Abstract: The thinning of a semiconductor substrate of an integrated circuit from a back face is detected using the measurement of a physical quantity representative of the resistance between the ends of two electrically-conducting contacts situated at an interface between an insulating region and an underlying substrate region. The two electrically-conducting contacts extend through the insulating region to reach the underlying substrate region.

Abstract: An integrated circuit includes an interconnection part with a via level situated between a lower metallization level and an upper metallization level. The lower metallization level is covered by an insulating encapsulation layer and an inter-metallization level insulating layer. An electrical discontinuity is provided between a via of the via level and a metal track of the lower metallization level. The electrical discontinuity is formed by an additional insulating layer having a material composition identical to that of the inter-metallization level insulating layer. The electrical discontinuity is situated between a bottom of the via and a top of the metal track, with the discontinuity being bordered by the insulating encapsulation layer.

Abstract: An integrated circuit includes a semiconductor substrate and a multitude of electrically conductive pads situated between component zones of the semiconductor substrate and a first metallization level of the integrated circuit, respectively. The multitude of electrically conductive pads are encapsulated in an insulating region and include: first pads, in electrical contact with corresponding first component zones, and at least one second pad, not in electrical contact with a corresponding second component zone.

Abstract: An integrated circuit includes an interconnection part with a via level situated between a lower metallization level and an upper metallization level. The lower metallization level is covered by an insulating encapsulation layer. An electrical discontinuity between a first via of the via level and a first metal track of the lower metallization level is provided at the level of the insulating encapsulation layer. The electrical discontinuity is formed prior to formation of any via of the via level and prior to any metal track of the upper metallization level. The electrical discontinuity may comprise: a portion of an additional insulating layer extending over the insulating encapsulation layer; a portion of the insulating encapsulation layer; or an insulating oxide on a top surface of the first metal track.

Abstract: An integrated MOS transistor is formed in a substrate. The transistor includes a gate region buried in a trench of the substrate. The gate region is surrounded by a dielectric region covering internal walls of the trench. A source region and drain region are situated in the substrate on opposite sides of the trench. The dielectric region includes an upper dielectric zone situated at least partially between an upper part of the gate region and the source and drain regions. The dielectric region further includes a lower dielectric zone that is less thick than the upper dielectric zone and is situated between a lower part of the gate region and the substrate.

Abstract: An integrated circuit includes a substrate and at least one component unfavorably sensitive to compressive stress which is arranged at least partially within an active region of the substrate limited by an insulating region. To address compressive stress in the active region, the circuit further includes at least one electrically inactive trench located at least in the insulating region and containing an internal area configured to reduce compressive stress in the active region. The internal area is filled with polysilicon. The polysilicon filled trench may further extend through the insulating region and into the substrate.

Abstract: An integrated circuit includes a substrate; an interconnect portion disposed over the substrate, the interconnect portion comprising multiple metallization levels separated by an insulating region; and an antifuse structure coated with a portion of the insulating region, the antifuse structure comprising a beam held at two different points by two arms, a body, and an antifuse insulating zone, the beam, the body and the arms being metal and located within a same metallization level, the body and the beam mutually making contact via the antifuse insulating zone, the antifuse insulating zone configured to undergo breakdown in the presence of a breakdown potential difference between the body and the beam.

Abstract: Method for generation of electrical power within a three-dimensional integrated structure comprising several elements electrically intercoupled by a link device, the method comprising the production of a temperature gradient in at least one region of the link device resulting from the operation of at least one of the said elements and the production of electrical power using at least one thermo-electric generator comprising at least one assembly of thermocouples electrically coupled in series and thermally coupled in parallel and contained within the said region subjected to the said temperature gradient.

Abstract: The thinning of a semiconductor substrate of an integrated circuit from a back face is detected using the measurement of a physical quantity representative of the resistance between the ends of two electrically-conducting contacts situated at an interface between an insulating region and an underlying substrate region. The two electrically-conducting contacts extend through the insulating region to reach the underlying substrate region.

Abstract: An integrated circuit includes a substrate and at least one component unfavorably sensitive to compressive stress which is arranged at least partially within an active region of the substrate limited by an insulating region. To address compressive stress in the active region, the circuit further includes at least one electrically inactive trench located at least in the insulating region and containing an internal area configured to reduce compressive stress in the active region. The internal area is filled with polysilicon. The polysilicon filled trench may further extend through the insulating region and into the substrate.

