Abstract: A mask ROM fabrication method which comprises steps: sequentially forming a gate dielectric layer and a first photoresist layer on a substrate; letting a light having a wavelength of 365 nm pass through a first phase shift mask to photolithographically form on the first photoresist layer a plurality of first trenches having a width of 243-365 nm; doping the substrate to form a plurality of embedded bit lines having a width of 243-365 nm; removing the first photoresist layer; sequentially forming a polysilicon layer and a second photoresist layer on the gate dielectric layer; and letting the light pass through a second phase shift mask to photolithographically form a plurality of polysilicon word lines on the polysilicon layer. Thereby is reduced the line width of mask ROM to 243-365 nm and decreased the area of mask ROM.

Abstract: A method of growing an epitaxial silicon layer is provided. The method comprising providing a substrate including an oxygen-terminated silicon surface and forming a first hydrogen-terminated silicon surface on the oxygen-terminated silicon surface. Additionally, the method includes forming a second hydrogen-terminated silicon surface on the first hydrogen-terminated silicon surface through atomic-layer deposition (ALD) epitaxy from SiH4 thermal cracking radical assisted by Ar flow and flash lamp annealing continuously. The second hydrogen-terminated silicon surface is capable of being added one or more layer of silicon through ALD epitaxy from SiH4 thermal cracking radical assisted by Ar flow and flash lamp annealing continuously. In one embodiment, the method is applied for making devices with thin-film transistor (TFT) floating gate memory cell structures which is capable for three-dimensional integration.

Abstract: A mask ROM, a method for fabricating the same and a method for coding the same are disclosed. The method for forming the mask ROM maximizes packing density and integration of a device. The mask ROM includes a semiconductor substrate having a device isolation region and an active region, BN junction regions formed in predetermined portions of the active region, an insulating film, first electrode layers formed on predetermined portions of the insulating film, spacers formed at sides of the first electrode layers, and second electrode layers between the spacers.

Abstract: A silicon-on-insulator (SOI) Read Only Memory (ROM), and a method of making the SOI ROM. ROM cells are located at the intersections of stripes in the surface SOI layer with orthogonally oriented wires on a conductor layer. Contacts from the wires connect to ROM cell diodes in the upper surface of the stripes. ROM cell personalization is the presence or absence of a diode and/or contact.

Abstract: There is provided a monolithic three dimensional TFT mask ROM array. The array includes a plurality of device levels. Each of the plurality of device levels contains a first set of enabled TFTs and a second set of partially or totally disabled TFTs.

Abstract: A silicon-on-insulator (SOI) Read Only Memory (ROM), and a method of making the SOI ROM. ROM cells are located at the intersections of stripes in the surface SOI layer with orthogonally oriented wires on a conductor layer. Contacts from the wires connect to ROM cell diodes in the upper surface of the stripes. ROM cell personalization is the presence or absence of a diode and/or contact.

Abstract: A memory capable of reducing the memory cell size is provided. This memory comprises a plurality of memory cells including diodes, a plurality of bit lines and an n-type impurity region arranged to intersect with the bit lines for functioning as cathodes of the diodes included in the memory cells and a word line. The n-type impurity region is divided every bit line group formed by a prescribed number of bit lines.

Abstract: There is provided a monolithic three dimensional TFT mask ROM array. The array includes a plurality of device levels. Each of the plurality of device levels contains a first set of enabled TFTs and a second set of partially or totally disabled TFTs.

Abstract: The present invention relates to a multi-level read only memory cell that can store two bits and the fabrication method thereof. The multi-level ROM cell has the storage capacity of two bits and the resultant NAND type ROM memory array can provide four logic states of two bits, thus increasing the data storage capacity.