolls This saves the manufacturing of wafers and enables the direct processing of single-crystal semiconductors Success, enables cost-effective SOI (Silicon on Insulator) and multilayer semiconductors, facilitates the manufacture position of semiconductor components, enables new flexible components, simplifies the connection technology (back-end area) and the production of printed circuit boards. Semiconductor tapes, comparable to large ones Paper rolls in papermaking, reduce costs in semiconductor production and make you fast and continuous production process, comparable to rotary machines in the printing industry, possible.

The field of application relates to another by reducing the cost of the raw material Cost reduction in the manufacture and by a cost reduction in the assembly technology from elektro components in almost all areas of semiconductor technology. Today's semiconductor manufacturing is based on single slice or batch processes, a semiconductor band can make this one of the essential cheaper production line production (rotary systems) with continuous production process with new Her position procedure to be replaced. Above all, the manufacturing costs for simple components with large ones Space requirements (e.g. solar cells) are thus significantly reduced. Relative to the conventional thick semiconductor wafers (approx. 0.7 mm) is the usable semiconductor surface for thin foils (1 µm) Much larger with the same material consumption. This significantly reduces the price per usable Semiconductor surface. Not only with silicon but also with very expensive semiconductors such as B. SiC and GaAs can This process can be used and therefore the prerequisite for the large-scale use of this Semiconductors are created.

New applications result from the possibility of direct and bilateral processing of the Semiconductor band. This and the precisely adjustable thickness of the semiconductor tape in the micrometer and sub- Micrometer range enable novel components with better properties, e.g. B. faster thin film transistors, multi-layer or thin-film solar cells with higher efficiency, flexible or rollable Components of almost any size (roll-up screens, flexible mobile devices or components on chip cards), better performance components such. B. Thin-film IGBTs for the voltage range below 600 V, and novel sensors and integrated electronic and micromechanical components.  

The state of the art in semiconductor technology is based on the processing of individual semiconductor wafers. This is one of the key points why semiconductor technology is relatively expensive. The semiconductor technology is therefore essentially limited to space-saving components with integrated circuits. solar Cells, flat screens and other large-scale components are expensive and often not competitive with them conventional technologies. Furthermore, due to the relatively thick (approx. 700 µm) slices you have one high semiconductor consumption and can essentially only front processes for the manufacture of integrier Use circuits that limit the manufacturing process. They are usually highly integrated Circuits in microelectronics only a few micrometers of semiconductor material on the wafer surface electrically active, the remaining 99-99.9% of the semiconductor material is not for the function of the component necessary. Due to the thick semiconductor material, flexible components are only with complex thinning process in which the semiconductor wafer is ground off from the back.

State of the art is the production of semiconductor foils by ion implantation. This technology is therefore no longer patentable as such, but special process combinations are technically very interesting and patentable. One example is the so-called "smart-cut" process, which separates a thin film from an output disk with the aid of ion implantation and at the same time bonds it to a carrier disk ^1,2 . The Smart-Cut process brings advantages in Silicon on Insulator (SOI) production and in the diversification of expensive semiconductor materials, such as. B. SiC. A similar process was developed by Genesis (USA). The company Genesis uses a new implantation method (Plasma Immersion Ion Implantation PIII), bonds the discs at room temperature and separates the film by a high pressure blower. Smart-cut technology and comparable technologies require silicon wafers as the starting and carrier material and do not enable the production of a semiconductor tape and the associated direct processing of the semiconductor film. These procedures also require several process steps after implantation (bonding plus temperature or high-pressure blower). The film without backing material cannot be processed. Smart-Cut and similar processes are essentially only suitable for SOI technology and for layer transfer, but not for a new semiconductor technology in which the semiconductor film is processed directly.

With the method shown in FIG. 1, a semiconductor film roll can be produced directly from a single crystal (ingot) without wafer production for the first time with the aid of implantation, which further enables the film to be processed directly (without bonding to a carrier) in a simple and inexpensive manner.

The disadvantages compared to the prior art are that many semiconductor manufacturing processes for the continuous process flow must be newly developed or adapted. Furthermore, the slides Assembly line production only suitable for mass production and not for small series production.

