Abstract: A semiconductor memory device is provided, and which includes a substrate, plural gates, plural plugs, a capacitor structure and a conducting cap layer. The gates are disposed within the substrate, and the plugs are disposed on the substrate, with each plug electrically connected to two sides of each gate on the substrate. The capacitor structure is disposed on the substrate, and the capacitor structure includes plural capacitors, with each capacitor electrically connected to the plugs respectively. The conducting cap layer covers the top surface and sidewalls of the capacitor structure. Also, the semiconductor memory device further includes an adhesion layer and an insulating layer. The adhesion layer covers the conducting cap layer and the capacitor structure, and the insulating layer covers the adhesion layer.

Abstract: A method of forming a semiconductor structure includes providing a material layer having a recess formed therein. A first tungsten metal layer is formed at a first temperature and fills the recess. An anneal process at a second temperature is then performed, wherein the second temperature is higher than the first temperature.

Abstract: A semiconductor structure for preventing row hammering issue in DRAM cell is provided in the present invention. The structure includes a trench with a gate dielectric, an n-type work function metal layer, a TiN layer conformally formed within, and a buried word line filled in the trench.

Abstract: The present invention provides a storage node contact structure of a memory device comprising a substrate having a dielectric layer comprising a recess, a first tungsten metal layer, and an adhesive layer on the first tungsten metal layer and a second tungsten metal layer on the adhesive layer, wherein the second tungsten metal layer is formed by a physical vapor deposition (PVD).

Abstract: A semiconductor structure for preventing row hammering issue in DRAM cell is provided in the present invention. The structure includes a trench with a gate dielectric, an n-type work function metal layer, a TiN layer conformally formed within, and a buried word line filled in the trench.

Abstract: A method for manufacturing a semiconductor device with a cobalt silicide film is provided in the present invention. The method includes the steps of providing a silicon structure with an interlayer dielectric formed thereon, forming a contact hole in the interlayer dielectric to expose the silicon structure, depositing a cobalt film on the exposed silicon structure at a temperature between 300° C-400° C., wherein a cobalt protecting film is in-situ formed on the surface of the cobalt film, performing a rapid thermal process to transform the cobalt film into a cobalt silicide film, and removing untransformed cobalt film.

Abstract: A method of forming a bit line gate structure of a dynamic random access memory (DRAM) includes the following. A hard mask layer is formed on a metal stack by a chemical vapor deposition process importing nitrogen (N2) gases and then importing amonia (NH3) gases. The present invention also provides a bit line gate structure of a dynamic random access memory (DRAM) including a metal stack and a hard mask. The metal stack includes a polysilicon layer, a titanium layer, a titanium nitride layer, a first tungsten nitride layer, a tungsten layer and a second tungsten nitride layer stacked from bottom to top. The hard mask is disposed on the metal stack.

Abstract: A method for fabricating semiconductor device includes the steps of: forming a shallow trench isolation (STI) in a substrate; removing part of the STI to form a first trench; forming a cap layer in the first trench; forming a mask layer on the cap layer and the substrate; and removing part of the mask layer, part of the cap layer, and part of the STI to form a second trench.

Abstract: A method for fabricating a semiconductor device is disclosed. A substrate having a conductive region is provided. A metal layer is deposited on the conductive region. The metal layer reacts with the conductive region to form a first metal silicide layer. A TiN layer is deposited on the metal layer. A SiN layer is deposited on the TiN layer. An annealing process is performed to convert the first metal silicide layer into a second metal silicide layer.

Abstract: A dynamic random access memory (DRAM) device includes a substrate, plural buried gates and plural bit lines. The buried gates are disposed in the substrate along a first trench extending along a first direction. The bit lines are disposed over the buried gates and extending along a second direction across the first direction. Each of the bit lines includes a multi-composition barrier layer, wherein the multi-composition barrier layer includes WSixNy with x and y being greater than 0 and the multi-composition barrier layer is silicon-rich at a bottom portion thereof and is nitrogen-rich at a top portion thereof.

