The present invention relates to a circuit substrate arrangement comprising a base layer (2) made from aluminium, a circuit layer (3) made from copper, a dielectric layer (4) arranged between the base layer (2) and the circuit layer (3), an opening (5) passing through the base layer (2), the circuit layer (3) and the dielectric layer (4) and an electrical contact (6) between the base layer (2) and the circuit layer (3), wherein the electrical contact (6) comprises a rivet (7), wherein a frictionally connected joint (8) is formed between the rivet (7) and the base layer (2) and wherein an integrally bonded joint (9) is formed between the rivet (7) and the circuit layer (3).

First, a router (400) is rotated about a shaft (406) to cause a tip end (402) of the router (400) to move in a vertical direction with respect to a conductive layer (130) while being in contact with the conductive layer (130). In this way, the router (400) is inserted into the conductive layer (130) to form an opening in the conductive layer (130). Next, the router (400) is rotated about the shaft (406) to cause a side surface (404) of the router (400) to move in a horizontal direction with respect to the conductive layer (130) while being contact with the conductive layer (130). In this way, the conductive layer (130) is formed into a conductive pattern (132).

A method of manufacturing a component carrier is presented. The method includes providing a base structure having a front side and a back side, the back side being at least partially covered by a metallic layer, removing material of the base structure from the front side to thereby form a cavity which is at least partially closed by the metallic layer, inserting a component in the cavity and placing the component on the metallic layer.

A print circuit board and a manufacturing method thereof are disclosed. The print circuit board includes a first substrate, a first insulating layer and a metal sheet. The first insulating layer is formed between the first substrate and the metal sheet. The insulating layer includes silicon-based polymer compound. The manufacturing method for the print circuit board includes the following steps: coating a first substrate and a metal sheet with insulating material, placing the first substrate and the metal sheet into a heating device to bake the insulating material on the first substrate and the metal sheet, and bonding the metal sheet onto the first substrate through thermally pressing the baked insulating material. The insulating material includes silicon-based polymer compound.

A fluorine-containing substrate, a copper clad laminate, and a printed circuit board are provided. The fluorine-containing substrate includes a reinforcing material layer and a fluorine-containing resin layer. The reinforcing material layer includes a substrate and a first inorganic filler. The first inorganic filler is attached on the substrate and is dispersed in the reinforcing material layer. The particle size of the first inorganic filler ranges from 0.02 m to 1 m. The reinforcing material layer is covered by the fluorine-containing resin layer. The fluoride resin layer includes a second inorganic filler whose particle size ranges between a value larger than 1 m and 100 m.

A light emitting diode (LED) module may include a direct current (DC) voltage node formed on a first layer. The DC voltage node may be configured to sink a first current. One or more devices may be formed on the first layer configured to provide a second current to one or more LEDs. A device of the one or more devices may carry a steep slope voltage waveform. A local shielding area may be formed in a second layer directly below the DC voltage node and the one or more devices. The local shielding area may include a substantially continuous area of conductive material. A conductive via may extend through one or more layers. The conductive via may electrically connect the DC voltage node and the local shielding area.

A ceramic circuit board includes a ceramic substrate and metal layers provided to both surfaces of the ceramic substrate and containing Al and/or Cu, wherein a measurement value 1 of a linear thermal expansion coefficient at 25 C. to 150 C. is 510.sup.6 to 910.sup.6/K, a ratio 1/2 of the 1 to a theoretical value 2 of the linear thermal expansion coefficient at 25 C. to 150 C. is 0.7 to 0.95, and at least one of the metal layers forms a metal circuit.

The disclosure provides an insulated metal substrate (IMS) including a substrate having a first side and a second side. The IMS may also include a first dielectric layer on the first side of the substrate. The dielectric layer may include a metal-based oxynitride and/or a metalloid-based oxynitride layer, oxygen is from 0.1 at % to 49.9 at %, nitrogen is from 0.1 at % to 49.9 at % and a sum of oxygen and nitrogen is about 50 at %. The first dielectric layer comprises a material selected from a group consisting of aluminum oxynitride (AION), aluminum oxyhydronitride (AIHON), aluminum oxycarbonitride (AICON), SiGeON, GaON, SiON, and GeON. The substrate comprises one of Cu, Al, AISi, C-AI, WCu, or Ti.

The invention relates to a substrate (1) for electrical circuits comprising at least one first composite layer (2) which is produced by means of roll cladding and, after said roll cladding, has at least one copper layer (3) and an aluminium layer (4) attached thereon, wherein at least the surface side of the aluminium layer (4) facing away from the copper layer (3) is anodized for the generation of an anodic or insulating layer (5) made of aluminium oxide, and wherein the anodic or insulating layer (5) made of aluminium oxide is connected to a metal layer (7) or at least one second composite layer (2) or at least one paper-ceramic layer (11) via at least one adhesive layer (6, 6).

A method for making conformal non-planar multi-layer circuitry is described. The method can include providing a substrate having a non-planar surface and depositing a first conformal dielectric layer on the substrate, the first conformal dielectric layer conforming to the non-planar surface of the substrate and having a non-planar surface. The method can also include applying a first conformal circuitry layer on the first conformal dielectric layer. The method can include depositing a second conformal dielectric layer on the first conformal circuitry layer, the second conformal dielectric layer conforming to a non-planar surface of the first conformal circuitry layer, and applying a second conformal circuitry layer on the second conformal dielectric layer. Successive layers can be sequentially deposited.