The problems solved with the invention are that with the introduction of a semiconductor tape new ones Possibilities in the manufacture of semiconductor devices result, which in turn new or improved Enable products and cheaper production processes. The double-sided assembly line production of one Semiconductor tape is an essential component in comparison to the current wafer production process for components more efficient production process and usable as key technology. Many areas like that  Production of the semiconductor material, the composition of the semiconductor material (multilayer structure, new material), the production technology of the component, the properties of the components (flexible, improved electrical and mechanical properties), the connection and assembly technology and the Manufacture and properties of the end devices themselves are rationalized or their properties ver repaired. Flexible film components enable e.g. B. Products such as a rollable or foldable computer with integrated screen and keyboard or mobile electronic devices that can be worn as clothing.

An advantage over the prior art is that, for certain manufacturing processes, it is no longer necessary to saw disks from the round single crystal. By implantation, a film or film rolls and thus a semiconductor tape can be produced directly from a single crystal. No cutting is necessary and the surface roughness of the film is significantly lower than that of the sawn silicon wafer, which simplifies the subsequent surface treatment. The usable semiconductor area, the z. B. in the form of about 700 microns thick silicon wafers with a cylindrical single crystal with a diameter of 200 mm and a length of 1000 mm is about 30 m ² , is about 3 orders of magnitude to 30,000 m ² with a film thickness of 1 µm and increased by 4 orders of magnitude to 300,000 m ² with a film thickness of 0.1 µm. This significantly reduces the price of the semiconductor material. Not only with silicon but also with semiconductors such as B. SiC and GaAs, this method can be used, thereby creating the conditions for the large-scale use of these semiconductors. Semiconductors such as SiC and GaAs are not competitive with silicon in many areas due to their high price, although the properties of these materials are superior to silicon for certain applications. A multiplication of the usable semiconductor area can reduce the competitive disadvantages compared to silicon, since then the costs for the semiconductor starting material take a back seat compared to the total costs of the component production.

Another advantage over the prior art is the direct coating of the semiconductor tape without the previously required carrier materials. Furthermore, the semiconductor tape can be processed from both sides in the assembly line. Today's semiconductor production is based on single-slice or batch processes (processing of several slices at the same time). With a semiconductor belt, this single-slice production can be replaced by a much cheaper production line production (rotary systems) with a continuous production process and faster inline production processes. All essential production steps in semiconductor technology such as oxidizing, coating, implanting, coating, exposing, developing and etching can be carried out continuously and in assembly line production. In some cases, processes can be adopted by the printing and film industry. Rotation systems offer the possibility of bonding or gluing several tapes together at high speed, see Fig. 4. This offers several advantages:

• - Manufacture of novel heterogeneous semiconductors from several different layers are composed (different semiconductor layers, semiconductor and insulator layers or a combination of conductor, semiconductor and insulator layers).
• - By joining different doping semiconductor bands, any doping can profiles can be set.  
• - Easy manufacture of three-dimensional circuits by joining processed foils.
• - The thickness of the foils can be varied within wide limits (approx. 0.1-100 µm).
• - New, faster metallization and coating techniques are possible, e.g. B. the photoresist or the metallization can be applied as a photosensitive layer or metal foil.
• - Easy production of foil components
• - Integrated circuits on a semiconductor film can be placed on a modern flexible carrier film welded or welded on both sides (application e.g. for the chip card). Through flexible Foil chip technology can significantly simplify chip assembly and wiring. Size Parts of today's chip assembly and subsequent PCB production are no longer or very much much easier possible or can be summarized.

The direct processing of a semiconductor tape continues to enable new, more powerful components such as the production of thin film components with better electrical properties such. B. transistors, solar cells and power devices or the production of thin film devices with better mechanical Properties, e.g. B. rollable or flexible. Processing on both sides, e.g. B. structuring, doping, Metallization etc. enables smaller (integrated circuits), faster (transistors) components and Components with higher efficiency (solar cells) and higher sensitivity and functionality (Sensors, micromechanics). The size of the components is no longer dependent on the diameter of the semiconductors disc dependent. This brings advantages above all in the production of large components such. B. Solar cells or flat screens.

