The present disclosure describes a method for forming capping layers configured to prevent the migration of out-diffused cobalt atoms into upper metallization layers In some embodiments, the method includes depositing a cobalt diffusion barrier layer on a liner-free conductive structure that includes ruthenium, where depositing the cobalt diffusion barrier layer includes forming the cobalt diffusion barrier layer self-aligned to the liner-free conductive structure. The method also includes depositing, on the cobalt diffusion barrier layer, a stack with an etch stop layer and dielectric layer, and forming an opening in the stack to expose the cobalt diffusion barrier layer. Finally, the method includes forming a conductive structure on the cobalt diffusion barrier layer.

Integrated circuit structures including an interconnect feature without a higher-resistance liner material. In absence of a liner, metal of low resistance directly contacts an adjacent dielectric material, enabling lower resistance interconnect. Even for low-k dielectric compositions, adhesion of the metal to the dielectric material is improved through the incorporation of nitrogen proximal to the interface. Prior to deposition of the metal upon a surface of the dielectric, the surface is exposed to nitrogen species to form a nitrogen-rich compound at the surface. The metal deposited upon the surface may then be nitrogen-lean, for example a substantially pure elemental metal or metal alloy.

A fin field effect transistor device structure includes a fin structure formed over a substrate. The fin field effect transistor device structure also includes a source/drain epitaxial structure formed over the fin structure. The fin field effect transistor device structure also includes a contact structure with a concave top surface formed over the source/drain epitaxial structure. The fin field effect transistor device structure also includes a barrier layer conformally wrapped around the contact structure. The fin field effect transistor device structure also includes a via structure formed over the contact structure. The concave top surface of the contact structure is below the top surface of the barrier layer.

A method for transferring a plurality of die operatively associated with a transfer apparatus to a glass substrate to form a circuit component. The transfer occurs by positioning the glass substrate to face a first surface of a die carrier carrying multiple die. A reciprocating transfer member thrusts against a second surface of the die carrier to actuate the transfer member thereby causing a localized deflection of the die carrier in a direction of the surface of the glass substrate to position an initial die proximate to the glass substrate. The initial die transfers directly to a circuit trace on the glass substrate. At least one of the die carrier or the transfer member is then shifted such that the transfer member aligns with a subsequent die on the first surface of the die carrier. The acts of actuating, transferring, and shifting are repeated to effectuate a transfer of the multiple die onto the glass substrate.

A device includes a substrate having a top surface, a fin extending lengthwise along a first direction, a source feature and a drain feature, a gate structure having a gate stack extending along a second direction perpendicular to the first direction and interposing between the source and drain features, a gate via directly disposed on the gate stack, a source via electrically connecting the source feature, and a drain via electrically connecting the drain feature. The fin includes a stack of channel layers engaged by the gate stack. The source via has a first dimension along the second direction and a second dimension along the first direction, the drain via feature has a third dimension along the second direction and a fourth dimension along the first direction. A ratio of the first dimension to the second dimension is greater than a ratio of the third dimension to the fourth dimension.

Methods of depositing platinum group metal films of high purity, low resistivity, and good conformality are described. A platinum group metal film is formed in the absence of an oxidant. The platinum group metal film is selectively deposited on a conductive substrate at a temperature less than 200° C. by using an organic platinum group metal precursor.

Methods for forming conductive lines and integrated chips include forming a mandrel on an etch stop layer. First spacers are formed on sidewalls of the mandrel. The mandrel is etched away. Conductive lines are formed on sidewalls of the first spacers. The first spacers are etched away. Dielectric spacers are formed between the conductive lines.

An interconnection structure includes a first dielectric layer, a first conductive feature, a second dielectric layer, a conductive layer, a liner layer, a third dielectric layer, a second conductive feature, and a first capping layer. The first conductive feature is disposed in the first dielectric layer. The second dielectric layer is formed on the first dielectric layer, and the second dielectric layer is in direct contact with the first dielectric layer. The conductive layer is disposed in the second dielectric layer. The liner layer is disposed between the conductive layer and the second dielectric layer. The third dielectric layer is formed on the second dielectric layer. The second conductive feature is disposed in the third dielectric layer. The first capping layer is disposed between the second conductive feature and the third dielectric layer.

A semiconductor device includes a gate structure disposed in a first dielectric layer, a conductive segment disposed in the first dielectric layer and separated from the gate structure, a second dielectric layer disposed over the first dielectric layer, a first contact penetrating the second dielectric layer and electrically connected to the gate structure, a second contact penetrating the second dielectric layer and electrically connected to the conductive segment, and a silicon nitride-based layer surrounding at least one of the first and second contacts and connected between the second dielectric layer and the at least one of the first and second contacts. A method for making the semiconductor device is also provided.

A semiconductor structure is disclosed. The semiconductor structure includes a staircase structure disposed over a substrate. The staircase structure includes a plurality of layer stacks, where each layer stack is made of a first material layer over a portion of a second material layer. The staircase structure further includes a plurality of landing pads, where each landing pad is disposed over another portion of the second material layer of a respective layer stack.