Disclosed is a method of manufacturing a semiconductor device, including: forming a stacked structure including first material layers and second material layers alternately stacked on each other; forming a pillar passing through the stacked structure, the pillar including a protruding portion protruding above an uppermost surface of the stacked structure; forming a conductive layer surrounding the protruding portion of the pillar; and forming a conductive pattern in contact with the protruding portion of the pillar by oxidizing a surface of the conductive layer.

An object of the present invention is to provide a semiconductor device combining transistors integrating on a same substrate transistors including an oxide semiconductor in their channel formation region and transistors including non-oxide semiconductor in their channel formation region. An application of the present invention is to realize substantially non-volatile semiconductor memories which do not require specific erasing operation and do not suffer from damages due to repeated writing operation. Furthermore, the semiconductor device is well adapted to store multivalued data. Manufacturing methods, application circuits and driving/reading methods are explained in details in the description.

An object is to provide a deposition method in which a gallium oxide film is formed by a DC sputtering method. Another object is to provide a method for manufacturing a semiconductor device using a gallium oxide film as an insulating layer such as a gate insulating layer of a transistor. An insulating film is formed by a DC sputtering method or a pulsed DC sputtering method, using an oxide target including gallium oxide (also referred to as GaO.sub.X). The oxide target includes GaO.sub.X, and X is less than 1.5, preferably more than or equal to 0.01 and less than or equal to 0.5, further preferably more than or equal to 0.1 and less than or equal to 0.2. The oxide target has conductivity, and sputtering is performed in an oxygen gas atmosphere or a mixed atmosphere of an oxygen gas and a rare gas such as argon.

A method of integrating a first substrate having a first surface with a first insulating material and a first contact structure with a second substrate having a second surface with a second insulating material and a second contact structure. The first insulating material is directly bonded to the second insulating material. A portion of the first substrate is removed to leave a remaining portion. A third substrate having a coefficient of thermal expansion (CTE) substantially the same as a CTE of the first substrate is bonded to the remaining portion. The bonded substrates are heated to facilitate electrical contact between the first and second contact structures. The third substrate is removed after heating to provided a bonded structure with reliable electrical contacts.

A method comprises providing a first substrate having dielectric structures and conductive structures. Ions are implanted into the first substrate, the ions traveling through the dielectric structures and the conductive structures to define a cleave plane in the first substrate. The first substrate is cleaved at the cleave plane to obtain a cleaved layer having the dielectric structure and the conductive structures. The cleaved layer is used to form a three-dimensional integrated circuit device having a plurality of stacked integrated circuit (IC) layers, the cleaved layer being one of the stacked IC layers.

A silicon-containing nucleation layer can be employed to provide a self-aligned template for selective deposition of tungsten within backside recesses during formation of a three-dimensional memory device. The silicon-containing nucleation layer may remain as a silicon layer, converted into a tungsten silicide layer, or replaced with a tungsten nucleation layer. Tungsten deposition can proceed only on the surface of the silicon-containing nucleation layer or a layer derived therefrom in a subsequent tungsten deposition process.

A memory device may include a substrate, a first conductive line on the substrate and extending in a first direction, a second conductive line over the first conductive line and extending in a second direction crossing the first direction, a third conductive line over the second conductive line and extending in the first direction, a first memory cell at an intersection of the first conductive line and the second conductive line and including a first selection element layer and a first variable resistance layer, and a second memory cell at an intersection of the second conductive line and the third conductive line and including a second selection element layer and a second variable resistance layer. A first height of the first selection element layer in a third direction perpendicular to the first and second directions is different than a second height of the second selection element layer in the third direction.

This method comprises the following steps: a) providing a first structure successively comprising a first substrate, a first electronic device, and a first dielectric layer; a second structure successively comprising a second substrate, an active layer, a second dielectric layer, and a polycrystalline semiconductor layer, the active layer being designed to form a second electronic device; b) bombarding the polycrystalline semiconductor layer by a beam of species configured to form an amorphous part and to preserve a superficial polycrystalline part; c) bonding the first and second structures; d) removing the second substrate of the second structure; e) introducing dopants into the amorphous part, through the exposed active layer; f) thermally activating the dopants by recrystallization of the amorphous part.

Monolithic 3D ICs employing one or more local inter-level interconnect integrated intimately with at least one structure of at least one transistor on at least one transistor level within the 3D IC. In certain embodiments the local inter-level interconnect intersects a gate electrode or a source/drain region of at least one transistor and extends through at least one inter-level dielectric layer disposed between a first and second transistor level in the 3D IC. Local inter-level interconnects may advantageously make a direct vertical connection between transistors in different levels of the 3D IC without being routed laterally around the footprint (i.e., lateral, or planar, area) of either the overlying or underlying transistor level that is interconnected.

A multilayer semiconductor device structure having different circuit functions on different semiconductor device layers is provided. The semiconductor structure comprises a first semiconductor device layer fabricated on a bulk substrate. The first semiconductor device layer comprises a first semiconductor device for performing a first circuit function. The first semiconductor device layer includes a patterned top surface of different materials. The semiconductor structure further comprises a second semiconductor device layer fabricated on a semiconductor-on-insulator (SOT) substrate. The second semiconductor device layer comprises a second semiconductor device for performing a second circuit function. The second circuit function is different from the first circuit function. A bonding surface coupled between the patterned top surface of the first semiconductor device layer and a bottom surface of the SOT substrate is included. The bottom surface of the SOT substrate is bonded to the patterned top surface of the first semiconductor device layer via the bonding surface.