Abstract: A bonded assembly of a first wafer including a first semiconductor substrate and a second wafer including a second semiconductor substrate may be formed. The second semiconductor substrate may be thinned to a first thickness, and an inter-wafer moat trench may be formed at a periphery of the bonded assembly. A protective material layer may be formed in the inter-wafer moat trench and over the backside surface of the second semiconductor substrate. A peripheral portion of the second semiconductor substrate located outside the inter-wafer moat trench may be removed, and a cylindrical portion of the protective material layer laterally surrounds a remaining portion of the bonded assembly. The second semiconductor substrate may be thinned to a second thickness by performing at least one thinning process while the cylindrical portion of the protective material layer protects the remaining portion of the bonded assembly.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip structure. The integrated chip structure includes a first substrate having a first horizontally extending surface and a second horizontally extending surface above the first horizontally extending surface as viewed in a cross-sectional view. The first horizontally extending surface continuously wraps around an outermost perimeter of the second horizontally extending surface in a closed loop as viewed in a plan-view. A second substrate is disposed over the first substrate and includes a third horizontally extending surface above the second horizontally extending surface as viewed in the cross-sectional view. The second horizontally extending surface continuously wraps around an outermost perimeter of the third horizontally extending surface in a closed loop as viewed in the plan-view.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip structure. The method may be performed by forming a plurality of interconnect layers within a first interconnect structure disposed over an upper surface of a first semiconductor substrate. An edge trimming process is performed to remove parts of the first interconnect structure and the first semiconductor substrate along a perimeter of the first semiconductor substrate. The edge trimming process results in the first semiconductor substrate having a recessed surface coupled to the upper surface by way of an interior sidewall disposed directly over the first semiconductor substrate. A dielectric capping structure is formed onto a sidewall of the first interconnect structure after performing the edge trimming process.

Abstract: The present disclosure relates to a method and an associated process tool. The method includes generating electromagnetic radiation that is directed toward a perimeter of a pair of bonded workpieces and toward a radiation sensor that is arranged behind the perimeter of the pair of bonded workpieces. The electromagnetic radiation is scanned along a vertical axis. An intensity of the electromagnetic radiation that impinges on the radiation sensor is measured throughout the scanning. Measuring the intensity includes recording a plurality of intensity values of the electromagnetic radiation at a plurality of different positions along the vertical axis extending past top and bottom surfaces of the pair of bonded workpieces. A position of an interface between the pair of bonded workpieces is determined based on a maximum measured intensity value of the plurality of intensity values.

Abstract: A semiconductor device including a substrate, a source region, a drain region, a first gate structure and a second gate structure is provided. The source region and a drain region are formed in the substrate. The first gate structure is formed on the substrate and adjacent to the source region. The second gate structure is formed on the substrate and adjacent to the drain region. The second gate structure is electrically coupled to the drain region.

Abstract: A structure and a method of forming are provided. The structure includes a first dielectric layer overlying a first substrate. A first connection pad is disposed in a top surface of the first dielectric layer and contacts a first redistribution line. A first dummy pad is disposed in the top surface of the first dielectric layer, the first dummy pad contacting the first redistribution line. A second dielectric layer overlies a second substrate. A second connection pad and a second dummy pad are disposed in the top surface of the second dielectric layer, the second connection pad bonded to the first connection pad, and the first dummy pad positioned in a manner that is offset from the second dummy pad so that the first dummy pad and the second dummy pad do not contact each other.

Abstract: A bonded assembly of a first wafer including a first semiconductor substrate and a second wafer including a second semiconductor substrate may be formed. The second semiconductor substrate may be thinned to a first thickness, and an inter-wafer moat trench may be formed at a periphery of the bonded assembly. A protective material layer may be formed in the inter-wafer moat trench and over the backside surface of the second semiconductor substrate. A peripheral portion of the second semiconductor substrate located outside the inter-wafer moat trench may be removed, and a cylindrical portion of the protective material layer laterally surrounds a remaining portion of the bonded assembly. The second semiconductor substrate may be thinned to a second thickness by performing at least one thinning process while the cylindrical portion of the protective material layer protects the remaining portion of the bonded assembly.

