Abstract: A memory device includes an alternating stack of insulating layers and electrically conductive layers, and comprising stepped surfaces, a memory opening vertically extending through each layer within the alternating stack, a memory opening fill structure located in the memory opening and including a vertical stack of memory elements and a vertical semiconductor channel, a dielectric material layer that extends from a bottommost vertical step of the stepped surfaces to a topmost vertical step of the stepped surfaces, and a contact via structure including an upper contact via portion having an annular bottom surface that contacts an annular top surface of a first electrically conductive layer of the electrically conductive layers, and a lower contact via portion that vertically extends through a first subset of the electrically conductive layers that underlie the first electrically conductive layer, and the lower contact via portion is narrower than the upper contact via portion.

Abstract: An insulating film is formed over a semiconductor substrate. A wiring trench formed in the insulating film reaches partway in a thickness direction of the insulating film. A via hole is disposed at an end of the wiring trench. A barrier metal film covers inner surfaces of the wiring trench and via hole. A bottom of the wiring trench and a sidewall of the via hole are connected via an inclined plane. A length of a portion of the inclined plane having an inclination angle range of 40° to 50° relative to a surface of the semiconductor substrate is equal to or shorter than a maximum size of a plan shape of the via hole, in a cross section which is parallel to a longitudinal direction of the wiring trench, passes a center of the via hole and perpendicular to the surface of the semiconductor surface.

Abstract: A via hole is formed in the interlayer insulating film on a semiconductor substrate, the via hole reaching the bottom of the interlayer insulating film. A filling member fills a lower partial space in the via hole. A wiring trench continuous with the via hole as viewed in plan is formed, the wiring trench reaching partway in a thickness direction. The wiring trench is formed under the condition that an etching rate of the interlayer insulating film is faster than that of the filling member, in such a manner that a height difference between the upper surface of the filling member and the bottom of the wiring trench is half or less than half the maximum size of a plan shape of the via hole. The filling member in the via hole is removed. The inside of the via hole and wiring trench is filled with a conductive member.

Abstract: An insulating film is formed over a semiconductor substrate. A wiring trench formed in the insulating film reaches partway in a thickness direction of the insulating film. A via hole is disposed at an end of the wiring trench. A barrier metal film covers inner surfaces of the wiring trench and via hole. A bottom of the wiring trench and a sidewall of the via hole are connected via an inclined plane. A length of a portion of the inclined plane having an inclination angle range of 40° to 50° relative to a surface of the semiconductor substrate is equal to or shorter than a maximum size of a plan shape of the via hole, in a cross section which is parallel to a longitudinal direction of the wiring trench, passes a center of the via hole and perpendicular to the surface of the semiconductor surface.

Abstract: A via hole is formed in the interlayer insulating film on a semiconductor substrate, the via hole reaching the bottom of the interlayer insulating film. A filling member fills a lower partial space in the via hole. A wiring trench continuous with the via hole as viewed in plan is formed, the wiring trench reaching partway in a thickness direction. The wiring trench is formed under the condition that an etching rate of the interlayer insulating film is faster than that of the filling member, in such a manner that a height difference between the upper surface of the filling member and the bottom of the wiring trench is half or less than half the maximum size of a plan shape of the via hole. The filling member in the via hole is removed. The inside of the via hole and wiring trench is filled with a conductive member.

Abstract: A semiconductor device manufacturing method forming an interconnection structure by a dual damascene process is disclosed that includes the steps of forming first and second interlayer insulating films successively over an interconnection layer, at least one of which includes a low dielectric constant material; forming a via hole through the first and second interlayer insulating films; filling the via hole with a burying material including an acid generator; causing an acid substance to be generated in the burying material; forming a chemically amplified resist film covering the second interlayer insulating film and the burying material; forming the pattern of an interconnection trench in the area including the via hole over the chemically amplified resist film; forming the interconnection trench by etching the second interlayer insulating film using the chemically amplified resist film as a mask; and filling the via hole and the interconnection trench with a conductive material.

Abstract: A via hole is first formed, and an embedded material is embedded in the via hole. A height of the embedded material is adjusted so that a surface thereof is between an upper surface of an SiOC film and that of an SiC film. After this, an SiN film, a TEOS film, and the SiOC film are etched by using a resist mask as a mask. However, etching of the SiOC film is stopped when a bottom of a trench formed in the SiOC film is lower than an upper surface of the embedded material and higher than that of the SiC film. Then, the resist mask and the embedded material are removed. The SiOC film is etched again by using the SiN film as a mask, and the SiN film and an exposed part of the SiC film are removed.

Abstract: In a via-first Dual Damascene method, after a via hole and a wiring trench are formed, an SiN film, an exposed portion of an SiC film and an exposed portion of an SiC film are removed by etching. As a result, the via hole reaches a Cu wire, and the wiring trench reaches an SiOC film. A reaction product adheres mainly to a side wall portion of the wiring trench. The reaction product also adheres to other spots, but an amount of adherence to the side wall portion is the largest. Subsequently, oxygen plasma treatment is performed for insides of the via hole and the wiring trench. As a result of this oxygen plasma treatment, the reaction product is removed.

Abstract: In a via-first Dual Damascene method, after a via hole and a wiring trench are formed, an SiN film, an exposed portion of an SiC film and an exposed portion of an SiC film are removed by etching. As a result, the via hole reaches a Cu wire, and the wiring trench reaches an SiOC film. A reaction product adheres mainly to a side wall portion of the wiring trench. The reaction product also adheres to other spots, but an amount of adherence to the side wall portion is the largest. Subsequently, oxygen plasma treatment is performed for insides of the via hole and the wiring trench. As a result of this oxygen plasma treatment, the reaction product is removed.

Abstract: A via hole is first formed, and an embedded material is embedded in the via hole. A height of the embedded material is adjusted so that a surface thereof is between an upper surface of an SiOC film and that of an SiC film. After this, an SiN film, a TEOS film, and the SiOC film are etched by using a resist mask as a mask. However, etching of the SiOC film is stopped when a bottom of a trench formed in the SiOC film is lower than an upper surface of the embedded material and higher than that of the SiC film. Then, the resist mask and the embedded material are removed. The SiOC film is etched again by using the SiN film as a mask, and the SiN film and an exposed part of the SiC film are removed.