There are advantages over the prior art in addition to the mentioned front-end area in the Assembly technology (back-end area) of components and in the manufacture of end devices. The back-end area and the manufacture of printed circuit boards is a major cost factor in the manufacture of electronic Assemblies and in many cases exceeds the semiconductor production costs. The back-end area includes in usually that after the chip production on the silicon wafer (front-end area) the components are tested and the wafers are sawn, then the chips are bonded, wired and encapsulated. After Component manufacturing follows PCB manufacturing, which also involves a series of production steps includes (structuring, assembly, soldering). The production line for semiconductors complements in ideally with the modern and flexible foil circuit board production. Many process steps like sawing, Bonding, wiring, encapsulation, assembly and soldering are much easier and sometimes not at all to a lesser extent necessary. Since there is no area limitation as in the production of panes and the semiconductor tape can be produced more cost-effectively, the component itself can be increased in area be that with appropriate metallization and insulator levels as a flexible circuit board can be used. This means that the front-end, back-end and PCB production are combined can be, which enables an enormous simplification and miniaturization of electronic devices. The main component already contains the circuit board and can be equipped with additional components become. Foil components can also be quickly and easily placed on conventional circuit boards or on Weld modern foil circuit boards.  

Thanks to flexible components, new products such as B. rollable or flexible and foldable Devices for the mobile area are developed that can be worn directly on people. List and short description of the pictures

Fig. 1 Manufacture of a semiconductor tape directly from the cylindrical single crystal with the help of implantation

Fig. 2 Manufacture of a semiconductor tape directly from the cuboid single crystal

Fig. 3 surface treatment

Fig. 4 joining (bonding, welding, gluing) of foils

Fig. 5 assembly line production with both, front and back processes

Fig. 6 part production line with the process sequence, painting, drying, exposure, development, curing

The basic features of the solution for producing a semiconductor tape are shown in FIG. 1. With the help of the implantation of z. B. hydrogen or helium bubbles ( 10 ) can be generated in the semiconductor, which are used to separate a thin surface layer. After the ion implantation, a film ( 1 ) can be mechanically removed from a single crystal. A cylindrical single crystal ( 2 ) of the type used to manufacture wafers, which is ground and polished after the pulling process, has advantages in the production of the semiconductor tape. A disadvantage is that the crystal orientation of the semiconductor band changes with the size of the single crystal. Although the semiconductor tape is single-crystal, the crystal orientation changes in the longitudinal direction. This problem can be avoided with the method shown in FIG. 2. A cuboid single crystal ( 18 ) serves as the starting material. The cuboid is implanted in the longitudinal direction and then the film ( 1 ) is removed. The cuboid is removed layer by layer. The length of the semiconductor tape thus corresponds to the length of the cuboid. In order to obtain a sufficient length for continuous component production, the ends of the semiconductor strips must therefore be bonded together. However, the crystal structure of the first method is sufficient for many large-area applications. If areas with a uniform crystal orientation are necessary for critical components, these can be produced by the bonding process shown in FIG. 4. Different semiconductors can be successfully bonded to one another. One possibility is to bring together semiconductor foils, produced by the separation process described above. If one of the two foils is oxidized, an SOI tape with dielectric separation of the two foils can also be produced. If only small areas with a uniform church orientation are necessary, silicon foils can be separated from conventional silicon wafers and used for bonding onto the semiconductor tape produced by method 1 . Fig. 3 is a possibility shows the surface after the separation process to polish.

The continuous bonding process of two or more semiconductor foil strips by means of pressure rollers according to FIG. 4a has the essential difference compared to conventional bonding processes in that a bond front is formed which runs in the direction of the roll. The bond speed can thus be precisely controlled. It is also possible to use the pressure rollers ( 21 ) to set the pressure during the bonding process. The bond temperature can also be adjusted by regulating the temperature of the pressure rollers and additionally by lamp heaters. The surfaces to be bonded can be optimally conditioned immediately before the bonding process. In summary, this means that the essential bond parameters such as speed, contact pressure, temperature and conditioning of the surface can be set precisely.

The separation process according to FIGS. 1 and 2 creates a new product, the semiconductor tape, which is the prerequisite for the continuous production of components and, in addition, new technological possibilities and processes, which will be described in more detail below. A new process is the continuous bonding process, with which the semiconductor tape can be supplemented by a multilayer structure and optimized for the respective application. Fig. 5 shows schematically different possibilities of the production process of electronic components.

The invention is described in more detail below with the aid of specific examples. The invention includes a product, the semiconductor tape, the manufacturing processes of this product and new production processes made possible by this product.