Abstract: A method for forming a hybrid-bonding structure is provided. The method includes forming a first dielectric layer over a first semiconductor substrate. The first semiconductor substrate includes a conductive structure. The method also includes partially removing the first dielectric layer to form a first dielectric dummy pattern, a second dielectric dummy pattern and a third dielectric dummy pattern and an opening through the first dielectric layer. The first dielectric dummy pattern, the second dielectric dummy pattern and the third dielectric dummy pattern are surrounded by the opening. In addition, the method includes forming a first conductive line in the opening. The first conductive line is in contact with the conductive structure.

Abstract: The present disclosure, in some embodiments, relates to a multi-dimensional integrated chip structure. The multi-dimensional integrated chip structure includes a first substrate having a first upper surface and a second upper surface above the first upper surface. A first outermost perimeter of the first upper surface is larger than a second outermost perimeter of the second upper surface. A second substrate is over the first substrate. The second substrate has a third upper surface above the second upper surface. A third outermost perimeter of the third upper surface is smaller than the second outermost perimeter of the second upper surface.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip structure. The method may be performed by forming a plurality of interconnect layers within a first interconnect structure disposed over an upper surface of a first semiconductor substrate. An edge trimming process is performed to remove parts of the first interconnect structure and the first semiconductor substrate along a perimeter of the first semiconductor substrate. The edge trimming process results in the first semiconductor substrate having a recessed surface coupled to the upper surface by way of an interior sidewall disposed directly over the first semiconductor substrate. A dielectric capping structure is formed onto a sidewall of the first interconnect structure after performing the edge trimming process.

Abstract: In some embodiments, the present disclosure relates to a wafer edge trimming apparatus that includes a processing chamber defined by chamber housing. Within the processing chamber is a wafer chuck configured to hold onto a wafer structure. Further, a blade is arranged near an edge of the wafer chuck and configured to remove an edge potion of the wafer structure and to define a new sidewall of the wafer structure. A laser sensor apparatus is configured to direct a laser beam directed toward a top surface of the wafer chuck. The laser sensor apparatus is configured to measure a parameter of an analysis area of the wafer structure. Control circuitry is to the laser sensor apparatus and the blade. The control circuitry is configured to start a damage prevention process when the parameter deviates from a predetermined threshold value by at least a predetermined shift value.

Abstract: Various embodiments of the present disclosure are directed towards a chemical mechanical polishing (CMP) system including a first CMP head and a second CMP head. The first CMP head is configured to retain a workpiece and comprises a first plurality of pressure elements disposed across a first pressure control plate. The second CMP head is configured to retain the workpiece. The second CMP head comprises a second plurality of pressure elements disposed across a second pressure control plate. A distribution of the first plurality of pressure elements across the first pressure control plate is different from a distribution of the second plurality of pressure elements across the second pressure control plate.

Abstract: A semiconductor device is provided. The semiconductor device comprises an output circuit configured to be electrically connected between a driving circuit and an external load circuit, and a protection circuit electrically connected to the output circuit and the driving circuit. The protection circuit comprises a first transistor having a base electrode, a collector electrode and an emitter electrode and a second transistor having a base electrode, a collector electrode and an emitter electrode. The base electrode of the first transistor is electrically connected to the collector electrode of the second transistor.

Abstract: A high-voltage semiconductor device structure is provided. The high-voltage semiconductor device structure includes a semiconductor substrate, a source ring in the semiconductor substrate, and a drain region in the semiconductor substrate. The high-voltage semiconductor device structure also includes a doped ring surrounding sides and a bottom of the source ring and a well region surrounding sides and bottoms of the drain region and the doped ring. The well region has a conductivity type opposite to that of the doped ring. The high-voltage semiconductor device structure further includes a conductor electrically connected to the drain region and extending over and across a periphery of the well region. In addition, the high-voltage semiconductor device structure includes a shielding element ring between the conductor and the semiconductor substrate. The shielding element ring extends over and across the periphery of the well region.

