Abstract: A thin-film magnetic head has a semiconductor substrate in which there is an integrated circuit, and on which a magnetic layer structure is arranged. During manufacturing the integrated circuit is formed on one side of the semiconductor substrate, and that side of the semiconductor substrate is then secured to a carrier body by a securing layer. The substrate may then be ground or etched to a thickness less than 35&mgr;m before forming the magnetic layer structure on the opposite side. Securing to the carrier body prevents deformation of the layer structure during manufacturing, so that the resulting head has reproducible properties. Preferably a support body is secured over the layer structure. The head face is then formed such that the layer structure and the support and carrier bodies terminate in it.

Abstract: A trench-gate semiconductor device, for example a MOSFET or IGBT, of compact geometry is manufactured with self-aligned masking techniques in a simple process with good reproducibility. The source region (13) of the device is formed by introducing dopant (63) into an area of the body region (15) via a mask window (51a), diffusing the dopant to form a surface region (13b) that extends laterally below the mask (51) at a distance (d) beyond the masking edge (51b) of the window (51a), and then etching the body (10) at the window (51a) to form a trench (20) for the trench-gate (11) with a lateral extent (y) that is determined by the etching of the body (10) at the masking edge (51b) of the window (51a). A portion of the surface region (13b) is left to provide the source region (13) adjacent to the trench (20).

Abstract: In the manufacture of semiconductor devices that have an electrode (11,41) in an insulated trench (20), for example a trench-gate MOSFET, process steps are performed to line the trench walls with a lower insulating layer (21) in a lower part of the trench and with a thicker upper insulating layer (22) in an upper part of the trench.

Abstract: In the manufacture of semiconductor devices that have an electrode (11,41) in an insulated trench (20), for example a trench-gate MOSFET, process steps are performed to line the trench walls with a lower insulating layer (21) in a lower part of the trench and with a thicker upper insulating layer (22) in an upper part of the trench.

Abstract: A thin film semiconductor device includes a glass supporting body having thereon an insulating substrate which is attached thereto by a layer of adhesive material. On the surface of the substrate facing the supporting body is a layer of semiconductor material which includes therein a semiconductor element, such surface further having thereon a metalization pattern of conductor tracks. An insulating layer is additionally provided between the metalization pattern and the adhesive layer, and has a dielectric constant &egr;r below 3 and a thickness in the range of approximately 20 &mgr;m to 60 &mgr;m. By virtue of such additional layer, parasitic capacitanees between the metalization pattern and an envelope in which the device is included or a printed circuit board on which the device is mounted are reduced substantially, thereby reducing the power consumption of the device.

Abstract: A method of manufacturing enveloped semiconductor devices, in which use is made of a slice of a semiconductor material which is provided on its first side with an intermediate layer of an insulating material on which a top layer of a semiconductor material is formed, semiconductor elements are formed in the top layer, paths of the slice's surface situated on this side being left clear between the semiconductor elements, and the top layer is removed from the insulating intermediate layer at the location of the free paths. A metallization with connection electrodes extending as far as the free paths are formed on the first side of the slice, the slice is glued with its first side onto a transparent insulating supporting body, semiconductor material is removed from the second side of the slice facing away from the first side, and the slice thus reduced in thickness is provided on its second side with a layer of an insulating material.

Abstract: The invention relates to a radiation-sensitive device comprising a thin radiation-sensitive element (2), in particular a thin photodiode (2). The device includes a substrate (1) on which a photodiode (2) is provided. The surface (5) of the photodiode serves as a semi-pervious mirror (5) through which the radiation (100) enters; a reflecting layer (6) situated between the photodiode (2) and the substrate (1) also serves as a mirror (6). As a result, a so-called resonant cavity effect is possible, resulting, inter alia, in wavelength selectivity of the device. The known device has insufficient wavelength selectivity, which, in addition, cannot readily be set in an accurate and reproducible manner. A device in accordance with the invention is characterized in that the reflecting layer (6) is a metal layer (6) and in that the photodiode (2) is secured to the substrate (1) by means of an adhesive layer (7).

