The present disclosure provides a method for manufacturing capacitor array, including: forming, on an upper surface of the substrate, a laminated structure including sacrificial layers and support layers; forming a patterned mask layer on an upper surface of the laminated structure; etching the laminated structure based on the patterned mask layer to form a through hole, wherein after the through hole is formed, the patterned mask layer is retained on the upper surface of the laminated structure, and the through hole penetrates through the patterned mask layer and the laminated structure; forming a first electrode on a sidewall and at a bottom of the through hole; forming, in the patterned mask layer and the laminated structure, and removing the sacrificial layer based on the opening; forming a capacitor dielectric layer on a surface of the first electrode; and forming a second electrode on a surface of the capacitor dielectric layer.

A semiconductor device includes a terminal portion including a second external terminal, an insulating sheet disposed on the second external terminal, and a first external terminal disposed on the insulating sheet. The first external terminal has a first end portion with a first end. At the first end portion, a rear surface of the first external terminal is not parallel to a front surface of the second external terminal so that, in a thickness direction of the first external terminal, a distance between the first external terminal and the second external terminal increases with as the first end is approached.

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.

Disclosed are semiconductor devices including support patterns and methods of fabricating the same. The semiconductor devices may include a plurality of vertical structures on a substrate and a support pattern that contacts sidewalls of the plurality of vertical structures. The support pattern may include a plurality of support holes extending through the support pattern. The plurality of support holes may include a first support hole and a second support hole that are spaced apart from each other, and the first support hole may have a shape or size different from a shape or size of the second support hole.

Embodiments of the disclosure provide a capacitor for an integrated circuit (IC). The capacitor may include a first vertical electrode on an upper surface of a first conductor within a first wiring layer. A capacitor dielectric may be on an upper surface of the first vertical electrode. A second vertical electrode may be on an upper surface of the capacitor dielectric. The second vertical electrode is vertically between the capacitor dielectric and a second conductor. An inter-level dielectric (ILD) layer is adjacent to each of the first vertical electrode, the capacitor dielectric, and the second vertical electrode. The ILD layer is vertically between the first conductor and the second conductor.

A method for making a three-dimensional (3-D) module includes the steps of: A) forming a laminate of alternate ceramic tape layers and internal electrode layers on a substrate; B) etching said laminate to form first and second capacitor stacks at said first and second locations; C) firing said first and second capacitor stacks integrally; D) forming first and second pairs of external electrodes on said first and second capacitor stacks, respectively.

Three-dimensional capacitive structures may be produced by forming a capacitive stack conformally over pores in a region of porous anodic oxide. The porous anodic oxide region is provided on a stack of electrically-conductive layers including an anodization-resistant layer and an interconnection layer. In the pores there is a position having restricted diameter quite close to the pore bottom. In a first percentage of the pores in the region of anodic oxide, a functional portion of the capacitive stack is formed so as to extend into the pores no further than the restricted-diameter position. Cracks that may be present in the anodization-resistant layer have reduced effect on the properties of the capacitive structure. Increased thickness of the anodization-resistant layer can be tolerated, enabling equivalent series resistance of the overall capacitive structure to be reduced.

A semiconductor device includes a substrate, a bottom electrode on the substrate, a first support layer on the substrate next to a sidewall of the bottom electrode, a dielectric layer covering the sidewall and a top surface of the bottom electrode, and a top electrode on the dielectric layer. The bottom electrode includes a first part having a plurality of protrusions that protrude from a sidewall of the first part. The first part of the bottom electrode may be on the first support layer.

Semiconductor devices and methods are disclosed herein. In one example, a disclosed semiconductor device includes: an insulation layer, a first electrode with sidewalls and a bottom surface in contact with the insulation layer; a second electrode with sidewalls and a bottom surface in contact with the insulation layer; and an insulator formed between the first electrode and the second electrode. The insulator is coupled to a sidewall of the first electrode and coupled to a sidewall of the second electrode.

A method for fabricating a crown capacitor includes: forming a first supporting layer over a substrate; forming a second supporting layer above the first supporting layer; alternately stacking first and second sacrificial layers between the first and second supporting layers to collectively form a stacking structure; forming a recess extending through the stacking structure; performing an etching process to the first sacrificial layers at a first etching rate and the second sacrificial layers at a second etching rate greater than the first etching rate, such that each second sacrificial layer and immediately-adjacent two of the first sacrificial layers collectively define a concave portion; forming a first electrode layer over a surface of the recess in which the first electrode layer has a wavy structure; removing the first and second sacrificial layers; and forming a dielectric layer and a second electrode layer over the first electrode layer.