A method is provided for forming a metal contact plug. In one step, a substrate, which is an Si substrate or an SiO.sub.2 substrate, is etched to form a contact hole. In one step, a dielectric liner layer is formed on a sidewall of the contact hole. In one step, the metal contact plug that is in contact with the dielectric liner layer is formed in the contact hole. In one step, an implantation process is performed on the substrate, so as to implant dopants having an atomic size greater than that of Si into the substrate.

A semiconductor device and method of manufacture are provided which utilize a remote plasma process which reduces or eliminates segregation of material. By reducing segregation of the material, overlying conductive material can be deposited on a smoother interface. By depositing on smoother interfaces, overall losses of the deposited material may be avoided, which improves the overall yield.

Some embodiments include a method of forming an integrated assembly. A stack of alternating first and second materials is formed over a conductive structure. The conductive structure includes a semiconductor-containing material over a metal-containing material. An opening is formed to extend through the stack and through the semiconductor-containing material, to expose the metal-containing material. The semiconductor-containing material is doped with carbon and/or with one or more metals. After the doping of the semiconductor-containing material, the second material of the stack is removed to form voids. Conductive material is formed within the voids. Insulative material is formed within the opening. Some embodiments include integrated assemblies having carbon distributed within at least a portion of a semiconductor material.

A microelectronic device may have side surfaces each including a first portion and a second portion. The first portion may have a highly irregular surface topography extending from an adjacent surface of the microelectronic device. The second portion may have a less uneven surface extending from the first portion to an opposing surface of the microelectronic device. Methods of forming the microelectronic device may include creating dislocations in the wafer in a street between the one or more microelectronic devices by implanting ions and cleaving the wafer responsive to failure of stress concentrations near the dislocations through application of heat, tensile forces or a combination thereof. Related packages and methods are also disclosed.

A semiconductor structure is provided that contains a non-volatile battery which controls gate bias and has increased output voltage retention and voltage resolution. The semiconductor structure may include a semiconductor substrate including at least one channel region that is positioned between source/drain regions. A gate dielectric material is located on the channel region of the semiconductor substrate. A battery stack is located on the gate dielectric material. The battery stack includes, a cathode current collector located on the gate dielectric material, a cathode material located on the cathode current collector, a first ion diffusion barrier material located on the cathode material, an electrolyte located on the first ion diffusion barrier material, a second ion diffusion barrier material located on the electrolyte, an anode region located on the second ion diffusion barrier material, and an anode current collector located on the anode region.

A method for making a semiconductor device may include forming a trench in a semiconductor substrate, and forming a superlattice liner covering bottom and sidewall portions of the trench. The superlattice liner may include a plurality of stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The method may further include forming a semiconductor cap layer on the superlattice liner and having a dopant constrained therein by the superlattice liner, and forming a conductive body within the trench.

Described are methods for forming a multilayer conductive structure for semiconductor devices. A seed layer is formed comprising a metal and an additional constituent that in combination with the metal inhibits nucleation of a fill layer of the metal formed over the seed layer. Tungsten may be doped or alloyed with silicon to form the seed layer, with a tungsten fill being formed over the seed layer.

A semiconductor device may include a semiconductor substrate having a trench therein, and a superlattice liner at least partially covering bottom and sidewall portions of the trench. The superlattice liner may include a plurality of stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The semiconductor device may further include a semiconductor cap layer on the superlattice liner and having a dopant constrained therein by the superlattice liner, and a conductive body within the trench.

In one implementation, a method of forming a cobalt layer on a substrate is provided. The method comprises forming a barrier and/or liner layer on a substrate having a feature definition formed in a first surface of the substrate, wherein the barrier and/or liner layer is formed on a sidewall and bottom surface of the feature definition. The method further comprises exposing the substrate to a ruthenium precursor to form a ruthenium-containing layer on the barrier and/or liner layer. The method further comprises exposing the substrate to a cobalt precursor to form a cobalt seed layer atop the ruthenium-containing layer. The method further comprises forming a bulk cobalt layer on the cobalt seed layer to fill the feature definition.

Described are methods for forming a multilayer conductive structure for semiconductor devices. A seed layer is formed comprising a metal and an additional constituent that in combination with the metal inhibits nucleation of a fill layer of the metal formed over the seed layer. Tungsten may be doped or alloyed with silicon to form the seed layer, with a tungsten fill being formed over the seed layer.