Abstract: A method of manufacturing a semiconductor device which starts with a semiconductor wafer (1) which is provided with a layer of semiconductor material (4) lying on an insulating layer (3) at a first side (2). Semiconductor elements (5) and conductor tracks (14) are formed on this first side (2) of the semiconductor wafer (1). Then the semiconductor wafer (1) is fastened with this first side (2) to a support wafer (15), and material (18) is removed from the semiconductor wafer (1) from its other, second side (17) until the insulating layer (3) has been exposed. The method starts with a semiconductor wafer (1) whose insulating layer (3) is an insulating as well as a passivating layer. The semiconductor device must be provided with a usual passivating layer after its manufacture in order to protect it against moisture and other influences. In the method described here, such a passivating layer is present already before the manufacture of the semiconductor device starts.

Abstract: A semiconductor device comprises a substrate (1) with a plane surface (4) on which a layer structure (2) is formed in a number of layers (5, 7, 9, 13, 15, 17). The side of the substrate on which the layer structure was formed is fastened to a plane support body (18) by means of a glue layer (19) which encompasses spacer elements (20). These spacer elements are fastened to the surface of the substrate and all have the same height measured from the surface (4). In fastening the substrate to the support body, glue is provided and the substrate is pressed onto the support body so that the pressure is evenly distributed over the spacer elements.

Abstract: A method of manufacturing a semiconductor device which starts with a semiconductor wafer which is provided with a layer of semiconductor material lying on an insulating layer at a first side. Semiconductor elements and conductor tracks are formed on this first side of the semiconductor wafer. Then the semiconductor wafer is fastened with this first side to a support wafer, and material is removed from the semiconductor wafer from its other, second side until the insulating layer has been exposed. The method starts with a semiconductor wafer whose insulating layer is an insulating as well as a passivating layer. The semiconductor device must be provided with a usual passivating layer after its manufacture in order to protect it against moisture and other influences. In the method described here, such a passivating layer is present already before the manufacture of the semiconductor device starts.

Abstract: A method of manufacturing a device whereby a layer structure with semiconductor elements and conductor tracks is formed on a first side of a semiconductor wafer which is provided with a layer of semiconductor material disposed on an insulating layer. Then the semiconductor wafer is fastened with said first side to a support wafer by means of a glue layer, the support wafer being provided with a metallization. Material is then removed from the semiconductor wafer from the other, second side thereof until the insulating layer is exposed. Contact windows are provided in the insulating layer from the first side of the semiconductor wafer before the latter is refastened on the support wafer. These windows are filled with a material which can be removed selectively relative to the insulating layer. The contact windows are opened from the second side of the semiconductor wafer after the latter has been fastened on the support wafer and after the insulating layer has been exposed.

Abstract: The invention relates to a method of manufacturing a semiconductor device (1) for surface mounting. Such a method is known, whereby such a semiconductor device is manufactured in that a semiconductor body with a semiconductor element is mounted on a metal lead frame with metal package leads, after which contact surfaces of the semiconductor element are connected to the package leads by means of bonding wires. It is found that semiconductor devices of small dimensions are difficult to realize by this known method, while in addition the manufacture of integrated circuits with very many package leads is comparatively expensive owing to the many connections which are to be made between the integrated circuits and the package leads. According to the invention, the semiconductor devices are packaged while they are still on a slice of semiconductor material, while the package leads are formed from the semiconductor material.

Abstract: A semiconductor device with a carrier body on which a substrate is fastened by means of a glue layer, which substrate is provided at its first side facing the carrier body with a semiconductor element and with a pattern of conductor tracks comprising contact electrodes for external contacting from the second side of the substrate facing away from the carrier body. The substrate is provided with windows at the areas of the contact electrodes for external contacting from the second side. The process steps preceding the gluing of the substrate to the carrier body are carried out in a clean room suitable for the manufacture of semiconductor elements, whereas the remaining process steps are preferably carried out in a final mounting room. Expensive lithographical equipment need not be available in both rooms, because the comparatively large windows can be formed by means of a simple contact mask.

Abstract: A method of manufacturing a semiconductor device with a substrate (1) provided with a passive element (2), a pattern of conductors (3, 4), and a semiconductor element (5) which is formed in a small slice (6) of semiconductor material. The passive element (2), the pattern of conductors (3, 4), and the semiconductor element (5) are formed at a first side (8) of a wafer of semiconductor material (7), whereupon this wafer is glued with its first side (8) to the substrate (1), and the semiconductor material of the wafer (7) is removed from the second side (22) thereof, except at the area of the semiconductor element (5). A small slice (6) of semiconductor material thus remains in which the semiconductor element (5) has been formed. The wiring may be realized in a simple manner without the introduction of additional and expensive process steps, while the introduction of parasitic capacitances and self-inductances is counteracted.