Abstract: A non-porous dielectric barrier is provided between a porous portion of a dielectric region and an electrically conductive element of an interconnect portion of an integrated circuit. This non-porous dielectric barrier protects the integrated circuit from breakdown of the least one dielectric region caused by electrical conduction assisted by the presence of defects located in the at least one dielectric region.

Abstract: In order, for example, to improve the ohmic contact between two metal pieces located at a metallization level, these two metal pieces are equipped with two offset vias located at the metallization level and at least partially at the via level immediately above. Each offset via comprises, for example, a nonoxidizable or substantially nonoxidizable compound, such as a barrier layer of Ti/TiN.

Abstract: Method for generation of electrical power within a three-dimensional integrated structure comprising several elements electrically interconnected by a link device, the method comprising the production of a temperature gradient in at least one region of the link device resulting from the operation of at least one of the said elements, and the production of electrical power using at least one thermo-electric generator comprising at least one assembly of thermocouples electrically connected in series and thermally connected in parallel and contained within the said region subjected to the said temperature gradient.

Abstract: A non-porous dielectric barrier is provided between a porous portion of a dielectric region and an electrically conductive element of an interconnect portion of an integrated circuit. This non-porous dielectric barrier protects the integrated circuit from breakdown of the least one dielectric region caused by electrical conduction assisted by the presence of defects located in the at least one dielectric region.

Abstract: An integrated circuit includes several metallization levels separated by an insulating region. A hollow housing whose walls comprise metallic portions is produced within various metallization levels. A controllable capacitive device includes a suspended metallic structure situated in the hollow housing within a first metallization level including a first element fixed on two fixing zones of the housing and at least one second element extending in cantilever fashion from the first element and includes a first electrode of the capacitive device. A second electrode includes a first fixed body situated at a second metallization level adjacent to the first metallization level facing the first electrode. The first element is controllable in flexion from a control zone of this first element so as to modify the distance between the two electrodes.

Abstract: A stack including a dual-passivation is etched locally so as to reveal contact pads of an integrated circuit which are situated above a last metallization level of an interconnection part of the integrated circuit. This stack serves to protect the integrated circuit against a breakdown of at least one dielectric region, at least in part porous, separating two electrically conducting elements of the interconnection part of the integrated circuit. Such a breakdown may occur due to electrical conduction assisted by the presence of defects within the at least one dielectric region.

Abstract: An integrated circuit includes a substrate with several functional blocks formed thereon. At least two identical functional blocks are respectively disposed at two or more different locations on the integrated circuit. Electrically inactive dummy modules in the neighborhoods and/or inside of the functional blocks are provided, wherein at least two different electrically inactive dummy modules are includes in the respective neighborhoods and/or inside of the at least two identical functional blocks.

Abstract: A variable capacitor includes a fixed main capacitor electrode disposed in a first metal layer overlying a substrate, a second main capacitor electrode spaced from the fixed main capacitor electrode, and a movable capacitor electrode disposed in the first metal layer adjacent the fixed main capacitor electrode. The movable capacitor electrode can be caused to be in a first position ohmically electrically connected to the fixed main capacitor electrode such that the variable capacitor has a first capacitance value or in a second position spaced from the fixed main capacitor electrode such that the variable capacitor has a second capacitance value.

Abstract: The thinning of a semiconductor substrate of an integrated circuit from a back face is detected using the measurement of a physical quantity representative of the resistance between the ends of two electrically-conducting contacts situated at an interface between an insulating region and an underlying substrate region. The two electrically-conducting contacts extend through the insulating region to reach the underlying substrate region.

Abstract: An integrated circuit includes several metallization levels separated by an insulating region. A hollow housing whose walls comprise metallic portions is produced within various metallization levels. A controllable capacitive device includes a suspended metallic structure situated in the hollow housing within a first metallization level including a first element fixed on two fixing zones of the housing and at least one second element extending in cantilever fashion from the first element and includes a first electrode of the capacitive device. A second electrode includes a first fixed body situated at a second metallization level adjacent to the first metallization level facing the first electrode. The first element is controllable in flexion from a control zone of this first element so as to modify the distance between the two electrodes.