A method includes performing a first light-exposure and a second a second light-exposure on a photo resist. The first light-exposure is performed using a first lithograph mask, which covers a first portion of the photo resist. The first portion of the photo resist has a first strip portion exposed in the first light-exposure. The second light-exposure is performed using a second lithograph mask, which covers a second portion of the photo resist. The second portion of the photo resist has a second strip portion exposed in the second light-exposure. The first strip portion and the second strip portion have an overlapping portion that is double exposed. The method further includes developing the photo resist to remove the first strip portion and the second strip portion, etching a dielectric layer underlying the photo resist to form a trench, and filling the trench with a conductive feature.

A power semiconductor device includes a power semiconductor chip and a fourth electrode. The power semiconductor chip has a first surface and a second surface opposite to each other and includes a first electrode and a second electrode on the first surface thereof, and a third electrode on the second surface thereof. The first electrode is provided in a main cell area of the first surface. The fourth electrode is provided on the first surface of the power semiconductor chip, is electrically connected to the first electrode, and has an overhanging portion that extends outwardly from an outer edge of the power semiconductor chip.

Interconnects and methods of fabricating a plurality of interconnects. The method includes depositing a conformal layer of a plating base in each of a plurality of vias, and depositing a photoresist on two portions of a surface of the plating base outside and above the plurality of vias. The method also includes depositing a plating metal over the plating base in each of the plurality of vias, the depositing resulting in each of the plurality of vias being completely filled or incompletely filled, performing a chemical mechanical planarization (CMP), and performing metrology to determine if any of the plurality of vias is incompletely filled following the depositing the plating metal. A second iteration of the depositing the plating metal over the plating base is performed in each of the plurality of vias based on determining that at least one of the plurality of vias is incompletely filled.

Provided is a semiconductor device free from chipping of a thin semiconductor element during transportation. The semiconductor device includes: a thin semiconductor element including a front-side electrode on the front side of the semiconductor element, and including a back-side electrode on the back side of the semiconductor element; a metallic member formed on at least one of the front-side electrode and the back-side electrode, the metallic member having a thickness equal to or greater than the thickness of the semiconductor element; and a resin member in contact with the lateral side of the metallic member and surrounding the periphery of the metallic member, with a part of the front side of the semiconductor element being exposed.

The method of manufacturing a connection structure of a semiconductor chip includes: preparing a semiconductor chip having a first surface having a connection pad disposed thereon and a second surface opposing the first surface and including a passivation layer disposed on the first surface and covering the connection pad; forming an insulating layer on the first surface of the semiconductor chip, the insulating layer covering at least a portion of the passivation layer; forming a via hole penetrating through the insulating layer to expose at least a portion of the passivation layer; exposing at least a portion of the connection pad by removing the passivation layer exposed by the via hole; forming a redistribution via by filling the via hole with a conductive material; and forming a redistribution layer on the redistribution via and the insulating layer.

At least one circuit element may be formed on a front side of a ringed substrate, and the ringed substrate may be mounted on a mounting chuck. The mounting chuck may have an inner raised portion configured to receive the thinned portion of the substrate thereon, and a recessed ring around a perimeter of the mounting chuck configured to receive the outer ring of the ringed substrate therein. At least one solder bump may be formed that is electrically connected to the at least one circuit element, while the ringed wafer is disposed on the mounting chuck.

Provided is a substrate structure, including: a substrate body having a conductive contact; an insulating layer formed on the substrate body with the conductive contact exposed therefrom; and an insulating protection layer formed on a portion of a surface of the insulating layer, and having a plurality of openings corresponding to the conductive contact, wherein at least one of the openings is disposed at an outer periphery of the conductive contact. Accordingly, the insulating protection layer uses the openings to dissipate and disperse residual stresses in a manufacturing process of high operating temperatures.

Provided is a substrate structure, including: a substrate body having a conductive contact; an insulating layer formed on the substrate body with the conductive contact exposed therefrom; and an insulating protection layer formed on a portion of a surface of the insulating layer, and having a plurality of openings corresponding to the conductive contact, wherein at least one of the openings is disposed at an outer periphery of the conductive contact. Accordingly, the insulating protection layer uses the openings to dissipate and disperse residual stresses in a manufacturing process of high operating temperatures.

Semiconductor devices are provided. The semiconductor devices include a substrate, a first interlayer insulating layer disposed on a front-side of the substrate, a TSV structure passing through the first interlayer insulating layer and the substrate. The TSV structure has a bottom end protruding from a back-side of the substrate, a back-side insulating layer and a back-side passivation layer disposed on the back-side of the substrate, and a bumping pad buried in the back-side insulating layer and the back-side passivation layer and disposed on the bottom end of the TSV structure. The bottom end of the TSV structure protrudes into the back-side bumping pad, and top surfaces of the back-side passivation layer and the back-side bumping pad are coplanar.

Semiconductor devices are provided. The semiconductor devices include a substrate, a first interlayer insulating layer disposed on a front-side of the substrate, a TSV structure passing through the first interlayer insulating layer and the substrate. The TSV structure has a bottom end protruding from a back-side of the substrate, a back-side insulating layer and a back-side passivation layer disposed on the back-side of the substrate, and a bumping pad buried in the back-side insulating layer and the back-side passivation layer and disposed on the bottom end of the TSV structure. The bottom end of the TSV structure protrudes into the back-side bumping pad, and top surfaces of the back-side passivation layer and the back-side bumping pad are coplanar.