摘要:
An array of charge-trapping multi-bit memory cells is arranged in a virtual-ground NAND architecture. The memory cells are erased by Fowler-Nordheim tunneling of electrons into the memory layers. The write operation is effected by hot hole injection. A write voltage is applied by a bitline to two NAND chains in series. The subsequent bitline on the side of the memory cell to be programmed is maintained on floating potential, whereas the bitline on the other side is set to an inhibit voltage, which is provided to inhibit a program disturb of an addressed memory cell which is not to be programmed. This virtual-ground NAND architecture of charge-trapping memory cells enables an increased storage density.
摘要:
The charge-trapping layer comprises two strips above the source and drain junctions. The thicknesses of the charge-trapping layer and the gate dielectric are chosen to facilitate Fowler-Nordheim-tunnelling of electrons into the strips during an erasure process. Programming is performed by injection of hot holes into the strips individually for two-bit storage.
摘要:
An array of charge-trapping multi-bit memory cells is arranged in a virtual-ground NAND architecture. The memory cells are erased by Fowler-Nordheim tunneling of electrons into the memory layers. The write operation is effected by hot hole injection. A write voltage is applied by a bitline to two NAND chains in series. The subsequent bitline on the side of the memory cell to be programmed is maintained on floating potential, whereas the bitline on the other side is set to an inhibit voltage, which is provided to inhibit a program disturb of an addressed memory cell which is not to be programmed. This virtual-ground NAND architecture of charge-trapping memory cells enables an increased storage density.
摘要:
The charge-trapping layer comprises two strips above the source and drain junctions. The thicknesses of the charge-trapping layer and the gate dielectric are chosen to facilitate Fowler-Nordheim-tunnelling of electrons into the strips during an erasure process. Programming is performed by injection of hot holes into the strips individually for two-bit storage.
摘要:
To manufacture a memory device, a gate dielectric layer is formed over a semiconductor body and a gate electrode layer is formed over the gate dielectric layer. The gate electrode layer is structured to form a gate electrode with sidewalls. An etching process is performed to remove parts of the gate dielectric layer from beneath the gate electrode on opposite sides of the gate electrode. Boundary layers, e.g., oxide layers, are formed on an upper surface of the semiconductor body and a lower surface of the gate electrode adjacent where the gate dielectric has been removed thereby leaving spaces. Charge-trapping layer material can then be deposited to fill the spaces. Source and drain regions are then formed in the semiconductor body adjacent the gate electrode.
摘要:
To manufacture a memory device, a gate dielectric layer is formed over a semiconductor body and a gate electrode layer is formed over the gate dielectric layer. The gate electrode layer is structured to form a gate electrode with sidewalls. An etching process is performed to remove parts of the gate dielectric layer from beneath the gate electrode on opposite sides of the gate electrode. Boundary layers, e.g., oxide layers, are formed on an upper surface of the semiconductor body and a lower surface of the gate electrode adjacent where the gate dielectric has been removed thereby leaving spaces. Charge-trapping layer material can then be deposited to fill the spaces. Source and drain regions are then formed in the semiconductor body adjacent the gate electrode.
摘要:
A memory device includes an array of memory cells that include a memory element having a non-reactive resistance whose magnitude is programmable to assume a high-resistance state or a low-resistance state. Sets of first and second lines provide access to the memory cells, wherein the memory element of each memory cell is coupled between one of the first lines and one of the second lines. A checking unit determines whether to invert data values to be stored in memory cells coupled to at least a section of respective ones of the first lines based on a number of memory cells that would be programmed in the high-resistance state or the low-resistance state as a result of the data values in order to reduce the number memory cells programmed in the low-resistance state and the resulting leakage current.
摘要:
Transistor bodies of semiconductor material located at a main surface of a semiconductor substrate between shallow trench isolations are provided with a rounded or curved upper surface. A floating gate electrode is arranged above said upper surface and electrically insulated from the semiconductor material by a tunnel dielectric having essentially the same tiny thickness throughout a primary tunnel area encompassing the area of curvature. The floating gate electrode may bridge the transistor body and is covered with a coupling dielectric provided for a control gate electrode, which forms part of a wordline.
摘要:
A memory device includes an array of memory cells that include a memory element having a non-reactive resistance whose magnitude is programmable to assume a high-resistance state or a low-resistance state. Sets of first and second lines provide access to the memory cells, wherein the memory element of each memory cell is coupled between one of the first lines and one of the second lines. A checking unit determines whether to invert data values to be stored in memory cells coupled to at least a section of respective ones of the first lines based on a number of memory cells that would be programmed in the high-resistance state or the low-resistance state as a result of the data values in order to reduce the number memory cells programmed in the low-resistance state and the resulting leakage current.
摘要:
Transistor bodies of semiconductor material located at a main surface of a semiconductor substrate between shallow trench isolations are provided with a rounded or curved upper surface. A floating gate electrode is arranged above said upper surface and electrically insulated from the semiconductor material by a tunnel dielectric having essentially the same tiny thickness throughout a primary tunnel area encompassing the area of curvature. The floating gate electrode may bridge the transistor body and is covered with a coupling dielectric provided for a control gate electrode, which forms part of a wordline.