A semiconductor device comprises a semiconductor die and an integrated capacitor formed over the semiconductor die. The integrated capacitor is configured to receive a high voltage signal. A transimpedance amplifier is formed in the semiconductor die. An avalanche photodiode is disposed over or adjacent to the semiconductor die. The integrated capacitor is coupled between the avalanche photodiode and a ground node. A resistor is coupled between a high voltage input and the avalanche photodiode. The resistor is an integrated passive device (IPD) formed over the semiconductor die. A first terminal of the integrated capacitor is coupled to a ground voltage node. A second terminal of the integrated capacitor is coupled to a voltage greater than 20 volts. The integrated capacitor comprises a plurality of interdigitated fingers in one embodiment. In another embodiment, the integrated capacitor comprises a plurality of vertically aligned plates.

The present application provides a capacitor and a method for producing the same The capacitor includes: a multi-wing structure, including N groups of wing structures and N support structures, each group of the wing structures includes M wing structures arranged in parallel, M limit slots are formed on an outer side wall of the support structure, the M wing structures are fixed on outside of the support structure through the M limit slots, respectively, and M and N are positive integers; a laminated structure, covering the multi-wing structure and including at least one dielectric layer and a plurality of conductive layers; at least one first external electrode, electrically connecting to part or all of the odd-number conductive layers in the plurality of conductive layers; and at least one second external electrode, electrically connecting to part or all of even-number conductive layers in the plurality of conductive layers.

A semiconductor device includes: a first insulating layer, a plurality of first electrodes penetrating the first insulating layer, a plurality of second electrodes penetrating the first insulating layer, the plurality of second electrodes being located between the plurality of first electrodes: a first high dielectric constant layer having a dielectric constant higher than a dielectric constant of the first insulating layer, a plurality of third electrodes penetrating the first high dielectric constant layer, the plurality of third electrodes being respectively connected to the plurality of first electrodes, and a plurality of fourth electrodes penetrating the first high dielectric constant layer, the plurality of fourth electrodes being located between the plurality of third electrodes.

A method for manufacturing a capacitive device comprising the following steps: a) providing a metallic layer, b) depositing a full-sheet aluminium layer, c) structuring pores in the aluminium layer by a full-sheet anodic etching process, subsequently to which a continuous porous alumina layer is obtained comprising a first main face and a second main face, longitudinal pores extending from the first main face to the second main face, d) forming a capacitive area at a first area of the porous alumina layer, e) forming an upper electrode over the capacitive area, f) forming a contact resumption at a second area of the porous alumina layer, g) forming a lower electrode over the contact resumption.

The present invention relates to a capacitor and its formation method and to a DRAM cell. In various embodiments, a substrate is provided such that an electrical contact portion is formed thereon. A dielectric layer is formed on a surface of the substrate, including alternately stacked supporting layers and sacrificial layers. At least two capacitor holes penetrating the sacrificial layers and the supporting layers can formed to expose the same electrical contact portion. A lower electrode layer covering the inner surface of the capacitor holes can be formed. The lower electrode layer is connected to the electrical contact portion. The sacrificial layers are then removed and a capacitor dielectric layer and an upper electrode layer are formed successively on the inner and outer surfaces of the lower electrode layer and on the surface of the supporting layers. This can increase capacitance value per unit area of the capacitor.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a dielectric stack disposed over a substrate. The dielectric stack has a first plurality of layers interleaved between a second plurality of layers. The dielectric stack has one or more surfaces that define a plurality of indentations recessed into a side of the dielectric stack at different vertical heights corresponding to the second plurality of layers. A capacitor structure lines the one or more surfaces of the dielectric stack. The capacitor structure includes conductive electrodes separated by a capacitor dielectric.

Embodiments herein describe techniques for a semiconductor device including a three dimensional capacitor. The three dimensional capacitor includes a pole, and one or more capacitor units stacked around the pole. A capacitor unit of the one or more capacitor units includes a first electrode surrounding and coupled to the pole, a dielectric layer surrounding the first electrode, and a second electrode surrounding the dielectric layer. Other embodiments may be described and/or claimed.

A semiconductor device includes a substrate. The semiconductor device further includes a circuit layer over the substrate. The semiconductor device further includes a test line electrically connected to the circuit layer. The semiconductor device further includes a capacitor on the substrate. The capacitor includes a first conductor, wherein the first conductor is on a portion of the substrate exposed by the circuit layer. The capacitor further includes an insulator surrounding the first conductor.

A sense amplifier and a semiconductor device which are less likely to be influenced by a variation in transistor characteristics and their operation methods are provided. An amplifier circuit in a sense amplifier includes a first circuit and a second circuit, each including an inverter, a first transistor, a second transistor, and a capacitor. A first terminal and a second terminal of the capacitor are electrically connected to a first bit line and an input terminal of the inverter, respectively. The first transistor and the second transistor function as a switch that switches conduction and non-conduction between the input terminal and an output terminal of the inverter, and a switch that switches conduction and non-conduction between the output terminal of the inverter and the second bit line, respectively. The first circuit and the second circuit are initialized by a potential obtained when conduction is established between the input terminal and the output terminal of the inverter.

A semiconductor substrate has a front face with a first dielectric region. A capacitive element includes, on a surface of the first dielectric region at the front face, a stack of layers which include a first conductive region, a second conductive region and a third conductive region. The second conductive region is electrically insulated from the first conductive region by a second dielectric region. The second conductive region is further electrically insulated from the third conductive region by a third dielectric region. The first and third conductive regions form one plate of the capacitive element, and the second conductive region forms another plate of the capacitive element.