A method for manufacturing a semiconductor device includes providing a substrate, a first conductor, a second conductor, a first dielectric, a second dielectric, and a designated region. The first conductor is positioned between the first dielectric and the substrate. The second conductor is positioned between the second dielectric and the substrate. The first designated region is positioned in the substrate. The method includes providing a conductive material layer, which completely covers the first dielectric and the second dielectric. The method includes partially removing the conductive material layer to form a third conductor and a fourth conductor. The first dielectric is positioned between the third conductor and the first conductor. The fourth conductor directly contacts the designated region. The method includes implementing a memory unit using the first conductor and the third conductor and includes implementing a logic unit using the second conductor and the designated region.

After forming a first sacrificial gate stack over a portion of a first semiconductor fin located in a logic device region of a substrate, and a second sacrificial gate stack over a portion of a second semiconductor fin located in a memory device region of the substrate, in which each of the first sacrificial gate stack and the second sacrificial gate stack includes, from bottom to top, a tunneling oxide portion, a floating gate electrode, a control oxide portion, a gate conductor and a gate cap, an entirety of the first sacrificial gate stack is removed to provide a first gate cavity, and only the gate cap and the gate conductor are removed from the second sacrificial gate stack to provide a second gate cavity. Next, a high-k gate dielectric and a gate electrode are formed within each of the first gate cavity and the second gate cavity.

A marked pixel unit includes at least one active element, a first dielectric layer, a color filter unit, a second dielectric layer, and at least one pixel electrode. The active element includes a source, a gate, and a drain. The first dielectric layer is configured to cover the gate. The color filter unit is disposed above the first dielectric layer, and has an alignment opening. The second dielectric layer is disposed above the active element and the color filter unit, and has a contact hole. The pixel electrode is disposed above the second dielectric layer, and electrically connected to the drain through the contact hole. The contact hole of the second dielectric layer is located outside the alignment opening.

After forming a first sacrificial gate stack over a portion of a first semiconductor fin located in a logic device region of a substrate, and a second sacrificial gate stack over a portion of a second semiconductor fin located in a memory device region of the substrate, in which each of the first sacrificial gate stack and the second sacrificial gate stack includes, from bottom to top, a tunneling oxide portion, a floating gate electrode, a control oxide portion, a gate conductor and a gate cap, an entirety of the first sacrificial gate stack is removed to provide a first gate cavity, and only the gate cap and the gate conductor are removed from the second sacrificial gate stack to provide a second gate cavity. Next, a high-k gate dielectric and a gate electrode are formed within each of the first gate cavity and the second gate cavity.

A nonvolatile semiconductor memory device comprises: a substrate; a memory cell that is disposed on the substrate and accumulates a charge as data; and a cover layer covering the memory cell. The cover layer has a structure in which a first silicon nitride layer, an intermediate layer, and a second silicon nitride layer are stacked sequentially from a memory cell side.

Provided is a memory device including a first gate, a second gate and an inter-gate dielectric layer. The first gate is buried in a substrate. The second gate includes metal and is disposed on the substrate. The inter-gate dielectric layer is disposed between the first and second gates. A method of forming a memory device is further provided.