Abstract: A semiconductor device for microwave frequencies with a substrate which is provided at a first side with a semiconductor element, a passive element, and a pattern of conductive elements, while the opposed, second side is provided with a metallization which is connected to the elements present on the first side through windows formed in the substrate. The substrate consists of a silicon layer which is present on a layer of insulating material, the semiconductor element being formed in the silicon layer, and the metallization being provided on that side of the layer of insulating material which is remote from the silicon layer. The silicon layer may here have a very small thickness of, for example, 0.1 to 0.2 .mu.m. In such a thin silicon layer, bipolar and field effect transistors capable of processing signals of microwave frequencies can be formed. Since the silicon layer is thin, the influence of the conductivity of silicon on passive elements is small.

Abstract: A semiconductor device with a bipolar transistor formed in a layer of semiconductor material (2) provided on an insulating substrate (1), in which material a collector zone (4), a base zone (5), and an emitter zone (6) are provided below a strip of insulating material (3) situated on the layer (2), which zones are connected to contact regions (7, 8, 9, 10) lying adjacent the strip (3), three of the contact regions (8, 9, 10) lying next to one another at a same side of the strip (3), of which two (8 and 9) are connected to the base zone (5) while the third (10), which lies between the former two (8 and 9), is connected to the emitter zone (6). The three contact regions (8, 9, 10) situated next to another at the same side of the strip (3) are provided alternately in the layer of semiconductor material (2) and in a further layer of semiconductor material (19) extending up to the strip (3).

Abstract: A semiconductor device includes a semiconductor body (1) having a semiconductor element with connection points (2, 3) which adjoins a surface (4) of the semiconductor body (1) and is laterally insulated and surrounded by a first depression (5) in the surface (4), which depression (5) is provided with a wall (6) and a bottom (7), while the surface (4) of the semiconductor body (1) and the wall (6) and bottom (7) of the depression (5) are covered with an insulating layer (8). The connection points (2, 3) are provided in the insulating layer (8) on the surface (4) of the semiconductor body (1) and are connected to conductor tracks (10, 11) which connect the connection points (2, 3) across a wall (6) to connection surfaces (12, 13) associated with the connection points (2, 3) and situated on the bottom (7). It is found in practice that, in the case of progressive miniaturization, the manufacture of such devices leads to rejects caused by short-circuits between connection surfaces (12, 13).

Abstract: Method of manufacturing a thin-film magnetic head in which a main layer (5) of a non-magnetic material is formed on a support, which layer is recessed by removing material from a side remote from the support, said recess being subsequently filled up with a soft-magnetic material for forming a flux guide (17a, 17b), whereafter the main layer provided with the filled recess is mechanochemically polished for forming a main surface (19) at which subsequently a layer of a magnetoresistive material is provided for forming a magnetoresistive element (23).

Abstract: A method is provided of manufacturing a semiconductor device whereby semiconductor elements (5) and conductor tracks (14) are formed on a first side (2) of a semiconductor slice (1) which is provided with a layer of semiconductor material (4) disposed on an insulating layer (3). Then the semiconductor slice (1) is fastened with said first side (2) to a support slice (15), after which material is removed from the semiconductor slice (1) from the other, second side (17) until the insulating layer (3) has become exposed. The insulating layer (3) is provided with contact windows (18) in which conductive elements (19) are provided. This is done from the first side (2) of the semiconductor slice (1) before the latter is fastened to the support slice (15). The semiconductor elements (5) are externally contacted with a contact wire (20) via the conductive elements (19).

Abstract: A method of manufacturing a semiconductor device with a semiconductor element which includes a semiconductor zone (19) situated below an electrode (18) and adjoining a surface (5) of a semiconductor body (1), which semiconductor zone substantially does not project outside the electrode (18) in lateral direction. The electrode (18) is here formed on the surface (5) of the semiconductor body (1), after which semiconductor material adjoining the surface (5) and not covered by the electrode (18) is removed by an etching treatment, whereby the position of the semiconductor zone (19) below the electrode (18) is defined.