Abstract: A method for forming an interconnect structure includes forming an insulating layer on a substrate. A damascene opening is formed through a thickness portion of the insulating layer. A diffusion barrier layer is formed to line the damascene opening. A conductive layer is formed overlying the diffusion barrier layer to fill the damascene opening. A carbon-containing metal oxide layer is formed on the conductive layer and the insulating layer.

Abstract: A circuit includes a first plurality of memory cells coupled with a first data line and a first data transfer circuit coupled with the first data line and a second data line. In a first operation mode of the circuit, the first data line is left floating and is caused to have a first logical value by a current in at least one memory cell of the first plurality of memory cells. In a second operation mode of the circuit, the first data line is configured to reflect data stored in a memory cell of the plurality of memory cells, and the second data line is configured to reflect the data on the first data line through the first data transfer circuit.

Abstract: An embodiment is a semiconductor device comprising a first gate structure over a semiconductor substrate, a first etch stop layer (ESL) over the semiconductor substrate and the first gate, the first ESL having a curved top surface, and a first inter-layer dielectric (ILD) on the first ESL, the first ILD having a curved top surface. The semiconductor device further comprises a second ESL on the first ILD, the second ESL having a curved top surface, and a second ILD on the second ESL.

Abstract: Methods and apparatus for forming MEMS devices. An apparatus includes at least a portion of a semiconductor substrate having a first thickness and patterned to form a moveable mass; a moving sense electrode forming the first plate of a first capacitance; at least one anchor patterned from the semiconductor substrate and having a portion that forms the second plate of the first capacitance and spaced by a first gap from the first plate; a layer of semiconductor material of a second thickness patterned to form a first electrode forming a first plate of a second capacitance and further patterned to form a second electrode overlying the at least one anchor and forming a second plate spaced by a second gap that is less than the first gap; wherein a total capacitance is formed that is the sum of the first capacitance and the second capacitance. Methods are disclosed.

Abstract: A device includes a substrate and insulation regions over a portion of the substrate. A first semiconductor region is between the insulation regions and having a first conduction band. A second semiconductor region is over and adjoining the first semiconductor region, wherein the second semiconductor region includes an upper portion higher than top surfaces of the insulation regions to form a semiconductor fin. The second semiconductor region also includes a wide portion and a narrow portion over the wide portion, wherein the narrow portion is narrower than the wide portion. The semiconductor fin has a tensile strain and has a second conduction band lower than the first conduction band. A third semiconductor region is over and adjoining a top surface and sidewalls of the semiconductor fin, wherein the third semiconductor region has a third conduction band higher than the second conduction band.

Abstract: A metal-oxide-semiconductor field-effect transistor (MOSFET) includes a substrate, a source and a drain in the substrate, a gate electrode disposed over the substrate between the source and drain, and a gate dielectric layer disposed between the substrate and the gate electrode. At least a portion of the gate dielectric layer is extended beyond the gate electrode toward at least one of the source or the drain.

Abstract: A semiconductor device comprises a substrate, a bond pad above the substrate, a guard ring above the substrate, and an alignment mark above the substrate, between the bond pad and the guard ring. The device may comprise a passivation layer on the substrate, a polymer layer, a post-passivation interconnect (PPI) layer in contact with the bond pad, and a connector on the PPI layer, wherein the connector is between the bond pad and the guard ring, and the alignment mark is between the connector and the guard ring. The alignment mark may be at the PPI layer. There may be multiple alignment marks at different layers. There may be multiple alignment marks for the device around the corners or at the edges of an area surrounded by the guard ring.

Abstract: A chemical solution for use in cleaning a patterned substrate includes water, from approximate 0.01 to 99.98 percent by weight; hydrogen peroxide, from 0 to 30 percent by weight; a pH buffering agent, from approximate 0.01 to 50 percent by weight; a metal chelating agent, from approximate 0 to 10 percent by weight; and a compound for lowering a surface tension of the combination of water, hydrogen peroxide, pH buffering agent, and metal chelating agent. Examples of the compound include an organic solvent, from approximate 0 to 95 percent by weight, or a non-ionic surfactant agent, from approximate 0 to 2 percent by weight.

Abstract: A die has a top surface, and a metal pillar having a portion protruding over the top surface of the die. A sidewall of the metal pillar has nano-wires. The die is bonded to a package substrate. An underfill is filled into the gap between the die and the package substrate.

Abstract: Provided is a chip package structure and a method for forming the chip package. The method includes bonding a plurality of first dies on a carrier, encapsulating in a first molding compound the first dies on the carrier, coupling a plurality of second dies on the first dies using conductive elements, adding an underfill between the second dies and the first dies surrounding the conductive elements, and encapsulating in a second molding compound the second dies and the underfill. The chip package comprises a chip encapsulated in a molding compound, and a larger chip coupled to the first chip via conductive elements, wherein the conductive elements are encapsulated in an underfill between the chip and the larger chip without an interposer, and wherein the larger chip and the underfill are encapsulated in a second molding compound in contact with the molding compound.

