A component carrier includes a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. The at least one electrically conductive layer structure includes a first trace. A tapering trench is formed in the at least one electrically insulating layer structure beside and below the first trace. A method of manufacturing the component carrier is also described.

A covering film (100) includes a first covering layer (10), a first adhesive layer (20), and a thermal conductive layer (30) sandwiched between the first covering layer (10) and the first adhesive layer (20). A thermal conductivity of the thermal conductive layer (30) is K1, K1=3˜65 W/m.K. A thermal conductivity of the first covering layer (10) is K2, K2=0.02˜3.0 W/m.K. A thermal conductivity of the first adhesive layer (20) is K3, K3=0.02˜1.0 W/m.K. A circuit board and its manufacturing method are also provided.

A glass core wiring substrate incorporating a high-frequency filter having good high-frequency characteristics as a core material and allowing a more efficient arrangement of a conductor in the glass substrate, a module including the same, and a method of manufacturing the glass core wiring substrate incorporating a high-frequency filter. A conductive layer in a glass through a hole in a glass core substrate has a structure in which a hollow cylindrical conductor layer on a side wall of the glass through hole is connected to a cover conductor layer covering one of two openings of the glass through hole. To achieve such a structure, a carrier is attached to one surface of the glass core substrate to cover one of the openings of the glass through hole, and the carrier is peeled off and removed after lamination of the conductor.

Proposed are a flexible electrode circuit capable of being foamed through 3D circuit printing, a strain sensor using the same, and a manufacturing method thereof. The flexible electrode circuit includes a flexible substrate and an electrode foamed on the flexible substrate. The electrode includes a conductive line layer and a passivation layer. The conductive line layer includes a matrix including an elastic polymer and a conductive line having conductive liquid metal microparticles dispersed in the matrix. The passivation layer includes a coating portion coated on the conductive line and having an elastic polymer.

A ceramic circuit board includes a ceramic base material, a metal layer (first metal layer), and a marker portion. The marker portion is formed on the surface of the first metal layer. The surface of the metal layer (first metal layer) may be plated. When the surface of the metal layer (first metal layer) is plated, the marker portion may be formed on the plating.

A conductor non-formed portion where no conductor layer exists is provided in a first ground conductor layer. A multilayer body is provided with a void where no insulating resin exists. At least a portion of the conductor non-formed portion is provided in a first area positioned at a right of a first interlayer connection conductor with respect to a multilayer body left-right direction and at left of a second interlayer connection conductor with respect to the multilayer body left-right direction in a view in a multilayer body downward direction. At least a portion of a void overlaps with the conductor non-formed portion in the view in the multilayer body downward direction and is provided above a first signal conductor layer with respect to a multilayer body up-down direction and below the first ground conductor layer with respect to the multilayer body up-down direction.

A circuit board includes a multilayer body including a main surface, a mounted conductor, and a signal conductor at an intermediate position in the lamination direction of the multilayer body, and a ground conductor on the main surface. The multilayer body includes a connection portion including a portion overlapping the mounted conductor and overlapping an external board joined via a conductive joint material through use of the mounted conductor, and a circuit portion. A first region, which is the region of a circuit portion of the ground conductor, includes opening holes and a second region, which is the region of a connection portion of the ground conductor, includes opening holes. The ratio of the opening area of the opening holes to that of the second region is larger than the ratio of the opening area of the opening holes to that of the first region.

A method of manufacturing a component carrier includes forming a poorly adhesive structure on at least one layer structure, thereafter removing part of the poorly adhesive structure to thereby define a lateral limit of the poorly adhesive structure, thereafter attaching at least one further layer structure to the at least one layer structure and to the poorly adhesive structure, and forming a cavity by removing material of the at least one further layer structure above the poorly adhesive structure.

A stretchable mounting substrate that includes a first substrate including a stretchable base material and a stretchable wiring on the stretchable base material; a second substrate including a wiring for an electronic component, the second substrate overlapping at least a part of the first substrate in a plan view of the stretchable mounting substrate; and a connection member connecting the first substrate and the second substrate, the connection member including a connection base material and a connection wiring connecting the stretchable wiring of the first substrate and the wiring of the second substrate 20, wherein the connection member is configured to be deformed in accordance with an expansion/contraction direction of the first substrate so that an expansion/contraction ratio of a region of the first substrate overlapping the second substrate in the plan view is larger than an expansion/contraction ratio of the second substrate.

Compositions and methods for aromatic polysulfone copolymers are described herein. The polysulfone copolymers have advantageous properties, particularly in terms of high glass transition temperatures (T.sub.g), improved thermal stability, improved flame resistance, good mechanical properties, chemical resistance and dimensional stability at elevated temperature. The polysulfone copolymers are suitable for manufacturing high temperature molded systems and other articles of manufacture via injection molding, extrusion, compression molding, coating, blow molding, thermoforming, rotational molding and additive manufacturing.