Apparatuses and methods have been disclosed. One such apparatus includes strings of memory cells formed on a topside of a substrate. Support circuitry is formed on the backside of the substrate and coupled to the strings of memory cells through vertical interconnects in the substrate. The vertical interconnects can be transistors, such as surround substrate transistors and/or surround gate transistors.

A method for manufacturing a semiconductor memory device including following steps is provided. A substrate having a first region, a second region, and a third region is provided. A first stack structure is formed on the first region. A second stack structure is formed on the second region. A third stack structure is formed on the third region. A first mask layer is formed on the substrate to cover the third stack structure. A first ion implantation process is performed, so that a second floating gate and a second control gate in the second stack structure are changed to a first conductive type. A second mask layer formed on the substrate to cover the first and second stack structures. A second ion implantation process is performed, so that a third floating gate and a third control gate in the third stack structure are changed as a second conductive type.

A semiconductor memory device including a first semiconductor layer, first gate electrodes, a first gate insulating layer and a laminated film. The first semiconductor layer extends in a first direction intersecting a substrate. The first gate electrodes are arranged in the first direction and face the first semiconductor layer in a second direction intersecting the first direction. End portions of the first gate electrodes in the second direction have different positions from each other and form a stepped contact portion. The laminated film covers at least parts of upper surfaces and at least parts of side surfaces intersecting the second direction, of the first gate electrodes. The laminated film includes a first insulating layer, second semiconductor layers, a second gate insulating layer, and a second gate electrode. Positions in the first direction and positions in the second direction of the second semiconductor layers are different from each other.

A semiconductor device and method of fabricating the same are disclosed. The method includes depositing a polysilicon gate layer over a gate dielectric formed over a surface of a substrate in a peripheral region, forming a dielectric layer over the polysilicon gate layer and depositing a height-enhancing (HE) film over the dielectric layer. The HE film, the dielectric layer, the polysilicon gate layer and the gate dielectric are then patterned for a high-voltage Field Effect Transistor (HVFET) gate to be formed in the peripheral region. A high energy implant is performed to form at least one lightly doped region in a source or drain region in the substrate adjacent to the HVFET gate. The HE film is then removed, and a low voltage (LV) logic FET formed on the substrate in the peripheral region. In one embodiment, the LV logic FET is a high-k metal-gate logic FET.

In a semiconductor device including a higher-breakdown-voltage MISFET, an improvement is achieved in the breakdown voltage of the MISFET, while preventing an increase in the area of the MISFET. A gate pattern including a gate electrode of the higher-breakdown-voltage MISFET is formed higher in level than a gate pattern including a gate electrode of a lower-breakdown-voltage MISFET. An n.sup.+-type semiconductor region included in each of source/drain regions of the higher-breakdown-voltage MISFET is formed deeper than an n.sup.+-type semiconductor region included in each of source/drain regions of the lower-breakdown-voltage MISFET.

A method of forming a uniform WL over the MCEL region and resulting device are provided. Embodiments include providing a substrate having a MCEL region, a HV region and a logic region, separated by an isolation region; forming a plurality of CG stacks over the MCEL region, and a plurality of CG dummy stacks over the HV region and the logic region, respectively; forming first and second overlying polysilicon layers with a spacer therebetween, an EG and a WL on the MCEL region formed; planarizing the second polysilicon layer down to upper surface of the plurality of CG stacks and the plurality of CG dummy stacks; and removing portions of the second polysilicon layer in-between the plurality of CG stacks and around the plurality of CG dummy stacks.

A low cost IC solution is disclosed to provide Super CMOS microelectronics macros. Hereinafter, the Super CMOS or Schottky CMOS all refer to SCMOS. The SCMOS device solutions with a niche circuit element, the complementary low threshold Schottky barrier diode pairs (SBD) made by selected metal barrier contacts (Co/Ti) to P and NSi beds of the CMOS transistors. A DTL like new circuit topology and designed wide contents of broad product libraries, which used the integrated SBD and transistors (BJT, CMOS, and Flash versions) as basic components. The macros include diodes that are selectively attached to the diffusion bed of the transistors, configuring them to form generic logic gates, memory cores, and analog functional blocks from simple to the complicated, from discrete components to all grades of VLSI chips. Solar photon voltaic electricity conversion and bio-lab-on-a-chip are two newly extended fields of the SCMOS IC applications.

A semiconductor device includes a plurality of nonvolatile memory cells (1). Each of the nonvolatile memory cells comprises a MOS type first transistor section (3) used for information storage, and a MOS type second transistor section (4) which selects the first transistor section. The second transistor section has a bit line electrode (16) connected to a bit line, and a control gate electrode (18) connected to a control gate control line. The first transistor section has a source line electrode (10) connected to a source line, a memory gate electrode (14) connected to a memory gate control line, and a charge storage region (11) disposed directly below the memory gate electrode. A gate withstand voltage of the second transistor section is lower than that of the first transistor section. Assuming that the thickness of a gate insulating film of the second transistor section is defined as tc and the thickness of a gate insulating film of the first transistor section is defined as tm, they have a relationship of tc<tm.

A semiconductor device including a memory cell featuring a first gate insulating film over a semiconductor substrate, a control gate electrode over the first gate insulating film, a second gate insulating film over the substrate and a side wall of the control gate electrode, a memory gate electrode over the second gate insulating film arranged adjacent with the control gate electrode through the second gate insulating film, first and second semiconductor regions in the substrate positioned on a control gate electrode side and a memory gate side, respectively, the second gate insulating film featuring a first film over the substrate, a charge storage film over the first film and a third film over the second film, the first film having a first portion between the substrate and memory gate electrode and a thickness greater than that of a second portion between the control gate electrode and the memory gate electrode.

Various embodiments of the present application are directed to a method for forming an integrated circuit (IC), and the associated integrated circuit. In some embodiments, a stack of gate dielectric precursor layers is formed on a plurality of logic sub-region and is then selectively removed from at least two logic sub-regions. Then, a gate dielectric precursor layer is formed, and a plasma treatment process and an annealing process are subsequently performed. The gate dielectric precursor layer is then selectively removed from a low-voltage logic sub-region, but not a high-voltage logic sub-region. By removing the stack of gate dielectric precursor layers from the low-voltage logic sub-region prior to performing the plasma treatment process and the annealing process, less gate dielectric precursor material is treated, annealed, and removed from the low-voltage logic sub-region. Thus, the resulting residues are reduced, and the defects introduced by the residues are also reduced or eliminated.