Methods of forming fins include masking a region on a three-color hardmask fin pattern, leaving a fin of a first color exposed. The exposed fin of the first color is etched away with a selective etch that does not remove fins of a second color or a third color. The mask and all fins of a second color are etched away. Fins are etched into a fin base layer using the fins of the first color and the fins of the third color.

A method for patterning a substrate in which a patterned photoresist structure can be formed on the substrate, the patterned photoresist structure having a sidewall. A conformal layer of spacer material can be deposited on the sidewall. The patterned photoresist structure can then be removed from the substrate, leaving behind the spacer material. Then, the substrate can be directionally etched using the sidewall spacer as an etch mask to form the substrate having a target critical dimension.

A method includes patterning a mandrel layer over a target layer to form first mandrels and second mandrels, the first mandrels having a larger width than the second mandrels. A spacer layer is formed over the first mandrels and the second mandrels, and altered so that a thickness of the spacer layer over the first mandrels is greater than a thickness of the spacer layer over the second mandrels. Spacers are formed from the spacer layer which have a greater width adjacent the first mandrels than the spacers which are adjacent the second mandrels. The spacers are used to etch a target layer.

The present application discloses a semiconductor device including a first isolation structure, a second isolation structure, and a third isolation structure disposed in a semiconductor substrate. The semiconductor device further includes a transistor and a resistor. The transistor is disposed between the first isolation structure and the second isolation structure, and includes a gate electrode and a first source/drain (S/D) region. The resistor is disposed between the second isolation structure and the third isolation structure, and includes a resistor electrode. The first S/D region is disposed between the gate electrode and the second isolation structure, and is electrically connected to the resistor electrode.

A method includes patterning a mandrel layer over a target layer to form first mandrels and second mandrels, the first mandrels having a larger width than the second mandrels. A spacer layer is formed over the first mandrels and the second mandrels, and altered so that a thickness of the spacer layer over the first mandrels is greater than a thickness of the spacer layer over the second mandrels. Spacers are formed from the spacer layer which have a greater width adjacent the first mandrels than the spacers which are adjacent the second mandrels. The spacers are used to etch a target layer.

A method of fabricating semiconductor fins, including, patterning a film stack to produce one or more sacrificial mandrels having sidewalls, exposing the sidewall on one side of the one or more sacrificial mandrels to an ion beam to make the exposed sidewall more susceptible to oxidation, oxidizing the opposite sidewalls of the one or more sacrificial mandrels to form a plurality of oxide pillars, removing the one or more sacrificial mandrels, forming spacers on opposite sides of each of the plurality of oxide pillars to produce a spacer pattern, removing the plurality of oxide pillars, and transferring the spacer pattern to the substrate to produce a plurality of fins.

The disclosure provides a method for manufacturing shallow trench isolations, providing a substrate comprising a storage cell area and a peripheral area of a storage device; etching the upper part of the substrate of the storage cell area using a first etching process to form a first shallow trench, and filling the first shallow trench with silicon oxide using a first deposition process; and etching the upper part of the substrate of the peripheral area using a second etching process to form a second shallow trench, and filling the second shallow trench with silicon oxide using a second deposition process; wherein the depth and characteristic dimension of the first shallow trench are smaller than the depth and characteristic dimension of the second shallow trench. The disclosure can avoid the silicon dislocation defect of the peripheral area and ensure the device shape and characteristic dimension of the storage cell area.

A method for patterning a substrate in which a patterned photoresist structure can be formed on the substrate, the patterned photoresist structure having a sidewall. A conformal layer of spacer material can be deposited on the sidewall. The patterned photoresist structure can then be removed from the substrate, leaving behind the spacer material. Then, the substrate can be directionally etched using the sidewall spacer as an etch mask to form the substrate having a target critical dimension.

A method for forming a patterned mask layer is provided. The method includes forming a layer over a substrate. The method includes forming a first strip structure and a second strip structure over the layer. The method includes forming a spacer layer over the first strip structure, the second strip structure, and the layer. The method includes forming a third strip structure and a fourth strip structure between the first strip part and the second strip part. The connecting part is between the third strip structure and the fourth strip structure. The method includes removing the spacer layer. The first strip structure, the second strip structure, the third strip structure, and the fourth strip structure together form a patterned mask layer.

A method for forming a semiconductor structure is provided. In one form, a method includes: providing a base, where the base includes first regions and a second region located between the first regions; forming a pattern definition layer on the base; forming discrete mask layers on the pattern definition layer, the mask layers and the base defining openings, where openings of the first regions serve as first openings, and an opening of the second region serves as a second opening; forming a filling layer in the second opening; and etching, using the mask layers and the filling layer as masks, the pattern definition layer exposed from the first openings, to form target patterns. In embodiments and implementations of this application, the filling layer is formed between the mask layers of the second region, to obtain a mask that finally etches the pattern definition layer, so that the formed target patterns meet process requirements, which is conducive to improving electrical performance of the semiconductor structure.