A metal/ceramic bonding substrate wherein the bonding strength of an aluminum plate bonded directly to a ceramic substrate is higher than that of conventional metal/ceramic bonding substrates, and a method for producing same, wherein the method includes arranging a ceramic substrate in a mold; putting the mold in a furnace; lowering an oxygen concentration to 25 ppm or less and a dew point to 45 C. or lower in the furnace; injecting a molten metal of aluminum into the mold to contact the surface of the ceramic substrate; and cooling and solidifying the molten metal to form a metal plate for a circuit pattern of aluminum on one side of the ceramic substrate to bond one side of the metal plate for a circuit pattern directly to the ceramic substrate, while forming a metal base plate of aluminum on the other side of the ceramic substrate.

A method for producing a ceramic-aluminum bonded body obtained by bonding a ceramic member and an aluminum member, the aluminum member before bonding being composed of aluminum having a purity of 99.0 mass % or higher and 99.9 mass % or lower, includes a heat treatment step of subjecting the aluminum member to a heat treatment in a range of 400 C. or higher and lower than a solidus temperature, and a bonding step of bonding the aluminum member after the heat treatment step and the ceramic member via a brazing filler material including Si.

A method for preparing a ceramic copper clad laminate is provided, including following steps: providing a copper material; forming a copper oxide layer on a surface of the copper material; thermally treating the copper material on which the copper oxide layer is formed, to diffuse oxygen atoms in the copper material; removing the copper oxide layer on the thermally treated copper material; and soldering the copper-oxide-layer-removed copper material to a ceramic substrate to obtain a ceramic copper clad laminate.