Abstract: Some embodiments relate to a three-dimensional (3D) integrated circuit (IC). The 3D IC includes a first IC die comprising a first semiconductor substrate, and a first interconnect structure over the first semiconductor substrate. The 3D IC also includes a second IC die comprising a second semiconductor substrate, and a second interconnect structure that separates the second semiconductor substrate from the first interconnect structure. A seal ring structure separates the first interconnect structure from the second interconnect structure and perimetrically surrounds a gas reservoir between the first IC die and second IC die. The seal ring structure includes a sidewall gas-vent opening structure configured to allow gas to pass between the gas reservoir and an ambient environment surrounding the 3D IC.

Abstract: A bonded assembly of a first wafer including a first semiconductor substrate and a second wafer including a second semiconductor substrate may be formed. The second semiconductor substrate may be thinned to a first thickness, and an inter-wafer moat trench may be formed at a periphery of the bonded assembly. A protective material layer may be formed in the inter-wafer moat trench and over the backside surface of the second semiconductor substrate. A peripheral portion of the second semiconductor substrate located outside the inter-wafer moat trench may be removed, and a cylindrical portion of the protective material layer laterally surrounds a remaining portion of the bonded assembly. The second semiconductor substrate may be thinned to a second thickness by performing at least one thinning process while the cylindrical portion of the protective material layer protects the remaining portion of the bonded assembly.

Abstract: A high-voltage semiconductor device structure is provided. The high-voltage semiconductor device structure includes a semiconductor substrate, a source ring in the semiconductor substrate, and a drain region in the semiconductor substrate. The high-voltage semiconductor device structure also includes a doped ring surrounding sides and a bottom of the source ring and a well region surrounding sides and bottoms of the drain region and the doped ring. The well region has a conductivity type opposite to that of the doped ring. The high-voltage semiconductor device structure further includes a conductor electrically connected to the drain region and extending over and across a periphery of the well region. In addition, the high-voltage semiconductor device structure includes a shielding element ring between the conductor and the semiconductor substrate. The shielding element ring extends over and across the periphery of the well region.

Abstract: A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, the 3D IC comprises a first IC die comprising a first substrate, a first interconnect structure disposed over the first substrate, and a first through substrate via(TSV) disposed through the first substrate. The 3D IC further comprises a second IC die comprising a second substrate, a second interconnect structure disposed over the second substrate, and a second TSV disposed through the second substrate. The 3D IC further comprises a bonding structure arranged between back sides of the first IC die and the second IC die opposite to corresponding interconnect structures and bonding the first IC die and the second IC die. The bonding structure comprises conductive features disposed between and electrically connecting the first TSV and the second TSV.

Abstract: A method for manufacturing three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is formed and bonded to a first IC die by a first bonding structure. A third IC die is formed and bonded to the second IC die by a second bonding structure. The second bonding structure is formed between back sides of the second IC die and the third IC die opposite to corresponding interconnect structures and comprises a first TSV (through substrate via) disposed through a second substrate of the second IC die and a second TSV disposed through a third substrate of the third IC die. In some further embodiments, the second bonding structure is formed by forming conductive features with oppositely titled sidewalls disposed between the first TSV and the second TSV.

Abstract: Various embodiments of the present disclosure are directed towards an integrated circuit (IC) chip comprising a stilted pad structure. A wire underlies a semiconductor substrate on a frontside of the semiconductor substrate. Further, a trench isolation structure extends into the frontside of the semiconductor substrate. The stilted pad structure is inset into a backside of the semiconductor substrate that is opposite the frontside. The stilted pad structure comprises a pad body and a pad protrusion. The pad protrusion underlies the pad body and protrudes from the pad body, through a portion of the semiconductor substrate and the trench isolation structure, towards the wire. The pad body overlies the portion of the semiconductor substrate and is separated from the trench isolation structure by the portion of the semiconductor substrate.