The thickness of an insulating film, which will serve as an offset spacer film and is formed in an offset monitor region, is managed as the thickness of an offset spacer film formed over the side wall surface of a gate electrode of an SOTB transistor STR, etc. When the measured thickness is within the tolerance of a standard thickness, standard implantation energy and a standard dose amount are set. When the measured thickness is smaller than the standard thickness, implantation energy and a dose amount, which are respectively lower than the standard values thereof, are set. When the measured thickness is larger than the standard thickness, implantation energy and a dose amount, which are respectively higher than the standard values thereof, are set.

An object of the present invention is to provide a semiconductor device combining transistors integrating on a same substrate transistors including an oxide semiconductor in their channel formation region and transistors including non-oxide semiconductor in their channel formation region. An application of the present invention is to realize substantially non-volatile semiconductor memories which do not require specific erasing operation and do not suffer from damages due to repeated writing operation. Furthermore, the semiconductor device is well adapted to store multivalued data. Manufacturing methods, application circuits and driving/reading methods are explained in details in the description.

An object is to provide a deposition method in which a gallium oxide film is formed by a DC sputtering method. Another object is to provide a method for manufacturing a semiconductor device using a gallium oxide film as an insulating layer such as a gate insulating layer of a transistor. An insulating film is formed by a DC sputtering method or a pulsed DC sputtering method, using an oxide target including gallium oxide (also referred to as GaO.sub.X). The oxide target includes GaO.sub.X, and X is less than 1.5, preferably more than or equal to 0.01 and less than or equal to 0.5, further preferably more than or equal to 0.1 and less than or equal to 0.2. The oxide target has conductivity, and sputtering is performed in an oxygen gas atmosphere or a mixed atmosphere of an oxygen gas and a rare gas such as argon.

A method for fabricating substrate of a semiconductor device includes the steps of: providing a first silicon layer; forming a dielectric layer on the first silicon layer; bonding a second silicon layer to the dielectric layer; removing part of the second silicon layer and part of the dielectric layer to define a first region and a second region on the first silicon layer, wherein the remaining of the second silicon layer and the dielectric layer are on the second region; and forming an epitaxial layer on the first region of the first silicon layer, wherein the epitaxial layer and the second silicon layer comprise same crystalline orientation.

A transistor with stable electrical characteristics is provided. The transistor includes a first insulator over a substrate; first to third oxide insulators over the first insulator; a second insulator over the third oxide insulator; a first conductor over the second insulator; and a third insulator over the first conductor. An energy level of a conduction band minimum of each of the first and second oxide insulators is closer to a vacuum level than that of the oxide semiconductor is. An energy level of a conduction band minimum of the third oxide insulator is closer to the vacuum level than that of the second oxide insulator is. The first insulator contains oxygen. The number of oxygen molecules released from the first insulator measured by thermal desorption spectroscopy is greater than or equal to 1E14 molecules/cm.sup.2 and less than or equal to 1E16 molecules/cm.sup.2.

The invention relates to a method for fabricating a semiconductor circuit comprising providing a semiconductor substrate; fabricating a first semiconductor device comprising a first semiconductor material on the substrate and forming an insulating layer comprising a cavity structure on the first semiconductor device. The cavity structure comprises at least one growth channel and the growth channel connects a crystalline seed surface of the first semiconductor device with an opening. Further steps include growing via the opening from the seed surface a semiconductor filling structure comprising a second semiconductor material different from the first semiconductor material in the growth channel; forming a semiconductor starting structure for a second semiconductor device from the filling structure; and fabricating a second semiconductor device comprising the starting structure. The invention is notably also directed to corresponding semiconductor circuits.

A novel semiconductor device, a semiconductor device capable of operating at high speed, or a semiconductor device with low power consumption is provided. The semiconductor device includes a memory cell, a first circuit, a second circuit, and a wiring. The memory cell has a function of storing first data and has a function of supplying a first current corresponding to the first data to the wiring. The first circuit has a function of supplying a second current corresponding to second data to the wiring input from the outside. The second circuit has a function of performing correction of a current flowing in the wiring in the case where a value of the first current and a value of the second current are different from each other. The second circuit has a function of generating a signal including information on whether the correction is performed or not.

A semiconductor structure includes a bulk semiconductor substrate, an electrically insulating layer over the substrate, an active layer of semiconductor material over the electrically insulating layer and a transistor. The transistor includes an active region, a gate electrode region and an isolation junction region. The active region is provided in the active layer of semiconductor material and includes a source region, a channel region and a drain region. The gate electrode region is provided in the bulk semiconductor substrate and has a first type of doping. The isolation junction region is formed in the bulk semiconductor substrate and has a second type of doping opposite the first type of doping. The isolation junction region separates the gate electrode region from a portion of the bulk semiconductor substrate other than the gate electrode region that has the first type of doping.

A multilayer semiconductor device structure having different circuit functions on different semiconductor device layers is provided. The semiconductor structure comprises a first semiconductor device layer fabricated on a bulk substrate. The first semiconductor device layer comprises a first semiconductor device for performing a first circuit function. The first semiconductor device layer includes a patterned top surface of different materials. The semiconductor structure further comprises a second semiconductor device layer fabricated on a semiconductor-on-insulator (SOT) substrate. The second semiconductor device layer comprises a second semiconductor device for performing a second circuit function. The second circuit function is different from the first circuit function. A bonding surface coupled between the patterned top surface of the first semiconductor device layer and a bottom surface of the SOT substrate is included. The bottom surface of the SOT substrate is bonded to the patterned top surface of the first semiconductor device layer via the bonding surface.

When VC inspection for a TEG is performed, it is easily detected whether any failure of a contact plug occurs or not by increasing an emission intensity of a contact plug, so that reliability of a semiconductor device is improved. An element structure of an SRAM is formed on an SOI substrate in a chip region. Also, in a TEG region, an element structure of an SRAM in which a contact plug is connected to a semiconductor substrate is formed on the semiconductor substrate exposed from an SOI layer and a BOX film as a TEG used for the VC inspection.