A fabricating method of a semiconductor device is provided. A temporary semiconductor structure is provided. The temporary semiconductor structure includes a temporary substrate and a conductive layer, the temporary substrate has a first surface, the conductive layer is disposed on the first surface of the temporary substrate, and the conductive layer includes one or more first trace. Then, a recess is formed in the temporary semiconductor structure to form a first semiconductor structure and a first substrate. The recess penetrates through the first substrate and expose the one or more first trace. Thereafter, an input/output pad is formed in the recess and on the one or more first trace.

A fabricating method of a semiconductor device is provided. A temporary semiconductor structure is provided. The temporary semiconductor structure includes a temporary substrate and a conductive layer, the temporary substrate has a first surface, the conductive layer is disposed on the first surface of the temporary substrate, and the conductive layer includes one or more first trace. Then, a recess is formed in the temporary semiconductor structure to form a first semiconductor structure and a first substrate. The recess penetrates through the first substrate and expose the one or more first trace. Thereafter, an input/output pad is formed in the recess and on the one or more first trace.

A semiconductor storage device includes first and second chips and first and second power supply electrodes. The first chip includes conductive layers arranged in a first direction, a semiconductor pillar extending in the first direction and facing the conductive layers, first contacts extending in the first direction and connected to the conductive layers, second contacts extending in the first direction and connected to a first power supply electrode, third contacts extending in the first direction, facing the second contacts in a direction crossing the first direction, and connected to the second power supply electrode, and first bonding electrodes connected to the first contacts. The second chip includes a semiconductor substrate, transistors provided on the semiconductor substrate, fourth contacts connected to the transistors, and second bonding electrodes connected to the fourth contacts. The first and second chips are bonded together so that respective first and second bonding electrodes are connected together.

A semiconductor memory device includes a substrate with a cell array region and a connection region, an electrode structure including electrodes stacked on the substrate and having a staircase structure on the connection region, a vertical channel structure on the cell array region to penetrate the electrode structure and electrically connected to the substrate, a dummy structure on the connection region to penetrate the staircase structure, and a first sidewall oxide pattern interposed between the substrate and the dummy structure. The dummy structure includes an upper portion that is on the substrate, a middle portion that is in contact with the first sidewall oxide pattern, and a lower portion that is below the middle portion. With increasing vertical distance from the upper portion, a diameter of the middle portion decreases until it reaches its smallest value and then increases.

A semiconductor memory device includes a substrate with a cell array region and a connection region, an electrode structure including electrodes stacked on the substrate and having a staircase structure on the connection region, a vertical channel structure on the cell array region to penetrate the electrode structure and electrically connected to the substrate, a dummy structure on the connection region to penetrate the staircase structure, and a first sidewall oxide pattern interposed between the substrate and the dummy structure. The dummy structure includes an upper portion that is on the substrate, a middle portion that is in contact with the first sidewall oxide pattern, and a lower portion that is below the middle portion. With increasing vertical distance from the upper portion, a diameter of the middle portion decreases until it reaches its smallest value and then increases.

Embodiments of three-dimensional (3D) memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a memory stack on the substrate, a plurality of channel structures each extending vertically through the memory stack, an isolation structure, and an alignment mark. The memory stack includes a plurality of interleaved conductive layers and dielectric layers. An outmost one of the conductive layers toward the substrate is a source select gate line (SSG). The isolation structure extends vertically into the substrate and surrounds at least one of the channel structures in a plan view to separate the SSG and the at least one channel structure. The alignment mark extends vertically into the substrate and is coplanar with the isolation structure.

A semiconductor device may include a first pattern. The semiconductor device may include a second pattern intersecting with the first pattern and including an intersection region with the first pattern and a non-intersection region.

A vertical memory device includes a substrate including a cell region and a peripheral circuit region, gate electrodes sequentially stacked on the cell region of the substrate in a vertical direction substantially perpendicular to an upper surface of the substrate, a channel on the cell region and extending through the gate electrodes in the vertical direction, a first lower contact plug on the peripheral circuit region and extending in the vertical direction, a second lower contact plug on the peripheral circuit region adjacent to the first lower contact plug and extending in the vertical direction, and a first upper wiring electrically connected to the first lower contact plug. The first upper wiring is configured to and apply an electrical signal to the first lower contact plug. The second lower contact plug is not electrically connected to an upper wiring configured to apply an electrical signal.

Apparatus might include an array of memory cells and a controller to perform access operations on the array of memory cells. The controller might be configured to establish a negative potential in a body of a memory cell of the array of memory cells, and initiate a sensing operation on the memory cell while the body of the memory cell has the negative potential. Apparatus might further include an array of memory cells, a timer, and a controller to perform access operations on the array of memory cells. The controller might be configured to advance the timer, and establish a negative potential in a body of a memory cell of the array of memory cells in response to a value of the timer having a desired value.

Apparatus might include an array of memory cells and a controller to perform access operations on the array of memory cells. The controller might be configured to establish a negative potential in a body of a memory cell of the array of memory cells, and initiate a sensing operation on the memory cell while the body of the memory cell has the negative potential. Apparatus might further include an array of memory cells, a timer, and a controller to perform access operations on the array of memory cells. The controller might be configured to advance the timer, and establish a negative potential in a body of a memory cell of the array of memory cells in response to a value of the timer having a desired value.