An article includes a ceramic wall that defines at least a side of a passage. The ceramic wall includes a flow turbulator that projects into the passage. The flow turbulator is formed of ceramic matrix composite.

A heat-sink-attached-power module substrate (1) has a configuration such that either one of a metal layer (13) and a heat sink (31) is composed of aluminum or an aluminum alloy, and the other one of them is composed of copper or a copper alloy, the metal layer (13) and the heat sink (31) are bonded together by solid phase diffusion bonding, an intermetallic compound layer formed of copper and aluminum is formed in a bonding interface between the metal layer (13) and the heat sink (31), and an oxide is dispersed in an interface between the intermetallic compound layer and either one of the metal layer (13) composed of copper or a copper alloy and heat sink (31) composed of copper or a copper alloy in a layered form along the interface.

A method for producing a metal-ceramic substrate includes attaching a metal layer to a surface side of a ceramic layer, the metal layer being structured into a plurality of metallization regions respectively separated from one another by at least one trench-shaped intermediate space to form conductive paths and/or connective surfaces and/or contact surfaces. The method further includes filling the at least one trench-shaped intermediate space with an electrically insulating filler material, and covering first edges of the metallization regions facing and adjoining the surface side of the ceramic layer in the at least one trench-shaped intermediate space, as well as at least one second edge of the metallization regions facing away from the surface side of the ceramic layer in the at least one trench-shaped intermediate space, by the electrically insulating filler material.

A ceramic substrate manufacturing method and a ceramic substrate manufactured thereby, may include a seed layer, a brazing filler layer, and a metal foil that are laminated on a ceramic substrate and that are brazed such that the metal foil is firmly bonded to the ceramic substrate by a brazing joint layer. Such methods and devices may substantially improve the adhesion of the metal foil and the ceramic substrate.

To provide a power-module substrate and a manufacturing method thereof in which small voids are reduced at a bonded part and separation can be prevented. Bonding a metal plate of aluminum or aluminum alloy to at least one surface of a ceramic substrate by brazing, when a cross section of the metal plate is observed by a scanning electron microscope in a field of 3000 magnifications in a depth extent of 5 m from a bonded interface between the metal plate and the ceramic substrate in a width area of 200 m from a side edge of the metal plate, residual-continuous oxide existing continuously by 2 m or more along the bonded interface has total length of 70% or less with respect to a length of the field.

A method and apparatus is disclosed for substrate-backed porcelain. A sheet of substrate is secured to a sheet of porcelain. A surface of the substrate is coated with adhesive. A surface of the porcelain is coated with adhesive. The surfaces are joined together by the adhesive. A force is applied across the surfaces to improve adhesion.

In a power-module substrate unit, a circuit layer is structured by a plurality of small circuit layers; a ceramic substrate layer is structured by at least one plate; the small circuit layers are formed to have a layered structure having a first aluminum layer bonded on one surface of the ceramic substrate layer and a first copper layer bonded on the first aluminum layer by solid diffusion; a radiation plate is made of copper or copper alloy; the metal layer and the radiation plate are bonded by solid diffusion.

A power-module substrate including a circuit layer having a first aluminum layer bonded on one surface of a ceramic substrate and a first copper layer bonded on the first aluminum layer by solid-phase-diffusion bonding, and a metal layer having a second aluminum layer made from a same material as the first aluminum layer and bonded on the other surface of the ceramic substrate and a second copper layer made from a same material as the first copper layer and bonded on the second aluminum layer by solid-phase-diffusion bonding, in which a thickness t1 of the first copper layer is 1.7 mm to 5 mm, a sum of the thickness t1 of the first copper layer and a thickness t2 of the second copper layer is 7 mm or smaller, and a ratio t2/t1 is larger than 0 and 1.2 or smaller except for a range of 0.6 to 0.8.

A method for joining, assembling, at least two parts made of silicon carbide-based materials by non-reactive brazing is provided. According to the method, the parts are contacted with a non-reactive brazing composition, the assembly formed by the parts and the brazing composition is heated to a brazing temperature sufficient to melt the brazing composition totally or at least partly, and the parts and brazing composition are cooled to that, after solidification of the brazing composition, a moderately refractory joint is formed; wherein the non-reactive brazing composition is an alloy comprising, in atomic percentages, 45% to 65% silicon, 28% to 45% nickel and 5% to 15% aluminum. A brazing composition as defined above is provided. A brazing paste, suspension comprising a powder of said brazing composition and an organic binder as well as a joint and assembly obtained the foregoing method are also provided.

A power module substrate includes an insulating layer, a circuit layer that is formed on a first surface of the insulating layer, and a metal layer that is formed on a second surface of the insulating layer, in which a first base layer is laminated on a surface of the metal layer on the opposite side of the surface to which the insulating layer is provided, and the first base layer has: a first glass layer that is formed at the interface with the metal layer; and a first Ag layer that is laminated on the first glass layer.