The improvement of the reliability of a semiconductor device having a split gate type MONOS memory is implemented. An ONO film and a second polysilicon film are sequentially formed so as to fill between a first polysilicon film and a dummy gate electrode. Then, the dummy gate electrode is removed. Then, the top surfaces of the first and second polysilicon films are polished, thereby to form a memory gate electrode formed of the second polysilicon film at the sidewall of a control gate electrode formed of the first polysilicon film via the ONO film. As a result, the memory gate electrode high in perpendicularity of the sidewall, and uniform in film thickness is formed.

A memory device may include: a memory cell array including a plurality of memory cells; and a control circuit suitable for programming the memory cell array. The control circuit may program the memory cell array according to a predetermined coding method, such that read voltage levels for multi-sensing are minimized and the numbers of read operations for logical pages are distributed. Therefore, the memory device can improve the cell distribution for the plurality of memory cells and the performance of read timing.

A semiconductor device includes a first storage unit including twin cells which are electrically rewritable and complementarily store 1-bit data based on a difference in a threshold voltage, a second storage unit including a memory cell which is electrically rewritable, data stored in the memory cell being erased when data in the twin cells is erased, at least one scrambler subjecting first data to a scramble processing by using scramble data to generate second data, a first write circuit which writes the second data into the twin cells in the first storage unit, a second write circuit which writes the scramble data into the memory cell in the second storage unit, and at least one descrambler subjecting the second data read from the first storage unit to a descramble processing by using the scramble data read from the second storage unit.

A method for reading data stored in a flash memory includes at least the following steps: controlling the flash memory to perform a plurality of read operations upon a plurality of memory cells included in the flash memory; obtaining a plurality of bit sequences read from the memory cells, respectively, wherein the read operations read bits of a predetermined bit order from the memory cells by utilizing different control gate voltage settings; and determining readout information of the memory cells according to binary digit distribution characteristics of the bit sequences.

When a control circuit has received a first erase command, the control circuit controls performing a first pre-write process to allow a first storage device and a second storage device to have threshold voltages, respectively, both increased, and the control circuit thereafter controls performing an erase process to allow the first storage device and the second storage device to have their respective threshold voltages both decreased to be smaller than a prescribed erase verify level. When the control circuit has received a second erase command, the control circuit controls performing a second pre-write process to allow one of the first storage device and the second storage device to have its threshold voltage increased, and control circuit subsequently controls performing the erase process.

An insulating film configuring an uppermost layer of a gate insulating film of a memory cell comprises a silicon oxide film and is a layer to which a metal or metal oxide is added. A formation step of the insulating film comprises the steps of: forming the silicon oxide film; and adding the metal or the metal oxide in an atomic or molecular state by a sputtering process onto the silicon oxide film. Oxide of the metal has a higher dielectric constant than silicon oxide, and the metal oxide has a higher dielectric constant than silicon oxide. A High-K added layer is thus used as the insulating film configuring the gate insulating film of the memory cell, thereby a high saturation level of a threshold voltage can be maintained while a drive voltage (applied voltage for erase or write) is reduced, leading to improvement in reliability of the memory cell.

The improvement of the reliability of a semiconductor device having a split gate type MONOS memory is implemented. An ONO film and a second polysilicon film are sequentially formed so as to fill between a first polysilicon film and a dummy gate electrode. Then, the dummy gate electrode is removed. Then, the top surfaces of the first and second polysilicon films are polished, thereby to form a memory gate electrode formed of the second polysilicon film at the sidewall of a control gate electrode formed of the first polysilicon film via the ONO film. As a result, the memory gate electrode high in perpendicularity of the sidewall, and uniform in film thickness is formed.

A content addressable memory cell includes a first floating body transistor and a second floating body transistor. The first floating body transistor and the second floating body transistor are electrically connected in series through a common node. The first floating body transistor and the second floating body transistor store complementary data.

The disclosed technology relates generally to non-volatile memory devices, and more particularly to ferroelectric non-volatile memory devices. In one aspect, a non-volatile memory cell includes a pinch-off ferroelectric memory FET and at least one select device electrically connected in series to the pinch-off ferroelectric memory FET.

A content addressable memory cell includes a first floating body transistor and a second floating body transistor. The first floating body transistor and the second floating body transistor are electrically connected in series through a common node. The first floating body transistor and the second floating body transistor store complementary data.