In order to produce a semiconductor tape ( 1 ) from a cylindrical single crystal ( 2 ), the implantation of a relatively high dose of hydrogen in the range from 1.10 ¹⁶ cm ^-2 to 1.10 ¹⁷ cm ^{-2 is} necessary in order to prevent bubbles ( 10 ) in the silicon ( 2 ) to reach. The formation of bubbles enables the semiconductor film to be pulled off mechanically ( 11 ). This continuous separation process creates a semiconductor tape ( 1 ). For the production of the semiconductor tape, a suitable implantation method is essentially required and a pulling and winding device ( 9 ) with which the semiconductor tape is continuously pulled off the single crystal and wound onto a roll ( 8 ). Ribbon beam, multiband and PIII methods are particularly suitable as the implantation method. These methods have the advantage over conventional ion implantation that they do not require beam scanning and additionally have a high ion current. Fig. 1 shows a single crystal ( 2 ), a multi-band beam implantation system ( 4 ), the stripped semiconductor tape ( 1 ) and the wound semiconductor film roll ( 8 ). The multi-band beam implantation system shown can the starting material to be adapted, see Fig. 1 and Fig. 2. further allows a very high ion current at the same time relatively low local ion current density, targeted areas can irradiate and is simply constructed. A multi-band blasting machine is therefore ideally suited for this application. In principle, however, conventional implantation procedures can also be used.

The essential components of the multi-band jet system are the anode ( 12 ), cathode ( 16 ) and the extraction grid ( 6 ), which are adapted to the sample material. A hydrogen plasma is created by admitting hydrogen into the plasma space delimited by the anode, cathode and side wall ( 15 ) and by applying a high frequency to the cathode grid ( 17 ). With the help of the extraction grid ( 6 ), hydrogen ions are extracted from the plasma and accelerated in the direction of the single crystal as an ion beam ( 7 ). The extraction and acceleration voltage is applied between the cathode and extraction grid. An additional acceleration is possible by applying a second voltage between the extraction grid and the single crystal. The energy and thus the penetration depth of the hydrogen ions in the single crystal are adjusted by means of the extraction and acceleration voltage. The penetration depth determines the depth of the bubble formation and thus the thickness of the semiconductor tape. The cathode and extraction grid is composed of slots and webs. The slit extraction creates a band beam, the number of slits being equal to the number of band beams. The width of the band beam is adapted to the length of the single crystal and thus determines the width of the semiconductor band.

In order to achieve a high throughput or a rapid mechanical pulling of the film strip from the single crystal a powerful implantation system is necessary.  

example

With a stripping speed of one meter per minute, a bandwidth of 1 m (length of the single crystal) and a separation dose of 5.10 ¹⁶ cm ^-2 , an ion current of 1.33 A is required. Conventional implantation systems with such a high ion current strength are difficult to achieve realize. Multi-band beam or pill systems can reach these current strengths relatively easily, but must be optimized for the high energies that are necessary in the production of relatively thick films of 1 µm. However, thin foils of 0.2 µm (sufficient for certain applications) can already be produced with today's systems. For a film thickness of 1 µm, a proton energy of 130 keV is required for a film thickness of 0.2 µm, a proton energy of 20 keV.

The high power input and thus the heating of the single crystal must also be taken into account. In the example mentioned, the power input for the production of a 1 µm semiconductor band is 173 kW and for 0.2 µm 26.6 kW. These high powers require cooling of the single crystal. One possibility is direct water cooling through a hole in the center of the single crystal ( 3 ).

In Fig. 2, the separation method explained in Fig. 1 for a cylindrical single crystal is applied to a cuboid single crystal.

After the separation process, it is usually necessary to improve the surface of the silicon band, since the ion implantation or the separation roughened it. This can be done, for example, by polishing the front ( 35 ) and back ( 36 ) as shown in Fig. 3. In addition, thermal treatment of the semiconductor tape is necessary to heal the crystalline damage caused by the ion implantation. In principle, it is also possible to carry out these process steps directly during the production of the silicon strip, that is to say to add the polishing and annealing in the steps shown in FIG. 1.

The continuous separation process enables a new product, the semiconductor tape. This in turn is the Basis for new semiconductor manufacturing processes, such as B. a semiconductor assembly line production of components and new technological possibilities such as the continuous bonding process that are described below becomes.

