Embodiments provide a memory device and a method for fabricating the same, relating to the field of semiconductor technology. The method includes: forming buried gate structures in a first direction in a substrate; patterning the substrate, cutting off the buried gate structures, and forming active structures arranged at parallel intervals and isolation grooves between the active structures in a second direction, where the active structures are island-shaped columnar bodies, and the active structures include the buried gate structures; forming isolation structures in the isolation grooves, where surfaces of the isolation structures are flush with surfaces of the active structures; and forming conductive word lines in the first direction on the surfaces of isolation structures and the surfaces of the active structures, where the conductive word lines cover upper surfaces of the buried gate structures in the active structures.

A memory device includes a page made up of plural memory cells arranged in a column on a substrate, and a page write operation is performed to hold positive hole groups generated by an impact ionization phenomenon, in a channel semiconductor layer by controlling voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity region, and a second impurity region of each memory cell contained in the page and a page erase operation is performed to remove the positive hole groups out of the channel semiconductor layer by controlling voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity region, and the second impurity region. The first impurity layer of the memory cell is connected with a source line, the second impurity layer is connected with a bit line, one of the first gate conductor layer and the second gate conductor layer is connected with a word line, and another is connected with a drive control line; during the write operation after the page erase operation, the positive hole group is formed in the channel semiconductor layer by an impact ionization phenomenon by controlling voltages applied to the word line, the drive control line, the source line, and the bit line; and an applied voltage/applied voltages of one or both of the word line and the drive control line is/are lowered with drops in a first threshold voltage of the first gate conductor layer and a second threshold voltage of the second gate conductor layer.

A microelectronic device comprises a base structure, a memory array overlying the base structure, and a conductive pad tier overlying the memory array. The base structure comprises a logic region including logic devices. The memory array comprises vertically extending strings of memory cells within a horizontal area of the logic region of the base structure. The conductive pad tier comprises first conductive pads substantially outside of the horizontal area of the logic region of the base structure, and second conductive pads horizontally neighboring the first conductive pads and within the horizontal area of the logic region of the base structure. Memory devices and electronic systems are also described.

A microelectronic device comprises a base structure, a memory array overlying the base structure, and a conductive pad tier overlying the memory array. The base structure comprises a logic region including logic devices. The memory array comprises vertically extending strings of memory cells within a horizontal area of the logic region of the base structure. The conductive pad tier comprises first conductive pads substantially outside of the horizontal area of the logic region of the base structure, and second conductive pads horizontally neighboring the first conductive pads and within the horizontal area of the logic region of the base structure. Memory devices and electronic systems are also described.

A apparatus includes a memory cell region; a peripheral region adjacent to the memory cell region; first, second, third, fourth and fifth bit-lines arranged in numerical order and extending across the memory cell region and the peripheral region; and first, second and third bit-line contacts connecting with the first, third and fifth bit-lines in the peripheral region, respectively; wherein the first and second bit-line contacts are arranged adjacently without interposing the second bit-line therebetween; and wherein the second and third bit-line contacts are arranged adjacently with interposing the fourth bit-line therebetween.

A apparatus includes a memory cell region; a peripheral region adjacent to the memory cell region; first, second, third, fourth and fifth bit-lines arranged in numerical order and extending across the memory cell region and the peripheral region; and first, second and third bit-line contacts connecting with the first, third and fifth bit-lines in the peripheral region, respectively; wherein the first and second bit-line contacts are arranged adjacently without interposing the second bit-line therebetween; and wherein the second and third bit-line contacts are arranged adjacently with interposing the fourth bit-line therebetween.

A method includes forming a plurality of first line-shaped mask patterns over a substrate including a memory cell region and an array edge region; forming a plurality of second line-shaped mask patterns over the plurality of first line-shaped mask patterns; removing first portions from the plurality of first line-shaped mask patterns in the memory cell region to leave a plurality of island-shaped mask patterns above the memory cell region; removing second portions from the plurality of first line-shaped mask patterns in the array edge region to leave a holes-provided mask pattern above the array edge region; forming a mask pattern which includes a plurality of holes provided on portions; and forming, with the mask pattern which includes the plurality of holes, a plurality of contact holes in the array edge region to provide a plurality of contact electrodes connected to a plurality of word-lines.

A method includes forming a plurality of first line-shaped mask patterns over a substrate including a memory cell region and an array edge region; forming a plurality of second line-shaped mask patterns over the plurality of first line-shaped mask patterns; removing first portions from the plurality of first line-shaped mask patterns in the memory cell region to leave a plurality of island-shaped mask patterns above the memory cell region; removing second portions from the plurality of first line-shaped mask patterns in the array edge region to leave a holes-provided mask pattern above the array edge region; forming a mask pattern which includes a plurality of holes provided on portions; and forming, with the mask pattern which includes the plurality of holes, a plurality of contact holes in the array edge region to provide a plurality of contact electrodes connected to a plurality of word-lines.

A memory device includes a memory array, a circuit structure, a bonding structure between the memory array and the circuit structure, and a shielding structure between the memory array and the circuit structure and surrounding the bonding structure. The bonding structure includes a first bonding pattern and a second bonding pattern. The circuit structure is electrically connected with the memory array through the bonding structure. The shielding structure includes a third bonding pattern and a fourth bonding pattern. The first bonding pattern is in contact with the second bonding pattern at a first interface between the first bonding pattern and the second bonding pattern. The third bonding pattern is in contact with the fourth bonding pattern at a second interface between the third bonding pattern and the fourth bonding pattern.

A memory device includes a memory array, a circuit structure, a bonding structure between the memory array and the circuit structure, and a shielding structure between the memory array and the circuit structure and surrounding the bonding structure. The bonding structure includes a first bonding pattern and a second bonding pattern. The circuit structure is electrically connected with the memory array through the bonding structure. The shielding structure includes a third bonding pattern and a fourth bonding pattern. The first bonding pattern is in contact with the second bonding pattern at a first interface between the first bonding pattern and the second bonding pattern. The third bonding pattern is in contact with the fourth bonding pattern at a second interface between the third bonding pattern and the fourth bonding pattern.