Abstract: The present disclosure generally relates to dopant profile control in a heterojunction bipolar transistor (HBT). In an example, a semiconductor device structure includes a semiconductor substrate and an HBT. The HBT includes a collector region, a base region, and an emitter region. The base region is disposed on or over the collector region. The emitter region is disposed on or over the base region. The base region is disposed on or over the semiconductor substrate and includes a heteroepitaxial sub-layer. The heteroepitaxial sub-layer is doped with a dopant. A concentration gradient of the dopant increases from a region in a layer adjoining and overlying the heteroepitaxial sub-layer to a peak concentration in the heteroepitaxial sub-layer without decreasing between the region and the peak concentration.

Abstract: A semiconductor device include a first semiconductor layer with a first doping concentration. A second semiconductor layer has a second doping concentration and has a first surface and a second opposing surface. The second doping concentration is higher than the first doping concentration. The first surface of the second semiconductor layer is in contact with the first semiconductor layer. A contact is on the second surface of the second semiconductor layer. The contact includes a metal and a semiconductor.

Abstract: A SiGe heterojunction bipolar transistor is fabricated by etching an epitaxially-formed structure to form a mesa that has a collector region, a cap region, and a notched SiGe base region that lies in between. A protective plug is formed in the notch of the SiGe base region so that thick non-conductive regions can be formed on the sides of the collector region and the cap region. Once the non-conductive regions have been formed, the protective plug is removed. An extrinsic base is then formed to lie in the notch and touch the base region, followed by the formation of isolation regions and an emitter region.

Abstract: The invention relates to a semiconductor device (10) with a substrate (11) and a semiconductor body (1) comprising a bipolar transistor with in that order a collector region (2), a base region (3), and an emitter region (4), wherein the semiconductor body comprises a projecting mesa (5) comprising at least a portion of the collector region (2) and the base region (3), which mesa is surrounded by an isolation region (6). According to the invention, the semiconductor device (10) also comprises a field effect transistor with a source region, a drain region, an interposed channel region, a superimposed gate dielectric (7), and a gate region (8), which gate region (8) forms a highest part of the field effect transistor, and the height of the mesa (5) is greater than the height of the gate region (8). This device can be manufactured inexpensively and easily by a method according to the invention, and the bipolar transistor can have excellent high-frequency characteristics.

Abstract: A SiGe heterojunction bipolar transistor is fabricated by etching an epitaxially-formed structure to form a mesa that has a collector region, a cap region, and a notched SiGe base region that lies in between. A protective plug is formed in the notch of the SiGe base region so that thick non-conductive regions can be formed on the sides of the collector region and the cap region. Once the non-conductive regions have been formed, the protective plug is removed. An extrinsic base is then formed to lie in the notch and touch the base region, followed by the formation of isolation regions and an emitter region.

Abstract: A BiCMOS substrate includes a bipolar area having a buried carrier layer, and a deep trench isolation (DTI) trench extending into the buried carrier layer to form a surface well implant above a buried well implant within the DTI trench, the buried well implant being the buried carrier layer portion within the DTI trench. A floating gate is disposed on the carrier well. Optionally, a high voltage control gate is formed of a stack of the buried well implant and the surface well implant within the DTI trench. Optionally, a poly layer formed of a bipolar process base poly layer is disposed on the floating gate. Optionally, a shallow well isolation region is formed on the substrate, a floating gate is disposed on the shallow well region, and an overlaying control gate, formed of a bipolar process base poly, is disposed above the floating gate.

Abstract: The illumination system has a light source (1) with a plurality of light emitters (R, G, B). The light emitters comprise at least a first light-emitting diode of a first primary color and at least a second light-emitting diode of a second primary color, the first and the second primary colors being distinct from each other. The illumination system has a facetted light-collimator (2) for collimating light emitted by the light emitters. The facetted lightcollimator is arranged along a longitudinal axis (25) of the illumination system. Light propagation in the facetted light-collimator is based on total internal reflection or on reflection at a reflective coating provided on the facets of the facetted light-collimator. The facetted light-collimator merges into a facetted light-reflector (3) at a side facing away from the light source. The illumination system further comprises a light-shaping diffuser (17). The illumination system emits light with a uniform spatial and spatio-angular color distribution.

