Abstract: An apparatus for chemical mechanical polishing includes a wafer carrier, a first electrode, a rotatable pedestal, a second electrode, and an electric current detector. The first electrode is disposed at the wafer carrier. The rotatable pedestal is positioned opposite to the wafer carrier in order to perform a polishing operation with the wafer carrier accordingly. The second electrode is disposed at the rotatable pedestal and electrically coupled to the first electrode in order to form a circuit loop. The electric current detector is between the first electrode and the second electrode.

Abstract: A method for manufacturing a metal gate structure includes forming a high-k dielectric layer in a gate trench; forming an etch stop over the high-k dielectric layer; forming a work function adjusting layer over the etch stop by forming a tri-layer by an atomic layer deposition (ALD) operation with a sequence of a grain boundary engineering layer configured to allow a dopant atom to penetrate there through, a doping layer configured to provide the dopant atom to the grain boundary engineering layer, and a capping layer configured to prevent the doping layer from oxidation; and filling metal to level up the gate trench. The grain boundary engineering layer is prepared by the ALD operation under various temperatures such as from about 200 to about 350 degrees Celsius.

Abstract: A composition for chemical mechanical polishing includes a plurality of particles and a plurality of abrasive particles. Each of the plurality of particles includes a body and a functional group. The body is configured to transfer energy of an incident light into a plasmonic wave. The functional group is configured to bind onto a metal containing layer.

Abstract: A method for fabricating a semiconductor structure is provided, including: providing a solid precursor having a first average particle size; solving the solid precursor in an organic solvent into an intermediate; recrystallizing the intermediate to form solid granules, wherein the solid granules has a second average particle size larger than the first average particle size; vaporizing the solid granules to form a film-forming gas; and depositing the film-forming gas on a substrate to form a resistance film. A method for modifying a resistance film source in a semiconductor fabrication and a solid precursor delivery system are also provided. The method for fabricating a semiconductor structure in the present disclosure can remove small particles or ultra-small particles from solid precursor, and does not need extra time to dump cracked solid precursor.

Abstract: A physical vapor deposition (PVD) chamber, a process kit of a PVD chamber and a method of fabricating a process kit of a PVD chamber are provided. In various embodiments, the PVD chamber includes a sputtering target, a power supply, a process kit, and a substrate support. The sputtering target has a sputtering surface that is in contact with a process region. The power supply is electrically connected to the sputtering target. The process kit has an inner surface at least partially enclosing the process region, and a liner layer disposed on the inner surface. The substrate support has a substrate receiving surface, wherein the liner layer disposed on the inner surface of the process kit has a surface roughness (Rz), and the surface roughness (Rz) is substantially in a range of 50-200 ?m.

Abstract: Embodiments of mechanisms of monitoring metal impurity in a high-k dielectric film are provided. The method includes forming an interfacial layer over a substrate. The method also includes forming a high-k dielectric film on the interfacial layer, and the interfacial layer and the high-k dielectric film form a stacked structure over the substrate. The method further includes conducting the first thickness measurement on the stacked structure. In addition, the method includes performing a treatment to the stacked structure after the first thickness measurement, and the treatment includes an annealing process. The method also includes conducting the second thickness measurement on the stacked structure after the treatment.

Abstract: A apparatus includes a susceptor and a non-reactive gas source. The susceptor has through holes and a wafer support surface. Each through hole includes a lift pin and a lift pin head. The lift pin has a vertical degree of motion in the through hole to lift up or place a wafer on the susceptor. The lift pin head has at least one flow channel structure running from its first surface at least partially exposed to a bottom side of the susceptor through its second surface exposed to a top side of the susceptor wherein the lift pin. The non-reactive gas source is configured to flow a gas to a backside of the wafer through the flow channel structure through the bottom side of the susceptor.

Abstract: A method for planarizing a semiconductor wafer. An insulation layer is formed over the wafer. A spin-on-glass layer is coated over the insulation layer. Subsequently, the spin-on-glass layer is baked to smooth out its upper surface. A chemical-mechanical polishing process is carried out to planarize the insulation layer. The method eliminates recess cavities in the more loosely packed device region of the insulation layer after a planarization process.