A semiconductor memory structure and a method of manufacturing a semiconductor memory structure are provided. The semiconductor memory structure includes alternatively arranged stacking portions and cell regions. Each cell region includes two ferroelectric layers formed along the adjacent stacking portions; and at least one central portion disposed between the ferroelectric layers and includes a first conductive structure and a second conductive structure separated by a channel isolation structure as well as two semiconductor layers formed along the ferroelectric layers. The first conductive structure includes a contact portion and an extension portion. The contact portion is disposed between the semiconductor layers. The extension portion extends from the contact portion to the channel isolation structure and is separated from the semiconductor layers through dielectric layers.

A memory device, a semiconductor device and manufacturing methods for forming the memory device and the semiconductor device are provided. The memory device include a stacking structure, a switching layer, channel layers and pairs of conductive pillars. The stacking structure includes alternately stacked isolation layers and word lines, and extends along a first direction. The stacking structure has a staircase portion and a connection portion at an edge region of the stacking structure. The connection portion extends along the staircase portion and located aside the staircase portion, and may not be shaped into a staircase structure. The switching layer covers a sidewall of the stacking structure. The channel layers cover a sidewall of the switching layer, and are laterally spaced apart from one another along the first direction. The pairs of conductive pillars stand on the substrate, and in lateral contact with the switching layer through the channel layers.

A ferroelectric transistor includes a semiconductor channel comprising a semiconductor material, a strained and/or defect containing ferroelectric gate dielectric layer located on a surface of the semiconductor channel, a source region located on a first end portion of the semiconductor channel, and a drain region located on a second end portion of the semiconductor channel.

A semiconductor structure contains a semiconductor channel extending between a source region and a drain region, at least one gate electrode, a ferroelectric material portion located between the semiconductor channel and the at least one gate electrode, a front-side gate dielectric located between the ferroelectric material portion and the semiconductor channel, and a backside gate dielectric located between the ferroelectric material portion and the at least one gate electrode. The front-side gate dielectric and the backside gate dielectric have a dielectric constant greater than 7.9 and a band gap greater than a band gap of the ferroelectric material portion.

A memory device includes a multi-layer stack including a plurality of first conductive lines and a plurality of second conductive lines. The first conductive lines are stacked on one another. The second conductive lines cross over the plurality of first conductive lines, wherein widths of the plurality of second conductive lines are increased as the plurality of second conductive lines become close to a middle portion of the multi-layer stack.

A test structure for 3D memory arrays and methods of forming the same are disclosed. In an embodiment, a memory array includes a first word line over a semiconductor substrate and extending in a first direction; a second word line over the first word line and extending in the first direction; a memory film contacting the first word line and the second word line; an oxide semiconductor (OS) layer contacting a first source line and a first bit line, the memory film being between the OS layer and each of the first word line and the second word line; and a test structure over the first word line and the second word line, the test structure including a first conductive line electrically coupling the first word line to the second word line, the first conductive line extending in the first direction.

A semiconductor die comprises a device portion comprising: an array of active memory devices extending in a first direction, and interface portions located adjacent to axial ends of the device portion in the first direction. The interface portions have a staircase profile in a vertical direction and comprise an array of dummy memory devices and an array of gate vias. The dummy memory devices are axially aligned with the active memory devices in the first direction, each dummy memory device comprising at least one interface via. Moreover, each row of the array of gate vias extends in the first direction and is located parallel to a row of the array of dummy memory devices in a second direction perpendicular to the first direction. Each gate via is electrically coupled to the at least one interface via of a dummy memory device located adjacent thereto.

A semiconductor die comprises a device portion comprising: an array of active memory devices extending in a first direction, and interface portions located adjacent to axial ends of the device portion in the first direction. The interface portions have a staircase profile in a vertical direction and comprise an array of dummy memory devices and an array of gate vias. The dummy memory devices are axially aligned with the active memory devices in the first direction, each dummy memory device comprising at least one interface via. Moreover, each row of the array of gate vias extends in the first direction and is located parallel to a row of the array of dummy memory devices in a second direction perpendicular to the first direction. Each gate via is electrically coupled to the at least one interface via of a dummy memory device located adjacent thereto.

A memory device, a semiconductor device and manufacturing methods for forming the memory device and the semiconductor device are provided. The memory device include a stacking structure, a switching layer, channel layers and pairs of conductive pillars. The stacking structure includes alternately stacked isolation layers and word lines, and extends along a first direction. The stacking structure has a staircase portion and a connection portion at an edge region of the stacking structure. The connection portion extends along the staircase portion and located aside the staircase portion, and may not be shaped into a staircase structure. The switching layer covers a sidewall of the stacking structure. The channel layers cover a sidewall of the switching layer, and are laterally spaced apart from one another along the first direction. The pairs of conductive pillars stand on the substrate, and in lateral contact with the switching layer through the channel layers.

A memory opening or a line trench is formed through an alternating stack of insulating layers and sacrificial material layers. A memory opening fill structure or a memory stack assembly is formed, which includes a vertical stack of discrete intermediate metallic electrodes formed on sidewalls of the sacrificial material layers, a gate dielectric layer, and a vertical semiconductor channel. Backside recesses are formed by removing the sacrificial material layers selective to the insulating layers, and a combination of a ferroelectric dielectric layer and an electrically conductive layer within each of the backside recesses. The electrically conductive layer is laterally spaced from a respective one of the discrete intermediate metallic electrodes by the ferroelectric dielectric layer. Ferroelectric-metal-insulator memory elements are formed around the vertical semiconductor channel.