An interconnect structure and a method of forming the interconnect structure are provided. A dielectric layer and openings therein are formed over a substrate. A conductive seed layer is formed over the top surface and along a bottom and sidewalls of the openings. A conductive fill layer is formed over the seed layer. Metal oxide on the surface of the seed layer may be reduced/removed by a surface pre-treatment. The cleaned surface is covered by depositing fill material over the seed layer without exposing the surface to oxygen. The surface treatment may include a reactive remote plasma clean using hydrogen radicals. If electroplating is used to deposit the fill layer, then the surface treatment may include soaking the substrate in the electrolyte before turning on the electroplating current. Other surface treatments may include active pre-clean (APC) using hydrogen radicals; or Ar sputtering using a metal clean version xT (MCxT) tool.

Techniques for dielectric damage-free interconnects are provided. In one aspect, a method for forming a Cu interconnect structure includes: forming a via and trench in a dielectric over a metal line M1; depositing a first barrier layer into the via and trench; removing the first barrier layer from the via and trench bottoms using neutral beam oxidation, and removing oxidized portions of the first barrier layer such that the first barrier layer remains along only sidewalls of the via and trench; depositing Cu into the via in direct contact with the metal line M1 to form a via V1; lining the trench with a second barrier layer; and depositing Cu into the trench to form a metal line M2. The second barrier layer can instead include Mn or optionally CuMn so as to further serve as a seed layer. A Cu interconnect structure is also provided.

In one embodiment of the present disclosure, a microfeature workpiece includes at least two features of two different sizes disposed in a dielectric, wherein a width of a first feature is less than or equal to 17 nm and wherein the first feature is filled with cobalt or nickel, and wherein a width of a second feature is greater than 20 nm and wherein the second feature is filled with a stack layer of cobalt or nickel and copper.

A method of forming an integrated circuit structure includes forming an etch stop layer over a conductive feature, forming a dielectric layer over the etch stop layer, forming an opening in the dielectric layer to reveal the etch stop layer, and etching the etch stop layer through the opening using an etchant comprising an inhibitor. An inhibitor film comprising the inhibitor is formed on the conductive feature. The method further includes depositing a conductive barrier layer extending into the opening, performing a treatment to remove the inhibitor film after the conductive barrier layer is deposited, and depositing a conductive material to fill a remaining portion of the opening.

An interconnect structure and a method of forming the interconnect structure are provided. A dielectric layer and openings therein are formed over a substrate. A conductive seed layer is formed over the top surface and along a bottom and sidewalls of the openings. A conductive fill layer is formed over the seed layer. Metal oxide on the surface of the seed layer may be reduced/removed by a surface pre-treatment. The cleaned surface is covered by depositing fill material over the seed layer without exposing the surface to oxygen. The surface treatment may include a reactive remote plasma clean using hydrogen radicals. If electroplating is used to deposit the fill layer, then the surface treatment may include soaking the substrate in the electrolyte before turning on the electroplating current. Other surface treatments may include active pre-clean (APC) using hydrogen radicals; or Ar sputtering using a metal clean version xT (MCxT) tool.

Embodiments described herein relate generally to one or more methods for forming a barrier layer for a conductive feature in semiconductor processing. In some embodiments, an opening is formed through a dielectric layer to a conductive feature. A barrier layer is formed in the opening along a sidewall of the dielectric layer and on a surface of the conductive feature. Forming the barrier layer includes depositing a layer including using a precursor gas. The precursor gas has a first incubation time for deposition on the surface of the conductive feature and has a second incubation time for deposition on the sidewall of the dielectric layer. The first incubation time is greater than the second incubation time. A conductive fill material is formed in the opening and on the barrier layer.

Embodiments described herein relate generally to one or more methods for forming a barrier layer for a conductive feature in semiconductor processing. In some embodiments, an opening is formed through a dielectric layer to a conductive feature. A barrier layer is formed in the opening along a sidewall of the dielectric layer and on a surface of the conductive feature. Forming the barrier layer includes depositing a layer including using a precursor gas. The precursor gas has a first incubation time for deposition on the surface of the conductive feature and has a second incubation time for deposition on the sidewall of the dielectric layer. The first incubation time is greater than the second incubation time. A conductive fill material is formed in the opening and on the barrier layer.

A back surface of a wafer is formed with a ring-shaped projecting portion. The wafer is cut with a blade from a side of a front surface of the wafer in a state where the projecting portion of the wafer with a back surface facing upward is supported.

Described herein are methods of filling features with tungsten, and related systems and apparatus, involving inhibition of tungsten nucleation. In some embodiments, the methods involve selective inhibition along a feature profile. Methods of selectively inhibiting tungsten nucleation can include exposing the feature to a direct or remote plasma. The methods include performing multi-stage inhibition treatments including intervals between stages. One or more of plasma source power, substrate bias power, or treatment gas flow may be reduced or turned off during an interval. The methods described herein can be used to fill vertical features, such as in tungsten vias, and horizontal features, such as vertical NAND (VNAND) wordlines. The methods may be used for both conformal fill and bottom-up/inside-out fill. Examples of applications include logic and memory contact fill, DRAM buried wordline fill, vertically integrated memory gate and wordline fill, and 3-D integration using through-silicon vias.

Embodiments of the invention include a microelectronic device that includes a substrate having a layer of dielectric material that includes a feature with a depression, a Tungsten containing barrier liner layer formed in the depression of the feature, and a Cobalt conductive layer deposited on the Tungsten containing barrier liner layer in the depression of the feature. The Tungsten containing barrier liner layer provides adhesion for the Cobalt conductive layer.