Header circuitry for a memory device includes multiple backside power rails that form distinct voltage sources for a plurality of switching devices in the header circuitry. The header circuitry includes at least one region of a first conductivity type. A first section in the first region includes one backside power rail (BPR) that forms a first voltage source that provides a first voltage. A second section in the same first region includes another BPR that forms a second voltage source that provides a second voltage that is different from the first voltage.

Header circuitry for a memory device includes multiple backside power rails that form distinct voltage sources for a plurality of switching devices in the header circuitry. The header circuitry includes at least one region of a first conductivity type. A first section in the first region includes one backside power rail (BPR) that forms a first voltage source that provides a first voltage. A second section in the same first region includes another BPR that forms a second voltage source that provides a second voltage that is different from the first voltage.

Embodiments of present invention provide a semiconductor device. The semiconductor device includes a silicon (Si) substrate containing a set of short channel field-effect-transistors (FETs); a germanium (Ge) layer on top of the Si substrate containing a set of long channel p-type FETs (PFETs); and an oxide semiconductor layer on top of the Ge layer containing a set of long channel n-type FETs (NFETs), wherein the set of short channel FETs, long channel PFETs, and long channel NFETs are interconnected through a set of far-back-end-of-line (FBEOL) layers.

Embodiments of present invention provide a semiconductor device. The semiconductor device includes a silicon (Si) substrate containing a set of short channel field-effect-transistors (FETs); a germanium (Ge) layer on top of the Si substrate containing a set of long channel p-type FETs (PFETs); and an oxide semiconductor layer on top of the Ge layer containing a set of long channel n-type FETs (NFETs), wherein the set of short channel FETs, long channel PFETs, and long channel NFETs are interconnected through a set of far-back-end-of-line (FBEOL) layers.

A semiconductor device includes a multi-layer board which a wiring pattern and a grounding pattern are formed. A plurality of semiconductor elements are mounted on the multi-layer board. An insulating sealing member is provided on the multi-layer board and is covering the plurality of semiconductor elements. A metal film is provided on the insulating sealing member. An in-groove metal is provided in contact with a plurality of grooves extending from a side-surface upper end of the insulating sealing member to a side-surface lower end of the multi-layer board. An in-hole metal is provided in an inner wall of a hole penetrating through the insulating sealing member and is extending to the multi-layer board. The in-hole metal is contacting with the metal film and the grounding pattern.

Electronic device package technology is disclosed. In one example, an electronic device comprises a die (18) having a bond pad (22); and a decoupling capacitor (14) mounted on the die (18) and electrically coupled to the die (18). A method for making an electronic device comprises mounting a decoupling capacitor (14) on a die (18); and electrically coupling the decoupling capacitor (14) to the die (18).

Electronic device package technology is disclosed. In one example, an electronic device comprises a die (18) having a bond pad (22); and a decoupling capacitor (14) mounted on the die (18) and electrically coupled to the die (18). A method for making an electronic device comprises mounting a decoupling capacitor (14) on a die (18); and electrically coupling the decoupling capacitor (14) to the die (18).

A method of forming a package structure includes: forming an inductor comprising a through-via over a carrier; placing a semiconductor device over the carrier; molding the semiconductor device and the through-via in a molding material; and forming a first redistribution layer on the molding material, wherein the inductor and the semiconductor device are electrically connected by the first redistribution layer.

A method of forming a package structure includes: forming an inductor comprising a through-via over a carrier; placing a semiconductor device over the carrier; molding the semiconductor device and the through-via in a molding material; and forming a first redistribution layer on the molding material, wherein the inductor and the semiconductor device are electrically connected by the first redistribution layer.

A package comprising a first substrate, a first integrated device coupled to the first substrate, and a second substrate, and a plurality of solder interconnects coupled to the first substrate and the second substrate. The first substrate comprises at least one first dielectric layer; a first plurality of interconnects, wherein the first plurality of interconnects include a first plurality of post interconnects; and a first solder resist layer coupled to a first surface of the first substrate. The second substrate comprises a first surface and a second surface; at least one second dielectric layer; a second plurality of interconnects, wherein the second plurality of interconnects comprises a second plurality of post interconnects; and a second solder resist layer coupled to the second surface of the second substrate. The second surface of the second substrate faces the first substrate. The second solder resist layer includes a cavity.