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.

An embedded flash memory device includes a gate stack, which includes a bottom dielectric layer extending into a recess in a semiconductor substrate, and a charge storage layer over the bottom dielectric layer. The charge storage layer includes a portion in the recess. The gate stack further includes a top dielectric layer over the charge storage layer, and a metal gate over the top dielectric layer. Source and drain regions are in the semiconductor substrate, and are on opposite sides of the gate stack.

A method for fabricating a memory device is provided. In the method, a first gate dielectric layer is formed on a substrate in a first region. A second gate dielectric layer is formed on the substrate in a second region and a third region. A first conductive layer is formed on the substrate. A first dielectric layer is directly formed on the first conductive layer. One portion of the first dielectric layer, one portion of the first conductive layer, and one portion of the second gate dielectric layer in the second region are removed. A third gate dielectric layer and a second conductive layer are formed sequentially on the substrate in the second region. A third conductive layer and a second dielectric layer are formed sequentially on the substrate. Isolation structures are formed in the substrate. Here, the isolation structures penetrate the second dielectric layer and extend into the substrate.

A semiconductor structure and a method for forming the same are provided. The semiconductor structure comprises a substrate, at least a first cell, and at least a second cell. The substrate has a first region and a second region. The first and second cells are in the first and second regions respectively. The first cell comprises a first dielectric layer, a floating gate electrode, an oxide-nitride-oxide (ONO) gate dielectric layer, a second dielectric layer, and a control gate electrode. The ONO gate dielectric layer is on the floating gate electrode in the first dielectric layer on the substrate. The control gate electrode is in both of the first dielectric layer and the second dielectric layer on the first dielectric layer. The ONO gate dielectric layer contacting with the control gate electrode is wholly below a top surface of the first dielectric layer.

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 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.

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.

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.

An integrated circuit structure includes a plurality of flash memory cells forming a memory array, wherein each of the plurality of flash memory cells includes a select gate and a memory gate. A select gate electrode includes a first portion including polysilicon, wherein the first portion forms select gates of a column of the memory array, and a second portion electrically connected to the first portion, wherein the second portion includes a metal. A memory gate electrode has a portion forming memory gates of the column of the memory array.

An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.