Abstract: The present disclosure provides a resistive random access memory (RRAM) cells and methods of making the same. The RRAM cell includes a transistor and an RRAM structure. The RRAM structure includes a bottom electrode having a via portion and a top portion, a resistive material layer on the bottom electrode having a width that is same as a width of the top portion of the bottom electrode; a capping layer over the bottom electrode, a first spacer surrounding the capping layer and a top electrode, a second spacer surround the top portion of the bottom electrode and the first spacer, and the top electrode. The RRAM cell further includes a conductive material connecting the top electrode of the RRAM structure to a metal layer.

Abstract: Embodiments of the present disclosure include interconnect structures and methods of forming interconnect structures. An embodiment is an interconnect structure including a post-passivation interconnect (PPI) over a first substrate and a conductive connector on the PPI. The interconnect structure further includes a molding compound on a top surface of the PPI and surrounding a portion of the conductive connector, a top surface of the molding compound adjoining the conductive connector at an angle from about 10 degrees to about 60 degrees relative to a plane parallel with a major surface of the first substrate, the conductive connector having a first width at the adjoining top surface of the molding compound, and a second substrate over the conductive connector, the second substrate being mounted to the conductive connector.

Abstract: A method for forming a resistive memory cell within a memory array includes forming a patterned stopping layer on a first metal layer formed on a substrate and forming a bottom electrode into features of the patterned stopping layer. The method further includes forming a resistive memory layer. The resistive memory layer includes a metal oxide layer and a top electrode layer. The method further includes patterning the resistive memory layer so that the top electrode layer acts as a bit line within the memory array and a top electrode of the resistive memory cell.

Abstract: A method includes forming a semiconductor fin, performing a first passivation step on a top surface of the semiconductor fin using a first passivation species, and performing a second passivation step on sidewalls of the semiconductor fin using a second passivation species different from the first passivation species. A gate stack is formed on a middle portion of the semiconductor fin. A source or a drain region is formed on a side of the gate stack, wherein the source or drain region and the gate stack form a Fin Field-Effect Transistor (FinFET).

Abstract: An embodiment includes a substrate, wherein a portion of the substrate extends upwards forming a fin, a gate dielectric over a top surface and at least portions of sidewalls of the fin, a gate electrode over the gate dielectric, and a contact over and extending into the gate electrode, wherein the contact has a first width above the gate electrode and a second width within the gate electrode, the first width being smaller than the second width.

Abstract: An integrated circuit package includes a die. An electrically conductive layer comprises a redistribution layer (RDL) in the die, or a micro-bump layer above the die, or both. The micro bump layer comprises at least one micro-bump line. A filter comprises the electrically conductive layer. A capacitor comprises an electrode formed in the electrically conductive layer.

Abstract: Methods for forming a semiconductor device and a FinFET device are disclosed. A method comprises forming a dummy gate electrode layer over a substrate, the dummy gate electrode layer having a first height, forming a first etch stop layer on the dummy gate electrode layer, forming a first hard mask layer on the first etch stop layer, and patterning the first hard mask layer. The method further comprises patterning the first etch stop layer to align with the patterned first hard mask layer, and patterning the gate electrode layer to form a dummy gate electrode, the dummy gate electrode aligning with the patterned first etch stop layer, wherein after the patterning the gate electrode layer the first hard mask layer has a vertical sidewall of a second height, the second height being less than the first height, and the first hard mask layer having a rounded top surface.

Abstract: A method includes forming a passivation layer over a metal pad, wherein the metal pad is further overlying a semiconductor substrate of a wafer. A Post-Passivation Interconnect (PPI) is formed to electrically couple to the metal pad, wherein a portion of the PPI is overlying the passivation layer. A metal bump is formed over and electrically coupled to the PPI. The method further includes applying a molding compound over the metal bump and the PPI, applying a release film over the molding compound, pressing the release film against the molding compound, and curing the molding compound when the release film is pressed against the molding compound. The release film is then removed from the molding compound. The wafer is sawed into dies using a blade, with the blade cutting through the molding compound.

Abstract: Packaging devices and methods for semiconductor devices are disclosed. In some embodiments, a packaging device for a semiconductor device includes a packaging substrate including a semiconductor device mounting region. The packaging device includes a stress isolation structure (SIS) disposed on the packaging substrate proximate a portion of a perimeter of the semiconductor device mounting region.

Abstract: The present disclosure provides a biochip and methods of fabricating. The biochip includes a fluidic part and a sensing part bonded together using a polymer. The fluidic part has microfluidic channel pattern on one side and fluidic inlet and fluidic outlet on the other side that are fluidly connected to the microfluidic channel pattern. The fluidic inlet and fluidic outlet are formed by laser drilling after protecting the microfluidic channel pattern with a sacrificial protective layer. The polymer bonding is performed at low temperature without damaging patterned surface chemistry on a sensing surface of the sensing part.