Abstract: A dynamic random access memory (DRAM) device includes a substrate, plural word lines and plural bit lines. The word lines are disposed in the substrate along a first trench extending along a first direction. Each of the word lines includes a multi-composition barrier layer, wherein the multi-composition barrier layer includes TiSixNy with x and y being greater than 0 and the multi-composition barrier layer is silicon-rich at a bottom portion thereof and is nitrogen-rich at a top portion thereof. The bit lines are disposed over the word lines and extended along a second direction across the first direction.

Abstract: A manufacturing method of a metal gate structure includes the following steps. First, a substrate covered by an interlayer dielectric is provided. A gate trench is formed in the interlayer dielectric, wherein a gate dielectric layer is formed in the gate trench. A silicon-containing work function layer is formed on the gate dielectric layer in the gate trench. The silicon-containing work function layer includes a vertical portion and a horizontal portion. Finally, the gate trench is filled up with a conductive metal layer.

Abstract: A manufacturing method of a metal gate structure is provided. First, a substrate covered by an interlayer dielectric is provided. A gate trench is formed in the interlayer dielectric, wherein a gate dielectric layer is formed in the gate trench. A silicon-containing work function layer is formed on the gate dielectric layer in the gate trench. Finally, the gate trench is filled up with a conductive metal layer.

Abstract: A semiconductor device includes an opening, a metal nitride layer, a bilayer metal layer and a conductive bulk layer. The opening is disposed in a first dielectric layer. The metal nitride layer is disposed in the opening. The bilayer metal layer is disposed on the metal nitride layer in the opening, where the bilayer metal layer includes a first metal layer and a second metal layer which is disposed on the first metal layer and has a greater metal concentration than that of the first metal layer. The conductive bulk layer is filled in the opening.

Abstract: An electrical chemical plating process is provided. A semiconductor structure is provided in an electrical plating platform. A pre-electrical-plating step is performed wherein the pre-electrical-plating step is carried out under a fixed voltage environment and lasts for 0.2 to 0.5 seconds after the current is above the threshold current of the electrical plating platform. After the pre-electrical-plating step, a first electrical plating step is performed on the semiconductor structure.

Abstract: A semiconductor device includes an opening, a metal nitride layer, a bilayer metal layer and a conductive bulk layer. The opening is disposed in a first dielectric layer. The metal nitride layer is disposed in the opening. The bilayer metal layer is disposed on the metal nitride layer in the opening, where the bilayer metal layer includes a first metal layer and a second metal layer which is disposed on the first metal layer and has a greater metal concentration than that of the first metal layer. The conductive bulk layer is filled in the opening.

Abstract: An electrical chemical plating process is provided. A semiconductor structure is provided in an electrical plating platform. A pre-electrical-plating step is performed wherein the pre-electrical-plating step is carried out under a fixed voltage environment and lasts for 0.2 to 0.5 seconds after the current is above the threshold current of the electrical plating platform. After the pre-electrical-plating step, a first electrical plating step is performed on the semiconductor structure.

Abstract: A through silicon via structure is located in a recess of a substrate. The through silicon via structure includes a barrier layer, a buffer layer and a conductive layer. The barrier layer covers a surface of the recess. The buffer layer covers the barrier layer. The conductive layer is located on the buffer layer and fills the recess, wherein the contact surface between the conductive layer and the buffer layer is smoother than the contact surface between the buffer layer and the barrier layer. Moreover, a through silicon via process forming said through silicon via structure is also provided.

Abstract: A metal gate structure located on a substrate includes a gate dielectric layer, a metal layer and a titanium aluminum nitride metal layer. The gate dielectric layer is located on the substrate. The metal layer is located on the gate dielectric layer. The titanium aluminum nitride metal layer is located on the metal layer.

Abstract: A through silicon via structure is located in a recess of a substrate. The through silicon via structure includes a barrier layer, a buffer layer and a conductive layer. The barrier layer covers a surface of the recess. The buffer layer covers the barrier layer. The conductive layer is located on the buffer layer and fills the recess, wherein the contact surface between the conductive layer and the buffer layer is smoother than the contact surface between the buffer layer and the barrier layer. Moreover, a through silicon via process forming said through silicon via structure is also provided.