Abstract: A current sensor comprises a current conductor having a first portion, a measuring portion and a second portion, the first portion including one or more first electrical terminals and the second portion including one or more second electrical terminals. The current sensor further comprises third electrical terminals and a semiconductor chip. The semiconductor chip has one or more magnetic field sensors disposed in the active surface, is mounted on the current conductor with an active surface facing the current conductor. The active surface comprises first contacts. The semiconductor chip comprises electrical through silicon connections disposed over and electrically connected to the first contacts. A backside of the semiconductor chip comprises second contacts, each of the second contacts electrically connected to one of the electrical through silicon connections. Wire bonds electrically connect the second contacts with the third electrical terminals.

Abstract: A current sensor comprises a current conductor having a first portion, a measuring portion and a second portion, the first portion including one or more first electrical terminals and the second portion including one or more second electrical terminals. The current sensor further comprises third electrical terminals and a semiconductor chip. The semiconductor chip has one or more magnetic field sensors disposed in the active surface, is mounted on the current conductor with an active surface facing the current conductor. The active surface comprises first contacts. The semiconductor chip comprises electrical through silicon connections disposed over and electrically connected to the first contacts. A backside of the semiconductor chip comprises second contacts, each of the second contacts electrically connected to one of the electrical through silicon connections. Wire bonds electrically connect the second contacts with the third electrical terminals.

Abstract: Described herein is a method for forming a vertical memory device (150) having a vertical channel region (113) sandwiched between a source region (109, 112) and a drain region (114). A charge trapping layer (106) is provided either side of the vertical channel region (113) and associated source and drain regions (109, 112, 114). The source region (109, 112) comprises a junction between a first region (109) comprising a first doping type with a first doping concentration and a second region (112) comprising a second doping type which is opposite to the first doping type and with a second doping concentration. The drain region (114) comprises the first doping type with a first doping concentration. In another embodiment, the drain region has two regions of differing doping types and concentrations and the source region comprises the first doping type with the first doping concentration.

Abstract: Disclosed are methods for forming a localized buried dielectric layer under a fin for use in a semiconductor device. In some embodiments, the method may include providing a substrate comprising a bulk semiconductor material and forming at least two trenches in the substrate, thereby forming at least one fin. The method further includes filling the trenches with an insulating material and partially removing the insulating material to form an insulating region at the bottom of each of the trenches. The method further includes depositing a liner at least on the sidewalls of the trenches, removing a layer from a top of each of the insulating regions to thereby form a window opening at the bottom region of the fin, and transforming the bulk semiconductor material of the bottom region of the fin via the window opening, thereby forming a localized buried dielectric layer in the bottom region of the fin.

Abstract: Disclosed are methods for forming a localized buried dielectric layer under a fin for use in a semiconductor device. In some embodiments, the method may include providing a substrate comprising a bulk semiconductor material and forming at least two trenches in the substrate, thereby forming at least one fin. The method further includes filling the trenches with an insulating material and partially removing the insulating material to form an insulating region at the bottom of each of the trenches. The method further includes depositing a liner at least on the sidewalls of the trenches, removing a layer from a top of each of the insulating regions to thereby form a window opening at the bottom region of the fin, and transforming the bulk semiconductor material of the bottom region of the fin via the window opening, thereby forming a localized buried dielectric layer in the bottom region of the fin.

Abstract: Disclosed are methods for manufacturing a floating gate memory device and the floating gate memory device thus obtained. In one embodiment, a method is disclosed that includes providing a semiconductor-on-insulator substrate, forming at least two trenches in the semiconductor-on-insulator substrate, and, as a result of forming the at least two trenches, forming at least one elevated structure. The method further includes forming isolation regions at a bottom of the at least two trenches by partially filling the at least two trenches, thermally oxidizing sidewall surfaces of at least a top portion of the at least one elevated structure, thereby providing a gate dielectric layer on at least the exposed sidewall surfaces; and forming a conductive layer over the at least one elevated structure, the gate dielectric layer, and the isolation regions to form at least one floating gate semiconductor memory device.

Abstract: Described herein is a method for forming a vertical memory device (150) having a vertical channel region (113) sandwiched between a source region (109, 112) and a drain region (114). A charge trapping layer (106) is provided either side of the vertical channel region (113) and associated source and drain regions (109, 112, 114). The source region (109, 112) comprises a junction between a first region (109) comprising a first doping type with a first doping concentration and a second region (112) comprising a second doping type which is opposite to the first doping type and with a second doping concentration. The drain region (114) comprises the first doping type with a first doping concentration. In another embodiment, the drain region has two regions of differing doping types and concentrations and the source region comprises the first doping type with the first doping concentration.

Abstract: Disclosed are methods for manufacturing a floating gate memory device and the floating gate memory device thus obtained. In one embodiment, a method is disclosed that includes providing a semiconductor-on-insulator substrate, forming at least two trenches in the semiconductor-on-insulator substrate, and, as a result of forming the at least two trenches, forming at least one elevated structure. The method further includes forming isolation regions at a bottom of the at least two trenches by partially filling the at least two trenches, thermally oxidizing sidewall surfaces of at least a top portion of the at least one elevated structure, thereby providing a gate dielectric layer on at least the exposed sidewall surfaces; and forming a conductive layer over the at least one elevated structure, the gate dielectric layer, and the isolation regions to form at least one floating gate semiconductor memory device.