Abstract: In a method of manufacturing a semiconductor device, a fin structure having a channel region protruding from an isolation insulating layer disposed over a semiconductor substrate is formed, a cleaning operation is performed, and an epitaxial semiconductor layer is formed over the channel region. The cleaning operation and the forming the epitaxial semiconductor layer are performed in a same chamber without breaking vacuum.

Abstract: In an embodiment, a method of forming a structure includes forming a first transistor and a second transistor over a first substrate; forming a front-side interconnect structure over the first transistor and the second transistor; etching at least a backside of the first substrate to expose the first transistor and the second transistor; forming a first backside via electrically connected to the first transistor; forming a second backside via electrically connected to the second transistor; depositing a dielectric layer over the first backside via and the second backside via; forming a first conductive line in the dielectric layer, the first conductive line being a power rail electrically connected to the first transistor through the first backside via; and forming a second conductive line in the dielectric layer, the second conductive line being a signal line electrically connected to the second transistor through the second backside via.

Abstract: A semiconductor package including a ring structure with one or more indents and a method of forming are provided. The semiconductor package may include a substrate, a first package component bonded to the substrate, wherein the first package component may include a first semiconductor die, a ring structure attached to the substrate, wherein the ring structure may encircle the first package component in a top view, and a lid structure attached to the ring structure. The ring structure may include a first segment, extending along a first edge of the substrate, and a second segment, extending along a second edge of the substrate. The first segment and the second segment may meet at a first corner of the ring structure, and a first indent of the ring structure may be disposed at the first corner of the ring structure.

Abstract: An electronic device and a forming method thereof are provided. The electronic device includes a substrate, a metal layer, a first insulating layer, a first conductive layer, a second insulating layer, and a second conductive layer. The metal layer is disposed on the substrate and includes a sensing line and a drain electrode. The first insulating layer is disposed on the metal layer. The first conductive layer is disposed on the first insulating layer and includes a touch electrode. The second insulating layer is disposed on the first conductive layer. The second conductive layer is disposed on the second insulating layer and includes a conductive pattern. The conductive pattern is electrically connected to the sensing line and the touch electrode.

Abstract: An ultrasonic welding device includes a first component and a second component. The first component includes at least one first welding feature and at least one second welding feature which are arranged along a horizontal direction, and the first and second welding features have different sizes in a vertical direction. The second component has at least one welding structure which is configured to be in contact with the first and second welding features, so as to weld the first and second components.

Abstract: An electrical device includes a container, a conversion unit, an outer cover and an inner cover. The container is provided with an inner bottom surface and an inner which define an accommodating channel together. An inlet of the accommodating channel is opposite to the inner bottom surface. The conversion unit is disposed within the accommodating channel. The outer cover covers the inlet of the accommodating channel. The inner cover is disposed within the accommodating channel, and located between the conversion unit and the outer cover. One part of the conversion unit extends to the opening, and at least one outer edge of the inner cover is connected to an inner wall of the container.

Abstract: A magnetic memory element has a Ru hard mask layer. The use of Ru advantageously allows for closer spacing of adjacent magnetic memory elements leading to increased data density. In addition, the use of Ru as a hard mask reduces parasitic electrical resistance by virtue of the fact that Ru does not oxidize in ordinary manufacturing environments. The magnetic memory element can be formed by depositing a plurality of memory element layers, depositing a Ru hard mask layer, depositing a RIEable layer over the Ru hard mask layer, and forming a photoresist mask over the hard mask layer. A reactive ion etching can be performed to transfer the image of the photoresist mask onto the RIEable layer to form a RIEable mask. An ion etching can then be performed to transfer the image of the RIAable mask onto the underlying Ru hard mask and underlying memory element layers.

Abstract: A semiconductor device includes a substrate, an oxide layer and a word line. The substrate has a plurality of protruding portions. Adjacent two of the protruding portions define a dense zone, and another adjacent two of the protruding portions define a loose zone. The oxide layer is disposed on the substrate. The word line is disposed on the substrate. A bottom surface of a portion of the word line in the dense zone and a bottom surface of a portion of the word line in the loose zone are substantially at the same height.

Abstract: A semiconductor device includes a substrate, an oxide layer and a word line. The substrate has a plurality of protruding portions. Adjacent two of the protruding portions define a dense zone, and another adjacent two of the protruding portions define a loose zone. The oxide layer is disposed on the substrate. The word line is disposed on the substrate. A bottom surface of a portion of the word line in the dense zone and a bottom surface of a portion of the word line in the loose zone are substantially at the same height.