In FIG. 4, the continuous bonding process is illustrated. This involves welding semiconductor tapes together by pressing on the surfaces and thermal treatment. After unrolling the film strips ( 1 ), the surfaces to be bonded are preconditioned ( 20 ) directly before bonding. Here, for. B. the surface cleaned of particles and foreign atoms and the surface connections are optimally adjusted to the subsequent bonding process. Using two press rollers ( 21 ), the surfaces to be bonded are pressed together with a defined pressure and thus cold-welded (bonded). A thermal post-treatment ( 22 ) improves the bonding process and any crystal damage is healed. The welded film is then rolled up. With this bonding process, several advantages over the conventional disk bonding processes can be achieved. It enables continuous and bubble-free bonding of tapes. With the help of the two press rollers, a defined and very high pressure can be exerted on the bond surfaces. Furthermore, the bond front moves in a defined direction (rolling direction) with adjustable speed and thus does not allow any major air pockets. The surface can also be conditioned immediately before the bonding process. It can e.g. B. particles are removed and the bond surface is chemically prepared so that a firm bonding process is possible. The further advantages of this bonding method are that a simultaneous bonding of several foils is possible and that several semiconductor foils of different types and thicknesses can be bonded together. So z. B. abrupt doping profiles of any kind, which were previously only possible by expensive epitaxial processes. Novel heterogeneous semiconductors can also be produced by bonding different semiconductor materials. Bringing together semiconductor foils with insulating foils or metal foils to form a multilayer system by means of the continuous bonding process is another possibility to simplify the semiconductor production. This bonding process is very well suited for the production of SOI (Silicon On Insulator). The previously very expensive SOI material can be produced simply and inexpensively by bonding a silicon tape with an oxidized silicon tape or another suitable insulator tape. It can e.g. B. monocrystalline semiconductor, non-conductor, and conductor layers can be brought together in any order, thereby producing materials with new properties and technical possibilities.

By modifying the bonding process as shown in Figure 3b, the single-crystalline semiconductor tape can be bonded to carrier plates ( 25 ) of any type and size. Bonding a semiconductor tape to a carrier plate requires only one pressure roller ( 21 ). The bonding force of the pressure roller acts on the carrier plate, which therefore requires a stable base ( 26 ) that moves linearly in the rolling direction. The bonding process takes place in the same way as in FIG. 3a and with the same advantages.

The thickness of the semiconductor tape and thus of the finished components can be adjusted by 3 processes.

• 1. With the help of ion energy z. B. of hydrogen. The ion energy determines the depth of the bubbles and thus the layer thickness of the separated film. For technical and practical reasons, Im plantation energies far above 130 keV do not make sense. This means that the separated layer one Thickness of 1 micron will not significantly exceed.
• 2. By bonding several semiconductor tapes together, the thickness can be increased as desired. The flexibility of the resulting semiconductor tape ( 24 ) represents a limit. If the thickness rises above a certain dimension, small roll radii ( 23 ) can no longer be realized due to material stresses, which in turn makes handling more difficult. The technically reasonable limit should therefore be around 100 µm.
• 3. By epitaxy. Here, silicon is deposited in a controlled manner from the gas phase, so that a crystalline layer growing on the silicon tape. With this method, the thickness of the Semiconductor foil tape also set in wide areas.

The specified limit of 100 µm for methods 2 and 3 is only applicable if the resulting semiconductor tape is further processed in the rolling process, since certain demands are placed on flexibility. However, further processing in panels is also interesting. The desired thickness is set by methods 2 and 3 . The resulting semiconductor tape is then sawn into plates. In this way, plates can be produced which have a much larger area than the disk material sawn from the single crystal. The current state of the art in silicon is disks with a diameter of 300 mm. With the described methods, panels with a side length of several meters are possible, the surface shape being arbitrary. The easiest way to saw squares and rectangles from a semiconductor band. The width of the band defines the maximum side length of a square plate or the width of a rectangular plate (the length is not limited). This means that single-crystal semiconductor plates with an area of several square meters can be produced. An ideal application for such panels is the solar cell.

In addition to the continuous bonding process, the semiconductor tape opens up further interesting production options. In this way, processes that can be coordinated with one another in a production line production, as shown schematically in FIG. 5, can be processed most economically and quickly. Since the assembly line or semiconductor belt itself is processed, the mechanically moving parts are minimal. Fig. 5 shows the principle le procedure. First the tape is unrolled ( 8 ) and then the processes follow. In addition to the economy of this production process, another advantage is the processability on both sides. The semiconductor tape can be processed on both sides simultaneously ( 27 ), on the front side ( 28 ) and on the back side ( 29 ).

