A donor substrate in a layer transfer process, is stabilized by attaching a backing substrate. The backing substrate allows thermal and mechanical stabilization during high-power implant processes. Upon cleaving the donor substrate to release a thin layer of material to a target, the backing substrate prevents uncontrolled release of internal stress leading to buckling/fracture of the donor substrate. The internal stress may accumulate in the donor substrate due to processes such as cleave region formation, bonding to the target, and/or the cleaving process itself, with uncontrolled bow and warp potentially precluding reclamation/reuse of the donor substrate in subsequent layer transfer processes. In certain embodiments the backing substrate may exhibit a Coefficient of Thermal Expansion (CTE) substantially matching, or complementary to, that of the donor substrate. In some embodiments the backing structure may include a feature such as a lip.

A MISFET is formed to include: a co-doped layer that is formed over a substrate and has an n-type semiconductor region and a p-type semiconductor region; and a gate electrode formed over the co-doped layer via a gate insulation film. The co-doped layer contains a larger amount of Mg, a p-type impurity, than that of Si, an n-type impurity. Accordingly, the carriers (electrons) resulting from the n-type impurities (herein, Si) in the co-doped layer are canceled by the carriers (holes) resulting from p-type impurities (herein, Mg), thereby allowing the co-doped layer to serve as the p-type semiconductor region. Mg can be inactivated by introducing hydrogen into, of the co-doped layer, a region where the n-type semiconductor region is to be formed, thereby allowing the region to serve as the n-type semiconductor region. By thus introducing hydrogen into the co-doped layer, the p-type semiconductor region and the n-type semiconductor region can be formed in the same layer.