Provided are an interconnector and an electronic apparatus including the interconnector. The interconnector includes: a metal layer; a dielectric layer surrounding at least a portion of the metal layer; and an interlayer disposed between the metal layer and the dielectric layer and including a ternary metal oxide.

A substrate processing apparatus for processing a combined substrate in which a first substrate, an interface layer including at least a laser absorption layer, and a second substrate are stacked is provided. An outer peripheral region including a non-bonding region of the first substrate and the second substrate, and an inner peripheral region in a bonding region are set in the combined substrate. A controller executes: a control of causing separation at an interface between the first substrate and the laser absorption layer or at an interface between the interface layer and the laser absorption layer by radiating laser light to the combined substrate while rotating the combined substrate and moving the laser light in the radial direction; and a control of radiating the laser light while moving the laser light from an inner side toward an outer side in the radial direction.

A method for manufacturing a semiconductor device of an embodiment includes a first film forming step of forming a first electrode layer on a base material back surface facing a side opposite to a device surface of a base material on which a circuit portion is formed. The method includes a second film forming step of forming a second electrode layer on a front surface of a film-formed member. The method includes a joining step of joining the first electrode layer and the second electrode layer. The method includes a film-formed member removing step of removing the film-formed member from the second electrode layer.

An aluminum nitride sintered body contains 1 to 5% by weight of yttrium oxide (Y.sub.2O.sub.3), 10 to 100 ppm by weight of titanium (Ti), and the balance being aluminum nitride (AlN). Accordingly, a volume resistance value and thermal conductivity at a high temperature are improved, and the generation of impurities during a semiconductor manufacturing process can be suppressed.

An IGZO thin-film transistor and a method for manufacturing same. The method includes: acquiring a substrate; forming an IGZO layer on the substrate by a solution process; doping V impurities on a surface of the IGZO layer by a spin doping process; forming a source electrode at one side of the IGZO layer, and forming a drain electrode at the other side; forming a gate dielectric layer on the doped IGZO layer; and forming a gate electrode on the gate dielectric layer.

A method of manufacturing a semiconductor element includes: forming a first semiconductor layer (SL1) and a second semiconductor layer (SL2) larger in thickness than the first semiconductor layer (SL1) on a mask layer (ML) including a first opening portion (K1) and a second opening portion (K2); forming a first device layer (DL1) and a second device layer (DL2); and bonding the first device layer (DL1) and the second device layer (DL2) to a support substrate (SK).

Methods of forming silicon nitride on a sidewall of a feature are disclosed. Exemplary methods include providing a substrate comprising a feature comprising a sidewall surface and a surface adjacent the sidewall surface, forming a silicon oxide layer overlying the sidewall surface and the surface adjacent the sidewall surface, using a cyclical deposition process, depositing a silicon nitride layer overlying the silicon oxide layer, and exposing the silicon nitride layer to activated species generated from a hydrogen-containing gas. Exemplary methods can additionally include selectively removing a portion of the silicon nitride layer. Structures formed using the methods and systems for performing the methods are also disclosed.

A planarization system is provided. The planarization system includes a first substrate chuck which holds the substrate during a planarization step, and a second substrate chuck which holds the substrate with a non-flat configuration during a separation step.

The present invention relates to a semiconductor element and a method for manufacturing same, wherein the semiconductor element may comprise: a base element, an intermediate layer formed in at least one direction of the base element; and a metal layer formed on the intermediate layer in a direction opposite to the base element, and wherein a conductive filament may be formed inside the intermediate layer according to the application of a voltage to the intermediate layer.

A control device configured to control a supply condition of a gas which is supplied between two substrates that are to be bonded to each other by a substrate bonding device, is configured to control the supply condition based on a measurement result obtained by a measurement in relation to at least one of the substrate, another substrate bonded before the substrate is bonded, or the substrate bonding device, and the two substrates are bonded to each other by a contact region expanding after the contact region is formed in a center.