A method including forming an oxygen gettering layer on one side of an insulating layer of a deep trench capacitor between the insulating layer and a substrate, the oxygen gettering layer including an aluminum containing compound, and depositing an inner electrode on top of the insulating layer, the inner electrode including a metal.

In some embodiments, a system may include an integrated circuit. The integrated circuit may include a substrate including a first surface, a second surface substantially opposite of the first surface, and a first set of electrical conductors coupled to the first surface. The first set of electrical conductors may function to electrically connect the integrated circuit to a circuit board. The integrated circuit may include a semiconductor die coupled to the second surface of the substrate using a second set of electrical conductors. The integrated circuit may include a passive device dimensioned to be integrated with the integrated circuit. The passive device may be positioned between the second surface and at least one of the first set of electrical conductors. The die may be electrically connected to a second side of the passive device. A first side of the passive device may be available to be electrically connected to a second device.

Provided is a vertical non-volatile memory device in which a capacitor constituting a peripheral circuit region is formed as a vertical type so that an area occupied by the capacitor in the entire device can be reduced as compared with a planar capacitor. Thus, a non-volatile memory device may be highly integrated and have a high capacity. The device includes a substrate having a cell region and a peripheral circuit region, a memory cell string including a plurality of vertical memory cells formed in the cell region and channel holes formed to penetrate the vertical memory cells in a first direction vertical to the substrate, an insulating layer formed in the peripheral circuit region on the substrates at substantially the same level as an upper surface of the memory cell string, and a plurality of capacitor electrodes formed on the peripheral circuit region to penetrate at least a portion of the insulating layer in the first direction, the plurality of capacitor electrodes extending parallel to the channel holes. The plurality of capacitor electrodes are spaced apart from one another in a second direction parallel to the substrate, and the insulating layer is interposed between a pair of adjacent capacitor electrodes from among the plurality of capacitor electrodes.

A method for manufacturing a metal insulator metal (MIM) trench capacitor, the method may include forming a cavity in an Intermetal Dielectric stack, wherein a bottom of the cavity exposes a lower metal layer; wherein the Intermetal Dielectric stack comprises a top dielectric layer; depositing a first metal layer on a bottom of a cavity and on sidewalls of the cavity; depositing a sacrificial layer over the first metal layer; filling the cavity with a filling material; removing, by a planarization process, a portion of the sacrificial layer positioned above the top dielectric layer and a portion of the first metal layer positioned above the top dielectric layer to expose an upper portion of the sacrificial layer and an upper portion of the first metal layer; forming a recess by removing the upper portion of the sacrificial layer and the upper portion the first metal layer while using the filling material as a mask; removing the filling material by a first removal process that is selective to the sacrificial layer and to the first metal layer; removing the sacrificial layer by a second removal process that is less aggressive than the first removal process; fabricating an insulator layer on the first metal layer; and depositing a second metal layer on the insulator layer.

A semiconductor device includes a plurality of memory cells being disposed in a matrix in a memory cell array area, each of the memory cells includes a capacitive element including a cell plate electrode, a capacitive insulating film, and a storage node electrode, and a switch transistor coupled between the storage node electrode and a bit line and being controlled based on a potential of a word line, a peripheral circuit disposed in a peripheral circuit area adjacent to the memory cell array area, and a signal line formed at a boundary between the memory cell array area and the peripheral circuit area. The capacitive element has a cylinder shape. The storage node electrode is formed on inner wall of a hole which penetrates through a first insulating film layer and a second insulating film layer.

A switched-capacitor DC-to-DC converter includes a logic cell and a capacitor cell vertically overlapping with the logic cell. The logic cell has a plurality of active elements disposed over a first substrate. The capacitor cell has a capacitor over a second substrate. A first interlayer insulation layer disposed over the first substrate is bonded to a second interlayer insulation layer disposed over the second substrate. A first through via connected to any one of interconnection patterns of the logic cell and a second through via connected to a lower electrode pattern of the capacitor cell are connected to each other through a first external circuit pattern. A third through via connected to an upper electrode pattern of the capacitor cell and a fourth through via connected to another one of the interconnection patterns of the logic cell are connected to each other through a second external circuit pattern.

A method of fabricating a pixel array includes forming a transistor network along a frontside of a semiconductor substrate. A contact element is formed for every pixel in the pixel array that is electrically coupled to a transistor within the transistor network. An interconnect layer is formed upon the frontside to control the transistor network with a dielectric that covers the contact element. A cavity is formed in the interconnect layer. A conductive layer is formed along cavity walls of the cavity and a dielectric layer is formed over the conductive layer within the cavity. A photosensitive semiconductor material is deposited over the dielectric layer within the cavity. An electrode cavity is formed that extends into the contact element. The electrode cavity is at least partially filled with a conductive material to form an electrode. The electrode, the conductive layer, and the photosensitive semiconductor material form a photosensitive capacitor.

A semiconductor memory device includes a power decoupling capacitor (PDC) for preventing effective capacitance reduction during a high frequency operation. The semiconductor memory device includes the PDC to which a cell capacitor type decoupling capacitor is connected in series. The PDC includes a metal conductive layer electrically connected in parallel to a conductive layer formed on the same level as a bit line of a cell array region, wherein a plurality of decoupling capacitors in a first group and a plurality of decoupling capacitors in a second group are respectively connected to each other in parallel in a peripheral circuit region, and a storage electrode of the first group and a storage electrode of the second group are electrically connected to each other in series through the conductive layer.

Methods of forming passive elements under a device layer are described. Those methods and structures may include forming at least one passive structure, such as a capacitor and a resistor structure, in a substrate, wherein the passive structures are vertically disposed within the substrate. An insulator layer is formed on a top surface of the passive structure, a device layer is formed on the insulator layer, and a contact is formed to couple a device disposed in the device layer to the at least one passive structure.

The disclosure provides a capacitor array. The capacitor array includes one or more first metal plates vertically stacked parallel to each other. A second metal plate is horizontally stacked to couple one end of each first metal plate of the one or more first metal plates. One or more third metal plates are vertically stacked parallel to the one or more first metal plates. Each third metal plate of the one or more third metal plates is stacked between two first metal plates.