In a method of patterning an integrated circuit, test layer thickness variation data is received when a test layer with a known thickness disposed over a test substrate undergoes tilted angle plasma etching. Overlay offset data per substrate locations caused by the tilted angle plasma etching is determined. The overlay offset data is determined based on the received thickness variation data. The overlay offset data is associated with an overlay between first circuit patterns of a first layer on the semiconductor substrate and corresponding second circuit patterns of a second layer disposed over the first layer on the substrate. A location of the substrate is adjusted based on the overlay offset data during a lithography operation to pattern a resist layer over the second layer. The second layer is patterned based on the projected layout patterns of the reticle and using the tilted angle plasma etching.

A method of processing a substrate that includes: loading the substrate having a raised feature with at least two sidewalls exposed in a processing chamber; depositing a first layer over the substrate to cover a first portion of the two sidewalls; depositing a second layer over the first layer to cover a second portion of the two sidewalls; depositing a third layer over the second layer and the raised feature to cover a third portion of the sidewalls and a top surface of the raised feature; performing an anisotropic dry etching that removes portions of the second layer and the third layer, a remainder of the second layer forming a second sidewall spacer and a remainder of the third layer forming a third sidewall spacer; and performing an isotropic etching that selectively removes the second sidewall spacer to expose portions of the sidewalls of the raised feature.

Semiconductor structures and fabrication methods are provided. An exemplary fabrication method includes providing a to-be-etched layer; forming a first sacrificial film on the to-be-etched layer; and forming a plurality of discrete first sidewall spacers and sidewall trenches on the first sacrificial film. Each sidewall trench is located between two adjacent first sidewall spacers; the first sidewall trenches include a first sidewall trench and a second sidewall trench, and a width of the second sidewall trench is greater than that of the first sidewall trench. The method also includes forming a second sidewall spacer in the first sidewall trench to fill the first sidewall trench; and etching the first sacrificial film using the first sidewall spacers and the second sidewall spacer as an etching mask to form a plurality of discrete first sacrificial layers on the to-be-etched layer.

The present application relates to a semiconductor fin structure cut process. The process includes: providing a semiconductor substrate and forming a plurality of fin structures on the semiconductor substrate, a gap being formed between every two adjacent fin structures; depositing a first dielectric layer, the first dielectric layer being filled in the gaps so that all fin structures are connected into a whole to form a semiconductor with fins; forming a plurality of pattern layer strips on the semiconductor with fins, a groove being formed between every two adjacent pattern layer strips, the fin structures closest to each pattern layer strip in the semiconductor with fins being necessary fin structures, attaching mask strips onto side surfaces of each pattern layer strip, the mask strips covering the necessary fin structures; etching the semiconductor with fins so that the unnecessary fin structures not covered by the mask strips are truncated.

Among other things, one or semiconductor arrangements, and techniques for forming such semiconductor arrangements are provided. An etch sequence is performed to form a first etched region over a planar region of a semiconductor arrangement. The first etched region exposes a planar structure, such as an alignment mark used for alignment during semiconductor fabrication. The etch sequence forms a second etched region over a semiconductor fin region of the semiconductor arrangement. In an embodiment, the etch sequence forms a first trench, a first fin nub and a first pillar in the semiconductor fin region, where the first trench is formed in a semiconductor substrate of the semiconductor fin region. A multi-depth STI structure is formed over at least one of the first trench, the first fin nub, or the first pillar.

A fabricating method of a high electron mobility transistor includes providing a substrate. Then, a channel layer, an active layer, a P-type group III-V compound material layer, a metal compound material layer, a hard mask material layer and a patterned photoresist are formed to cover the substrate. Later, a dry etching process is performed to etch the hard mask material layer and the metal compound material layer to form a hard mask and a metal compound layer by taking the patterned photoresist as a mask. During the dry etching process, a spacer generated by by-products is formed to surround the patterned photoresist, the hard mask and the metal compound layer. After the dry etching process, the P-type group III-V compound material layer is etched by taking the spacer and the patterned photoresist as a mask.

Representative implementations of techniques and methods include processing singulated dies in preparation for bonding. A plurality of semiconductor die components may be singulated from a wafer component, the semiconductor die components each having a substantially planar surface. Particles and shards of material may be removed from edges of the plurality of semiconductor die component. Additionally, one or more of the plurality of semiconductor die components may be bonded to a prepared bonding surface, via the substantially planar surface.

The present disclosure relates to plasma dicing of wafer. More specifically, the present disclosure is directed to frame masks and methods for plasma dicing wafers utilizing frame masks. The frame mask includes a mask frame, wherein the mask frame includes a top ring mask support and a side ring mask support. A plurality of mask segments suspended from the top ring mask support by segment supports, the mask segments are configured to define dicing channels on a blank wafer. The frame mask is configured to removably sit onto a frame lift assembly in a plasma chamber of a plasma dicing tool, when fitted onto the frame lift assembly, the mask segments are disposed above a wafer on a wafer ring frame for plasma dicing. The mask frame is configured to enable flow of plasma therethrough to the wafer to etch the wafer to form dicing channels defined by the mask segments.

A method for cutting off a fin in a field effect transistor, comprising: step 1: forming fins and first spacing regions, there are two types of fins—the first type is configured to be cut off and a second type is configured to be reserved; and forming a first material layer to fill the first spacing regions; step 2: forming a first pattern structure comprising first strip structures aligning to one first type fin and second spacing regions; step 3: forming second sidewalls on two sides of each first strip structure; step 4: removing the first strip structures to form a second pattern structure by the second sidewalls; step 5: etching away the first material layer and the first type of fins by using the second sidewalls as a mask ; step 6: removing the second sidewalls and the remaining first material layer. The present application enables using less advanced lithography equipment.

Techniques relate to a gate stack for a semiconductor device. A vertical fin is formed on a substrate. The vertical fin has an upper portion and a bottom portion. The upper portion of the vertical fin has a recessed portion on sides of the upper portion. A gate stack is formed in the recessed portion of the upper portion of the vertical fin.