Disclosed are integrated circuit (IC) structure embodiments with a three-dimensional (3D) metal-insulator-metal capacitor (MIMCAP) in back-end-of-the-line (BEOL) metal levels. The MIMCAP includes a plurality of high aspect ratio trenches that extend through at least one relatively thick dielectric layer within the metal levels. Conformal layers of a metal, an insulator and another metal line the trenches and cover the top of the dielectric layer in the area of the MIMCAP. Different configurations for the bottom and top electrode contacts can be used including, for example, one configuration where the top electrode contact is a dual-damascene structure within an ultra-thick metal (UTM) level above the MIMCAP and another configuration where both the top and bottom electrode contacts are such dual-damascene structures. Also disclosed are method embodiments for forming IC structures with such a MIMCAP and these method embodiments can be readily integrated into current BEOL processing, including UTM-level dual-damascene processing.

A system and method for fabricating on-die metal-insulator-metal capacitors capable of supporting relatively high voltage applications and increasing capacitance per area are described. In various implementations, an integrated circuit includes multiple metal-insulator-metal (MIM) capacitors. The MIM capacitors are formed between two signal nets such as two different power rails, two different control signals, or two different data signals. The integrated circuit includes multiple intermediate metal layers (or metal plates) formed between two signal nets. In high voltage regions, a MIM capacitor has one or more intermediate metal plates formed as floating plates between electrode metal plates. The floating plates have no connection to any power supply reference voltage level used by the integrated circuit. The insulating distance between the two electrode metal plates includes the thicknesses of the two dielectric layers, but the thickness of the conductive floating metal plate does not contribute to this insulating distance.

A capacitor and a method of fabricating the capacitor are provided. The capacitor includes a structure for forming a three-dimensional capacitor, the structure being a pillar structure or a trench structure; where when the structure is a pillar structure, the aspect ratio of the pillar structure is more than 10; when the structure is a trench structure, the capacitor further includes a substrate, the trench structure is formed by a material layer disposed on the surface of a base trench of the substrate, and the aspect ratio of the trench structure is more than 10. The aspect ratio of the pillar structure of the capacitor or the aspect ratio of the trench structure may be more than 10, so that the performance of the capacitor is better.

A package structure including a capacitor mounted within a cavity in the package substrate is disclosed. The package structure may additionally include a die mounted to a die side surface of the package substrate, and the opposing land side surface of the package substrate may be mounted to a printed circuit board (PCB). The capacitor may be mounted within a cavity formed in the die side surface of the package substrate or the land side surface of the package substrate. Mounting a capacitor within a cavity may reduce the form factor of the package. The die may be mounted within a cavity formed in the die side surface of the package substrate. Solder balls connecting the package to the PCB may be mounted within one or more cavities formed in one or both of the package substrate and the PCB.

A method of fabricating a semiconductor memory device includes forming a bit line and a bit line capping pattern on the semiconductor substrate, forming a first spacer covering a sidewall of the bit line capping pattern and a sidewall of the bit line, forming a contact plug in contact with a sidewall of the first spacer and having a top surface that is lower than an upper end of the first spacer, removing an upper portion of the first spacer, forming a first sacrificial layer closing at least an entrance of the void, forming a second spacer covering the sidewall of the bit line capping pattern and having a bottom surface in contact with a top surface of the first spacer, and removing the first sacrificial layer. The bit line capping pattern is on the bit line. The contact plug includes a void exposed on the top surface.

Disclosed embodiments include in-recess fabricated vertical capacitor cells, that can be assembled as close to the surface of a semiconductor package substrate as the first-level interconnect surface. The in-recess fabricated vertical capacitor cells are semiconductor package-integrated capacitors. Disclosed embodiments include laminated vertical capacitor cells where a plated through-hole is twice breached to form opposing capacitor plates. The breached, plated through-hole capacitors are semiconductor package-integrated capacitors.

Disclosed embodiments include in-recess fabricated vertical capacitor cells, that can be assembled as close to the surface of a semiconductor package substrate as the first-level interconnect surface. The in-recess fabricated vertical capacitor cells are semiconductor package-integrated capacitors. Disclosed embodiments include laminated vertical capacitor cells where a plated through-hole is twice breached to form opposing capacitor plates. The breached, plated through-hole capacitors are semiconductor package-integrated capacitors.

A semiconductor device includes a capacitor structure. The capacitor structure comprises conductive vias extending through openings in a stack of alternating dielectric materials and first conductive materials, each conductive via comprising a second conductive material extending through the openings and another dielectric material on sidewalls of the openings, first conductive lines in electrical communication with a first group of the conductive vias, and second conductive lines in electrical communication with a second group of the conductive vias. Related semiconductor device, electronic systems, and methods are disclosed.

Back end of the line precision resistors that allow for high currents and for configuration as an eFuse by embedding a single thin film high resistive metal material within a dielectric layer, wherein the resisters are coupled to sidewalls of adjacent metal interconnects are described. The resistors can be formed in the metal one (M1) dielectric layer and can be coupled to sidewalls of the M1 interconnects. Also described are processes for fabricating integrated circuits including the resistors and/or e-Fuses.

A semiconductor structure includes: an electrode cover layer; a first conductive structure on the electrode cover layer; a contact structure, including a first and a first contact layera. The first contact layer is in contact with the first conductive structure, the bottom of the second contact layer is in contact with the top of the first contact layer, the width of the first contact layer is greater than the width of the bottom of the second contact layer, the lower surface of the contact structure is not lower than the lower surface of the electrode cover layer, and the resistivity of the first conductive structure is not greater than that of the contact structure and is not greater than that of the electrode cover layer. The contact area between contact structure and electrode covering layer is increased, thus avoiding voids in the contact structure, reducing contact and volume resistance between the contact and the capacitance under the electrode covering layer.