A substrate processing method includes providing a substrate formed with a stacked film including at least an etching target film, an underlying layer disposed below the etching target film, and a mask disposed above the etching target film; etching the etching target film through the mask using plasma; and performing heat treatment on the substrate at a predetermined temperature after the etching. At least one of the mask and the underlying layer contains a transition metal.

A method is provided for fabricating a semiconductor wafer having a device side, a back side opposite the device side and an outer periphery edge. Suitably, the method includes: forming a top conducting layer on the device side of the semiconductor wafer; forming a passivation layer over the top conducting layer, the passivation layer being formed so as not to extend to the outer periphery edge of the semiconductor wafer; and forming a protective layer over the passivation layer, the protective layer being spin coated over the passivation layer so as to have a smooth top surface at least in a region proximate to the outer periphery edge of the semiconductor wafer.

An etching method and a plasma processing apparatus form a recess with an intended shape. The etching method includes (a) providing a substrate, the substrate including a silicon-containing film and a mask on the silicon-containing film; (b) etching the silicon-containing film with a first plasma to form a recess, the first plasma generated from a first process gas; (c) supplying a second plasma to the substrate, the second plasma generated from a second process gas comprising tungsten; and (d) etching the recess with a third plasma generated from a third process gas.

Exemplary semiconductor processing methods may include providing an oxygen-containing precursor to a processing region of a semiconductor processing chamber. The methods may include forming a plasma of the oxygen-containing precursor to produce oxygen-containing plasma effluents. The methods may include contacting a substrate housed in the processing region with the oxygen-containing plasma effluents. The substrate may include a boron-and-nitrogen-containing material overlying a carbon-containing material. The boron-and-nitrogen-containing material comprises a plurality of openings. The methods may include etching the carbon-containing material.

According to one embodiment, a pattern forming method includes forming a first resin pattern on a substrate with a first resin. The first resin pattern includes a first transfer pattern and a first mark. A second resin is dispensed to cover the first mark of the first resin pattern. A first pattern is formed including the first transfer pattern and the second resin covering the first mark. The first pattern is then transferred to a first process film on the substrate.

A process includes forming, over a dielectric layer, a hardmask stack including a first layer below a second layer below a third layer below a fourth layer. The first and third layers include a different hardmask material from the second and fourth layers. A trench pattern including sidewall spacer structures is formed over the hardmask stack. The fourth layer is etched in a first region. The fourth and third layers are etched in a second region. The fourth and third layers are etched in a third region. The fourth layer is etched in a fourth region. The second and first layers are etched in the second and third regions. The third layer is etched in the first and fourth regions. In the dielectric layer, trenches are formed in the first and fourth regions, and via openings, deeper than the trenches, are formed in the second and third regions.

Methods for the fabrication of semiconductor devices are disclosed. A method may include depositing a mask layer on a substrate, forming a protection layer on the mask layer, and modifying the protection layer such that a porosity of the protection layer is reduced. Modifying the protection layer may include densifying the protection layer. Modifying the protection layer may include reducing the protection layer using a hydrogen plasma. The method may include etching the protection layer and the substrate. Etching may include etching, forming the protection layer, and modifying the protection layer in a predetermined number of cycles.

An integrated circuit includes a first and second power rail, a set of active regions, a first set of conductive lines and a first set of vias between the set of active regions and the first set of conductive lines. The first power rail being configured to supply a first supply voltage and being on a first metal layer of a back-side of a substrate. The second power rail being configured to supply a second supply voltage, and being on the first metal layer. The set of active regions being on a first level of a front-side of the substrate opposite from the back-side, overlapping and being electrically coupled to the first and second power rail. The first set of conductive lines being on a second metal layer of the back-side of the substrate, and being overlapped by the set of active regions.

A plasma processing method includes: a) providing a substrate on a substrate support; b) supplying a process gas; c) periodically supplying a pulse voltage to the substrate support; and d) periodically supplying RF power and generating plasma from the process gas to etch a silicon-containing film included in the substrate. The pulse voltage is negative. A first period in which a first pulse voltage is supplied and a second period in which the pulse voltage is not supplied or a second pulse voltage whose absolute value is less than that of the first pulse voltage is supplied are repeated in c). A third period in which first RF power is supplied and a fourth period in which the RF power is not supplied or second RF power less than the first RF power is supplied are repeated in d). The first period starts before a start of the third period.

A substrate processing method includes (a) providing a substrate including an underlying film and a metal-containing resist film in which a pattern is formed on the underlying film; (b) forming a metal-containing film on a surface of the metal-containing resist film; and (c) removing a residue of the metal-containing film together with at least a part of the metal-containing film.