A manufacturing method of a semiconductor structure includes at least the following steps. A patterned mask layer with a first opening is formed on a dielectric layer overlying a semiconductor substrate. A portion of the dielectric layer accessibly exposed by the first opening of the patterned mask layer is removed to form a second opening. A first protective film is formed on inner sidewalls of the dielectric layer and the patterned mask layer, where the second opening and the first protective film are formed at the same step. A second protective film is formed on the first protective film to form a protective structure covering the inner sidewalls. A portion of the semiconductor substrate accessibly exposed by the second opening is removed to form a via hole including an undercut underlying the protective structure. The via hole is trimmed and a through substrate via is formed in the via hole.

A manufacturing method of a semiconductor structure includes at least the following steps. A patterned mask layer with a first opening is formed on a dielectric layer overlying a semiconductor substrate. A portion of the dielectric layer accessibly exposed by the first opening of the patterned mask layer is removed to form a second opening. A first protective film is formed on inner sidewalls of the dielectric layer and the patterned mask layer, where the second opening and the first protective film are formed at the same step. A second protective film is formed on the first protective film to form a protective structure covering the inner sidewalls. A portion of the semiconductor substrate accessibly exposed by the second opening is removed to form a via hole including an undercut underlying the protective structure. The via hole is trimmed and a through substrate via is formed in the via hole.

The disclosed techniques relate to methods and apparatus for etching a substrate. A plate assembly divides a reaction chamber into a lower and upper sub-chamber. The plate assembly includes an upper and lower plate having apertures therethrough. When the apertures in the upper and lower plates are aligned, ions and neutral species may travel through the plate assembly into the lower sub-chamber. When the apertures are not aligned, ions are prevented from passing through the assembly while neutral species are much less affected. Thus, the ratio of ion flux:neutral flux may be tuned by controlling the amount of area over which the apertures are aligned. In certain embodiments, one plate of the plate assembly is implemented as a series of concentric, independently movable injection control rings. Further, in some embodiments, the upper sub-chamber is implemented as a series of concentric plasma zones separated by walls of insulating material.

The disclosed techniques relate to methods and apparatus for etching a substrate. A plate assembly divides a reaction chamber into a lower and upper sub-chamber. The plate assembly includes an upper and lower plate having apertures therethrough. When the apertures in the upper and lower plates are aligned, ions and neutral species may travel through the plate assembly into the lower sub-chamber. When the apertures are not aligned, ions are prevented from passing through the assembly while neutral species are much less affected. Thus, the ratio of ion flux:neutral flux may be tuned by controlling the amount of area over which the apertures are aligned. In certain embodiments, one plate of the plate assembly is implemented as a series of concentric, independently movable injection control rings. Further, in some embodiments, the upper sub-chamber is implemented as a series of concentric plasma zones separated by walls of insulating material.

The invention relates in particular to a method for creating patterns in a layer (410) to be etched, starting from a stack comprising at least the layer (410) to be etched and a masking, layer (420) on top of the layer (410) to be etched, the masking layer (420) having at least one pattern (421), the method comprising at least; a) a step of modifying at least one zone (411) of the layer (410) to be etched via ion implantation (430) vertically in line with said at least one pattern (421); b) at least one sequence of steps comprising: b1) a step of enlarging (440) the at least one pattern (421) in a plane in which the layer (410) to be etched mainly extends; b2) a step of modifying at least one zone (411″, 411″) of the layer (410) to be etched via ion implantation (430) vertically in line with the at least one enlarged pattern (421), the implantation being carried out over a depth less than the implantation depth of the preceding, modification step;) c) a step of removing (461, 462) the modified zones (411, 411′, 41″), the removal comprising a step of etching the modified zones (411, 411′, 411″) selectively with respect to the non-modified zones (412) of the layer (410) to be etched.

Technologies for selectively etching oxide and nitride materials on a work piece are described. Such technologies include methods for etching a work piece with a remote plasma that is produced by igniting a plasma gas flow. By controlling the flow rate of various components of the plasma gas flow, plasmas exhibiting desired etching characteristics may be obtained. Such plasmas may be used in single or multistep etching operations, such as recess etching operations that may be used in the production of non-planar microelectronic devices.

Technologies for selectively etching oxide and nitride materials on a work piece are described. Such technologies include methods for etching a work piece with a remote plasma that is produced by igniting a plasma gas flow. By controlling the flow rate of various components of the plasma gas flow, plasmas exhibiting desired etching characteristics may be obtained. Such plasmas may be used in single or multistep etching operations, such as recess etching operations that may be used in the production of non-planar microelectronic devices.

In an aspect, a system and method for assembling a semiconductor device on a receiving surface of a destination substrate is disclosed. In another aspect, a system and method for assembling a semiconductor device on a destination substrate with topographic features is disclosed. In another aspect, a gravity-assisted separation system and method for printing semiconductor device is disclosed. In another aspect, various features of a transfer device for printing semiconductor devices are disclosed.

In an aspect, a system and method for assembling a semiconductor device on a receiving surface of a destination substrate is disclosed. In another aspect, a system and method for assembling a semiconductor device on a destination substrate with topographic features is disclosed. In another aspect, a gravity-assisted separation system and method for printing semiconductor device is disclosed. In another aspect, various features of a transfer device for printing semiconductor devices are disclosed.

A method is for detecting a condition associated with a final phase of a plasma dicing process. The method includes providing a non-metallic substrate having a plurality of dicing lanes defined thereon, plasma etching through the substrate along the dicing lanes, wherein during the plasma etching infrared emission emanating from at least a portion of the dicing lanes is monitored so that an increase in infrared emission from the dicing lanes is observed as the final phase of the plasma dicing operation is entered, and detecting the condition associated with the final phase of the plasma dicing from the monitored infrared emission.