A semiconductor device includes a semiconductor substrate and word line structures. A plurality of active areas are formed in the substrate, and the plurality of active areas are isolated by an isolation structure. The isolation structure includes first areas and second areas. A dimension of the second areas is larger than that of the first areas in first direction. The word line structures are below a surface of the substrate and extend in first direction. The word line structures penetrate the isolation structure and the plurality of active areas. A word line structure includes first sub-word line structures located in first areas and second sub-word line structures located in second areas. The first sub-word line structures have first dimension in second direction, and the second sub-word line structures have second dimension at least larger than first dimension in second direction. The second direction forms an included angle with first direction.

Embodiments relate to a semiconductor structure and a method for fabricating. The semiconductor structure includes: a substrate, word lines, bit lines, and word line isolation structures. Active pillars arranged in an array are provided on a surface of the substrate, and the active pillars include channel regions, and a top doped region positioned on an upper side of the channel region and a bottom doped region positioned on a lower side of the channel region. The word lines extend along a first direction and surround the channel regions of a row of the active pillars arranged along the first direction. The bit lines extend along a second direction and are electrically connected to the bottom doped regions of a column of the active pillars arranged along the second direction, and in a direction facing away from the surface of the substrate.

A semiconductor structure and a method for forming the same are provided. The method for forming the semiconductor structure includes: providing a substrate; etching the substrate to form multiple active areas, trenches each positioned between adjacent active areas, and air gaps positioned below the active areas; and forming a filler layer filling at least each of the trenches.

A method for forming a transistor structure includes steps as follows: A substrate with an original surface is prepared. Next a gate conductive region is formed, wherein at least a portion of the gate conductive region is disposed below the original surface, and a bottom wall and sidewalls of the gate conductive region is surrounded by a gate dielectric layer. Then, a first conductive region is formed, wherein a bottom wall of the first conductive region is aligned or substantially aligned with a top wall of the gate conductive region.

A semiconductor memory device includes a substrate, an active structure, a shallow trench isolation and a plurality of word lines. The active structure is disposed in the substrate, and includes a plurality of first active fragments and a plurality of second active fragments extended parallel to each other along a first direction and the second active fragments are disposed outside a periphery of all of the first active fragments. The shallow trench isolation is disposed in the substrate to surround the active structure, and which includes a plurality of first portions and a plurality of second portions. The word lines are disposed in the substrate, parallel with each other to extend along a second direction, wherein at least one of the word lines are only intersected with the second active fragments, or at least one of the word lines does not pass through any one of the second portions.

A semiconductor structure includes a substrate, an isolation layer, a dielectric layer, an insulation layer, a conductor and a capping layer. The substrate has a concave portion. The isolation layer is located on a top surface of the substrate. The dielectric layer is located on the isolation layer. The insulation layer is located on a surface of the concave portion and extends to a sidewall of the isolation layer. The conductor is located on the insulation layer in the concave portion. The conductor has a first top surface and a second top surface, and the first top surface is closer to the dielectric layer than the second top surface. The capping layer is located in the concave portion and covers the conductor.

Provided are a capacitor and a semiconductor device including the same. The capacitor includes: a dielectric layer having a perovskite crystal structure; and first and second electrodes spaced apart from each other with the dielectric layer therebetween. At least one of the first and second electrodes includes a metallic layer having a perovskite crystal structure, a first ionic layer having ionic properties, and a semiconductor layer.

A semiconductor structure with a capacitor landing pad includes a substrate. A capacitor contact plug is disposed on the substrate. A capacitor landing pad contacts and electrically connects the capacitor contact plug. A bit line is disposed on the substrate. A dielectric layer surrounds the capacitor landing pad. The dielectric layer includes a bottom surface lower than a top surface of the bit line.

A semiconductor device includes a substrate including a plurality of active patterns and a bit line intersecting at least one of the plurality of active patterns on the substrate and extending in a first direction. The bit line includes a first conductive pattern extending in the first direction, a bit line capping pattern extending in the first direction on the first conductive pattern, and a graphene pattern extending in the first direction between the first conductive pattern and the bit line capping pattern. The first conductive pattern may include ruthenium (Ru). The semiconductor device may also include one or more bit line contacts arranged in the first direction under the bit line, the one or more bit line contacts electrically connected to a respective one of the plurality of active patterns.

The present application provides a method of manufacturing a. memory device having a word line (WL) with improved adhesion between a work function member and a conductive layer. The method includes steps of providing a semiconductor substrate defined with an active area and including an isolation structure surrounding the active area; forming a recess extending into the semiconductor substrate and across the active area; forming a first insulating layer conformal to the recess; disposing a first conductive material conformal to the first insulating layer; forming a conductive member surrounded by the first conductive material; disposing a second conductive material over the conductive member and removing a portion of the first conductive material above the second conductive material to form a conductive layer enclosing the conductive member; and forming a second insulating layer over the conductive layer and conformal to the first insulating layer.