Abstract: A magnetic memory element has a Ru hard mask layer. The use of Ru advantageously allows for closer spacing of adjacent magnetic memory elements leading to increased data density. In addition, the use of Ru as a hard mask reduces parasitic electrical resistance by virtue of the fact that Ru does not oxidize in ordinary manufacturing environments. The magnetic memory element can be formed by depositing a plurality of memory element layers, depositing a Ru hard mask layer, depositing a RIEable layer over the Ru hard mask layer, and forming a photoresist mask over the hard mask layer. A reactive ion etching can be performed to transfer the image of the photoresist mask onto the RIEable layer to form a RIEable mask. An ion etching can then be performed to transfer the image of the RIAable mask onto the underlying Ru hard mask and underlying memory element layers.

Abstract: A magnetic memory element having a Ru hard mask layer. The use of Ru advantageously allows for closer spacing of adjacent magnetic memory elements leading to increased data density. In addition, the use of Ru as a hard mask reduces parasitic electrical resistance by virtue of the fact that Ru does not oxidize in ordinary manufacturing environments. The magnetic memory element can be formed by depositing a plurality of memory element layers, depositing a Ru hard mask layer, depositing a RIEable layer over the Ru hard mask layer, and forming a photoresist mask over the hard mask layer. A reactive ion etching can be performed to transfer the image of the photoresist mask onto the RIEable layer to form a RIEable mask. An ion etching can then be performed to transfer the image of the RIAable mask onto the underlying Ru hard mask and underlying memory element layers.

Abstract: A magnetic memory element having a magnetic free layer and a magnetic reference layer with a non-magnetic barrier layer between the magnetic reference layer and the magnetic free layer. A spin current layer (which may be a precessional spin current layer) is located adjacent to the magnetic free layer and is separated from the magnetic free layer by a non-magnetic coupling layer. A material layer adjacent to and in contact with the spin current layer, has a material composition and thickness that are chosen to provide a desired effective magnetization in the spin current layer. The material layer, which may be a capping layer or a seed layer, can be constructed of a material other than tantalum which may include one or more of Zr, Mo, Ru, Rh, Pd, Hf, W, Ir, Pt and/or alloys and/or nitrides of these elements.

Abstract: A magnetic memory element for using in magnetic random access memory. The magnetic memory element includes a novel exchange coupling layer for use in an antiferromagnetic structure for magnetically pinning a magnetic reference layer of the memory element. The exchange coupling layer is located between a first magnetic layer (reference layer) and a second magnetic layer (keeper layer). The exchange coupling layer includes a layer of Ru located between first and second layers of Ir. The Ir layers can be in contact with each of the first and second magnetic layers to provide an interfacial magnetic anisotropy, as well as providing RKKY exchange field. The Ru layer, provides an increased RKKY exchange field as a result of the high RKKY exchange coupling of Ru.

Abstract: A magnetic memory element having a Ru hard mask layer. The use of Ru advantageously allows for closer spacing of adjacent magnetic memory elements leading to increased data density. In addition, the use of Ru as a hard mask reduces parasitic electrical resistance by virtue of the fact that Ru does not oxidize in ordinary manufacturing environments. The magnetic memory element can be formed by depositing a plurality of memory element layers, depositing a Ru hard mask layer, depositing a RIEable layer over the Ru hard mask layer, and forming a photoresist mask over the hard mask layer. A reactive ion etching can be performed to transfer the image of the photoresist mask onto the RIEable layer to form a RIEable mask. An ion etching can then be performed to transfer the image of the RIAable mask onto the underlying Ru hard mask and underlying memory element layers.

Abstract: A method for applying a coating to a surface of an industrial tool includes applying a coating including a thermosetting polymer to a metallic surface of the industrial tool. The coating is cured to form a bond between the coating and the metallic surface. According to certain embodiments, the thermosetting polymer may be combined with an additive. The additive may be selected to improve the chemical resistance or wear resistance of the coating and thereby improve the chemical resistance or wear resistance of certain surfaces of the industrial tool.

Abstract: A method for making a sensing circuit structure is disclosed to provide a transparent substrate, and then to form multiple plating base layers in the transparent substrate in a spaced manner, and then to form a metal conductor layer on each plating base layer using a plating technique. Thus, the thickness of the metal conductor layers can be thinner than that formed by silver paste. The invention relates also to a sensing circuit structure made by this method.

Abstract: A peel-off device for an electronic-part delivery system has a front end portion and a recess that is indented inwardly from the front end portion, that is formed through upper and lower surfaces of the front end portion and that has a width larger than that of an electronic part of predetermined specification.

Abstract: A peel-off device for an electronic-part delivery system has a front end portion and a recess that is indented inwardly from the front end portion, that is formed through upper and lower surfaces of the front end portion and that has a width larger than that of an electronic part of predetermined specification.