Abstract: A semiconductor wafer includes (a) a first principal side and a second principal side opposite to each other, (b) a first bevel contour and a second bevel contour provided at an outer periphery of the first principal side and the second principal side, (c) a first recess formed in the first bevel contour, and (d) a first type of ID mark configured by a protruding dot provided on a bottom face of the first recess.

Abstract: A semiconductor wafer has a bevel contour formed along the periphery thereof, products formed on the wafer, and an ID mark formed on the bevel contour. The ID mark shows at least the properties, manufacturing conditions, and test results of the products.

Abstract: An impurity diffusion surface layer is formed in a surface of a silicon substrate, and an aluminum electrode is arranged in direct contact with the impurity diffusion layer. The surface layer contains Ge as an impurity serving to change the lattice constant in a concentration of at least 1.times.10.sup.21 cm.sup.-3 under a thermal non-equilibrium state. The lattice constant of the surface layer is set higher than that of silicon containing the same concentration of germanium under a thermal equilibrium state. As a result, it is possible to decrease the Schittky barrier height at the contact between the surface layer and the electrode. The surface layer also contains an electrically active boron as an impurity serving to impart carriers in a concentration higher than the critical concentration of solid solution in silicon under a thermal equilibrium state. The presence of Ge permits the carrier mobility within the surface layer higher than that within silicon.

Abstract: An impurity diffusion surface layer is formed in a surface of a silicon substrate, and an aluminum electrode is arranged in direct contact with the impurity diffusion layer. The surface layer contains Ge as an impurity serving to change the lattice constant in a concentration of at least 1.times.10.sup.21 cm.sup.-1 under a thermal non-equilibrium state. The lattice constant of the surface layer is set higher than that of silicon containing the same concentration of germanium under a thermal equilibrium state. As a result, it is possible to decrease the Schittky barrier height at the contact between the surface layer and the electrode. The surface layer also contains an electrically active boron as an impurity serving to impart carriers in a concentration higher than the critical concentration of solid solution in silicon under a thermal equilibrium state. The presence of Ge permits the carrier mobility within the surface layer higher than that within silicon.

Abstract: A CMOS inverter circuit incorporating a P channel MOSFET and an N channel MOSFET, both of which can achieve surface conduction, is provided while maintaining the prescribed miniaturization. Thus, the threshold value and conductance of the both MOSFETs are independent of the thickness of the silicon film, and can be easily controlled in the manufacturing processes thereof.