Abstract: Embodiments of the invention address several issues and problems associated with etching of dielectric materials for BEOL applications. According to one embodiment, the method includes providing a patterned substrate containing a dielectric material, exposing the substrate to a gas phase plasma to functionalize a surface of the dielectric material, exposing the substrate to a silanizing reagent that reacts with the functionalized surface of the dielectric material to form a dielectric film, and sequentially repeating the exposing steps at least once to increase a thickness of the dielectric film. According to one embodiment, the dielectric material may be a porous low-k material, and the dielectric film seals the pores on a surface of the porous low-k material.

Abstract: A method for performing post-etch annealing of a workpiece in an annealing system is described. In particular, the method includes disposing one or more workpieces in an annealing system, each of the one or more workpieces having a multilayer stack of thin films that has been patterned using an etching process sequence to form an electronic device characterized by a cell critical dimension (CD), wherein the multilayer stack of thin films includes at least one patterned layer containing magnetic material. Thereafter, the patterned layer containing magnetic material on the one or more workpieces is annealed in the annealing system via an anneal process condition, wherein the anneal process condition is selected to adjust a property of the patterned layer containing magnetic material.

Abstract: A method for producing fin structures, using Directed Self Assembly (DSA) lithographic patterning, in an area of a semiconductor substrate includes providing a semiconductor substrate covered with a shallow trench isolation (STI) layer stack on a side thereof; defining a fin area on that side of the substrate by performing a lithographic patterning step other than DSA, wherein the fin structures will be produced in the fin area; and producing the fin structures in the semiconductor substrate within the fin area according to a predetermined fin pattern using DSA lithographic patterning. The disclosure also relates to associated semiconductor structures.

Abstract: Embodiments of the invention address several issues and problems associated with etching of dielectric materials for BEOL applications. According to one embodiment, the method includes providing a patterned substrate containing a dielectric material, exposing the substrate to a gas phase plasma to functionalize a surface of the dielectric material, exposing the substrate to a silanizing reagent that reacts with the functionalized surface of the dielectric material to form a dielectric film, and sequentially repeating the exposing steps at least once to increase a thickness of the dielectric film. According to one embodiment, the dielectric material may be a porous low-k material, and the dielectric film seals the pores on a surface of the porous low-k material.

Abstract: A method for producing fin structures, using Directed Self Assembly (DSA) lithographic patterning, in an area of a semiconductor substrate includes providing a semiconductor substrate covered with a shallow trench isolation (STI) layer stack on a side thereof; defining a fin area on that side of the substrate by performing a lithographic patterning step other than DSA, wherein the fin structures will be produced in the fin area; and producing the fin structures in the semiconductor substrate within the fin area according to a predetermined fin pattern using DSA lithographic patterning. The disclosure also relates to associated semiconductor structures.

Abstract: A method for producing fin structures, using Directed Self Assembly (DSA) lithographic patterning, in an area of a semiconductor substrate includes providing a semiconductor substrate covered with a shallow trench isolation (STI) layer stack on a side thereof; defining a fin area on that side of the substrate by performing a lithographic patterning step other than DSA, wherein the fin structures will be produced in the fin area; and producing the fin structures in the semiconductor substrate within the fin area according to a predetermined fin pattern using DSA lithographic patterning. The disclosure also relates to associated semiconductor structures.

Abstract: A method for producing fin structures, using Directed Self Assembly (DSA) lithographic patterning, in an area of a semiconductor substrate includes providing a semiconductor substrate covered with a shallow trench isolation (STI) layer stack on a side thereof; defining a fin area on that side of the substrate by performing a lithographic patterning step other than DSA, wherein the fin structures will be produced in the fin area; and producing the fin structures in the semiconductor substrate within the fin area according to a predetermined fin pattern using DSA lithographic patterning. The disclosure also relates to associated semiconductor structures.

Abstract: A method for performing post-etch annealing of a workpiece in an annealing system is described. In particular, the method includes disposing one or more workpieces in an annealing system, each of the one or more workpieces having a multilayer stack of thin films that has been patterned using an etching process sequence to form an electronic device characterized by a cell critical dimension (CD), wherein the multilayer stack of thin films includes at least one patterned layer containing magnetic material. Thereafter, the patterned layer containing magnetic material on the one or more workpieces is annealed in the annealing system via an anneal process condition, wherein the anneal process condition is selected to adjust a property of the patterned layer containing magnetic material.