Abstract: A BiCMOS substrate includes a bipolar area having a buried carrier layer, and a deep trench isolation (DTI) trench extending into the buried carrier layer to form a surface well implant above a buried well implant within the DTI trench, the buried well implant being the buried carrier layer portion within the DTI trench. A floating gate is disposed on the carrier well. Optionally, a high voltage control gate is formed of a stack of the buried well implant and the surface well implant within the DTI trench. Optionally, a poly layer formed of a bipolar process base poly layer is disposed on the floating gate. Optionally, a shallow well isolation region is formed on the substrate, a floating gate is disposed on the shallow well region, and an overlaying control gate, formed of a bipolar process base poly, is disposed above the floating gate.

Abstract: The illumination system has a light source (1) with a plurality of light emitters (R, G, B). The light emitters comprise at least a first light-emitting diode of a first primary color and at least a second light-emitting diode of a second primary color, the first and the second primary colors being distinct from each other. The illumination system has a facetted light-collimator (2) for collimating light emitted by the light emitters. The facetted lightcollimator is arranged along a longitudinal axis (25) of the illumination system. Light propagation in the facetted light-collimator is based on total internal reflection or on reflection at a reflective coating provided on the facets of the facetted light-collimator. The facetted light-collimator merges into a facetted light-reflector (3) at a side facing away from the light source. The illumination system further comprises a light-shaping diffuser (17). The illumination system emits light with a uniform spatial and spatio-angular color distribution.

Abstract: A BiCMOS-compatible JFET device comprising source and drain regions (17, 18) which are formed in the same process as that used to form the emitter out-diffusion or a vertical bipolar device, wherein the semiconductor layer which forms the emitter cap in the bipolar device forms the channel (16) of the JFET device and the layer of material (i.e. the base epi-stack) which forms the intrinsic base region of the bipolar device forms the intrinsic gate region (14) of the JFET device. As a result, the integration of the JFET device into a standard BiCMOS process can be achieved without the need for any additional masking or other processing steps.

Abstract: The invention relates to a method of manufacturing a semiconductor device comprising a substrate (1) and a semiconductor body (2) in which at least one semiconductor element is formed, wherein, in the semiconductor body (2), a semiconductor island (3) is formed by forming a first cavity (4) in the surface of the semiconductor body (2), the walls of said first cavity being covered with a first dielectric layer (6), after which, by means of underetching through the bottom of the cavity (4), a lateral part of the semiconductor body (2) is removed, thereby forming a cavity (20) in the semiconductor body (2) above which the semiconductor island (3) is formed, and wherein a second cavity (5) is formed in the surface of the semiconductor body (2), the walls of said second cavity being covered with a second dielectric layer, and one of the walls covered with said second dielectric layer forming a side wall of the semiconductor island (3).

Abstract: The present invention provides a semiconductor device comprising a plurality of layers, the semiconductor device comprising:—a substrate having a first major surface,—an inductive element fabricated on the first major surface of the substrate, the inductive element comprising at least one conductive line, and—a plurality of tilling structures in at least one layer, wherein the plurality of tilling structures are electrically connected together and are arranged in a geometrical pattern so as to substantially inhibit an inducement of an image current in the tilling structures by a current in the inductive element. It is an advantage of the above semiconductor device that, by using such tilling structures, an inductive element with improved quality factor is obtained. The present invention also provides a method for providing an inductive element in a semiconductor device comprising a plurality of layers.

Abstract: The electronic device comprises a substrate (1) with a cavity (6) in which an active device (8) is present. On the first side (2) of the substrate an interconnect structure (17) extends over the cavity and the substrate. On the second side (3) of the substrate to which the cavity extends, a heat sink (23) is available. The device is particularly suitable for use at high frequencies, for instance higher than 2 GHz and under conditions of high dissipation.