A method of forming a redistribution structure includes providing a dielectric layer. The dielectric layer is patterned to form a plurality of via openings. A seed layer is formed on the dielectric layer and filling in the plurality of via openings. A patterned conductive layer is formed a on the seed layer, wherein a portion of the seed layer is exposed by the patterned conductive layer. The portion of the seed layer is removed by using an etching solution, thereby forming a plurality of conductive lines and a plurality of vias. During the removing the portion of the seed layer, an etch rate of the patterned conductive layer is less than an etch rate of the seed layer.

A manufacturing method of a semiconductor structure includes the following operations. A substrate is provided, which includes a first N region, a first P region, a second N region and a second P region adjacently arranged in sequence. A gate dielectric layer, a first barrier layer, a first work function layer and a second barrier layer are formed on the substrate in sequence. A mask layer is formed on the second barrier layer of the first P region and the second P region. The second barrier layer of the first N region and the second N region is removed by a first etching process with the mask layer as a mask. The first work function layer and the first barrier layer of the first N region and the second N region are removed by a second etching process. A semiconductor structure is also provided.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary method of manufacture comprises receiving a substrate including a semiconductor material stack formed thereon, wherein the semiconductor material stack includes a first semiconductor layer of a first semiconductor material and second semiconductor layer of a second semiconductor material that is different than the first semiconductor material. Patterning the semiconductor material stack to form a trench. The patterning includes performing a first etch process with a first etchant for a first duration and then performing a second etch process with a second etchant for a second duration, where the second etchant is different from the first etchant and the second duration is greater than the first duration. The first etch process and the second etch process are repeated a number of times. Then epitaxially growing a third semiconductor layer of the first semiconductor material on a sidewall of the trench.

Provided is a method for processing a substrate having a metal formed on a planned dividing line along the planned dividing line, the method including a processed groove forming step of forming a processed groove in the substrate along the planned dividing line, and a burr removing step of, after the processed groove forming step is performed, making an etchant that includes at least an oxidizing agent and to which an ultrasonic vibration is imparted come into contact with the substrate, suppressing ductility of a metallic burr generated on a periphery of the formed processed groove and increasing fragility of the burr by modifying the burr by the oxidizing agent included in the etchant, and removing the burr by the ultrasonic vibration.

A method for fabricating a semiconductor device includes: forming a first gate dielectric layer in a first and a second regions of a peripheral region of a substrate; forming a first conductive layer and a first hard mask layer over the substrate; forming a first mask layer on the first hard mask layer in the first region; removing the first hard mask layer outside the first region; removing the first hard mask layer; performing a wet etch process by taking the first hard mask layer as a mask, and removing the first conductive layer and the first gate dielectric layer outside the first region; removing the first hard mask layer and the first conductive layer; forming a second gate dielectric layer in the second region; and forming a first and a second gate conductive layers in the first and the second regions respectively.

The present invention relates to compositions and methods for selectively etching silicon nitride in the presence of silicon oxide, polysilicon and/or metal silicides at a high etch rate and with high selectivity. Additives are described that can be used at various dissolved silica loading windows to provide and maintain the high selective etch rate and selectivity.

A connecting structure includes a substrate, a first conductive feature, a second conductive feature, a third conductive feature over the first conductive feature and a fourth conductive feature over the second conductive feature. The substrate includes a first region and a second region. The first conductive feature is disposed in the first region and has a first width. The second conductive feature is disposed in the second region and has a second width greater than the first width of the first conductive feature. The third conductive feature includes a first anchor portion surrounded by the first conductive feature. The fourth conductive feature includes a second anchor portion surrounded by the second conductive feature. A depth difference ratio between a depth of the first anchor portion and a depth of the second anchor portion is less than approximately 10%.

Described herein is an etching solution suitable for both tungsten-containing metals and TiN-containing materials, which comprises: water; and one or more than one oxidizers; and one or more than one of the components selected from the group consisting of: one or more fluorine-containing-etching compounds, one or more organic solvents, one or more chelating agents, one or more corrosion inhibitors and one or more surfactants.

This disclosure relates to etching compositions containing 1) at least one oxidizing agent; 2) at least one chelating agent; 3) at least one organic solvent; 4) at least one amine compound; and 5) water.

Vias, along with methods for fabricating vias, are disclosed that exhibit reduced capacitance and resistance. An exemplary interconnect structure includes a first source/drain contact and a second source/drain contact disposed in a dielectric layer. The first source/drain contact physically contacts a first source/drain feature and the second source/drain contact physically contacts a second source/drain feature. A first via having a first via layer configuration, a second via having a second via layer configuration, and a third via having a third via layer configuration are disposed in the dielectric layer. The first via and the second via extend into and physically contact the first source/drain contact and the second source/drain contact, respectively. A first thickness of the first via and a second thickness of the second via are the same. The third via physically contacts a gate structure, which is disposed between the first source/drain contact and the second source/drain contact.