In semiconductor technology, a frequently repeated sequence of processes is the masking or Structuring of silicon wafers and subsequent processing. For this, the individual silicon cover with a photosensitive varnish, which is spun on. Then the Lacquer exposed and developed and prepared for the subsequent process, in which it accordingly is heated. The following processes are e.g. B. etching layer, doping z. B. by means of ion implantation on and depositing layers. Then the paint is removed and the silicon wafer if necessary healed or treated by other process steps. If this sequence of processes is run through it follows in usually the next mask. The complexity of a semiconductor manufacturing process depends on the number the masking (paint application and structuring). In microelectronics, the number is Masking mostly over 10 and the number of individual processes mostly over 100.

The process sequence described for applying the varnish and structuring can be processed using the assembly line process. Such a partial production line of the frequently repeating sequence of processes is shown in FIG. 6. After the film roll ( 8 ) has been unwound, a photosensitive lacquer is sprayed on as a liquid ( 30 ), dried ( 31 ), exposed ( 32 ), developed ( 33 ) and heated ( 34 ).

In principle, the semiconductor tape can also be used in a production line immediately after separation from the single crystal be processed further without having to wrap a film roll. A production line is conceivable which starts with the production of the semiconductor tape up to the assembly of the finished component. For this however, all semiconductor manufacturing processes would have to be time-coordinated. This and reliability aspects  individual processes leave a complete production line only for very simple ones Components with a few process steps appear to make sense (e.g. solar cell). Are more practical and flexible Part production lines in which well coordinated processes are grouped together.

In addition to the faster production process, assembly line production also has process engineering advantages. The manufacturing variation shown in Fig. 6 can be simplified by new process steps or improved. So spraying and drying the paint z. B. be replaced by the application of a photosensitive lacquer film by means of continuous tape process. It is also conceivable that certain printing processes will be taken over by the printing industry. Structuring or masking using pressure rotation processes is possible, especially for large structures, such as power electronics, sensors and solar cells.

Additional degrees of freedom in the circuit design enables the processing of the semiconductor foil strip on both sides, as shown in FIG. 5. The front and back are equally processable with direct access to the active areas of the components even in very small or thin areas in the micrometer and submicron range. Conventional semiconductor technology is based on the processing of the front. In microelectronics, the processing of the back is limited to the production of a back contact. It is not possible to process active areas or a wiring level on the back, since the actual component is only up to a few micrometers thick, but the silicon wafer itself has a few hundred micrometers. Silicon wafers with a diameter of 200 mm have a thickness of approx. 700 µm. This precludes access to the active area and thus processing from the rear of the pane. In power electronics, the components are larger and the active areas wider and thicker. High-voltage components partially use the entire pane thickness, here one can speak of a limited two-sided processing. However, these are individual building elements. An equivalent coating of the front and back with double-sided structuring, simultaneous coating and double-sided wiring level with integrated circuits was previously not possible in semiconductor technology. This is only possible if the thickness of the semiconductor approximately corresponds to the thickness of the active area of a component. Semiconductor foil tapes can be produced with a thickness of less than 0.1 µm and can have a thickness of up to over 100 µm. It can cover over 90% of all component thicknesses, from high and highly integrated circuits to power components. A semiconductor tape that can be processed on both sides enables a number of new and more powerful components due to the higher degrees of freedom in the circuit design, a higher integration density, an adaptation of the film thickness to the thickness of the component and better accessibility to the active areas.

Examples are flexible components (chips with integrated circuits), solar cells with higher efficiency, Volume inversion thin film transistors, low volume resistivity power devices. Furthermore, three-dimensional circuits can be realized by superimposing components. Foil components can also be rolled up directly onto a flexible printed circuit board or the function of a Take over circuit board and thus flexible devices such. B. for mobile electronics. electronic  Devices that adapt to people in their usability, application and shape and as A piece of clothing that can be worn or integrated into clothing represents a technical revolution great application potential.

Claims (22)

1. Directly processable semiconductor film suitable for assembly line production processes of semiconductor components, characterized in that
that the film is in the form of a tape;
that it is produced as a semiconductor band directly from the semiconductor starting material (in single-crystal or ingot in semiconductor technology) without the need for semiconductor wafer production:
that the semiconductor tape is mechanically removed directly after the ion implantation. The necessary process steps are ion implantation of elements such. B. hydrogen for bubble formation in the semiconductor at a defined depth and separating the upper layer by mechanically pulling the tape.
Semiconductor tape, characterized in that the manufacturing process is carried out continuously in a pulling device and the tape is wound into a roll, which is suitable for continuous assembly line production processes of electronic components.
Characterized in
that the direct production of electronic components on a semiconductor tape without carrier material is possible,
that enables new production processes for the production of multilayer structures,
that new production processes for the production of electronic components are possible and
that enables new flexible components with better electrical and mechanical properties. 2. Semiconductor tape according to claim 1, characterized in that the ion implantation is carried out continuously in the inline process (assembly line process). The Implantation system (inline implanter) does not require mechanically complex batch or serial End station and complicated disc handling process by robots. 3. Device according to claim 2, characterized in that the plasma ( 5 ) for generating the ions is adapted to the single crystal or the sample in length and topography, that the ion implantation process takes place in a continuous assembly line process. 4. A method for producing the product in claim 1, characterized in that the semiconductor tape is pulled off continuously and mechanically 5. A method for using the product in claim 1, characterized in that bonding by pressing or rolling semiconductor tapes together or semiconductor tapes and plates is made possible. 6. Bonding method according to claim 5, characterized by a bubble-free continuous bonding process of foils in which the following bonding parameters can be set:

• - Contact pressure, by rolling the tapes together, a defined and very high pressure can be exerted on the bonding surfaces.
• - Bond front, defined in one direction progressive bond front with adjustable bond speed
• - bond temperature
• - Surface quality of the surfaces to be bonded. The surface can be treated immediately before the bonding process.

7. The method according to claim 5 and 6, characterized in that simultaneous bonding of several foils is possible. 8. The method according to claim 5-7, characterized in that several semiconductor foils of different types and thicknesses are bonded together at the same time can. 9. The method according to one or more of claims 5-8, characterized in that process films such. B. semiconductor, metal, and plastic films brought together by the method shown in Fig. 4 without bubbles and thereby materials with new properties and technical possibilities can be produced. 10. The method according to one or more of claims 5-9, characterized in that semiconductor tapes with or without a multilayer structure on suitable carrier plates of any kind and size can be bonded. 11. The method according to claim 10, characterized in that the bonding of partially or fully processed foils on carrier plates is made possible. Thereby Carrier plates no longer have to withstand high process temperatures. Instead of glass, quartz glass or Ceramic can e.g. B. plastic can be used as a carrier. 12. The semiconductor tape according to claim 1, characterized in that the thickness of the semiconductor tape is set by bonding multiple tapes or by epitaxial processes can be put. 13. The semiconductor tape as claimed in one or more of claims 1, 4-9, 11, 12, that plates by sawing or cutting (e.g. with a laser) the semiconductor tape, after setting the desired thickness, can be produced. 14. The method for producing single-crystal semiconductor plates according to claim 13, characterized that the plates can be produced in almost any shape (square, rectangular, round) and size. Due to the limited width of the semiconductor tape, a maximum of 1 m-2 m is technically expedient Panels limited in width to this dimension. 15. assembly line production method of semiconductor components by means of a semiconductor tape according to claim 1 in which the tape is processed itself. 16. The method according to one or more of claims 1, 4-9 and 12, that the semiconductor tape can be processed on both sides with direct access to the active areas of the Components, even in very small or thin areas in the micrometer and submicron range. 17. The semiconductor tape as claimed in claim 1, 4-9, 12, 15 and 16, that the production of foil components allows with any lateral dimensions and exactly adjustable thickness without the need for a thinning process.   18. Foil components according to claim 17, characterized in that novel components with better electrical properties can be manufactured. 19. Foil components according to claim 17, characterized in that the superimposition of components to three-dimensional circuits enables. 20. Foil components according to claim 17, characterized in that the flexible components directly on carriers of different shape, flexibility and topography can be applied. 21. Foil component according to claim 17, characterized in that the component itself in addition to the usual functions of electronic components such as Memory, processor, logic, etc. additionally as a flexible printed circuit board with appropriate wiring level and can be equipped with other components. 22. Foil component with circuit board function according to claim 21, characterized in that the front-end area, the back-end area of component manufacturing and the circuit boards Manufacturing is summarized and carried out with partly the same procedures and thus essential is simplified.