A semiconductor device comprises: a substrate including first and second buried source/drain layers; a first nano sheet stack including first nano sheets stacked in a direction vertical to the substrate; a second nano sheet stack including second nano sheets stacked in a direction vertical to the substrate; an isolation wall disposed between the first nano sheet stack and the second nano sheet stack; first gate covering portions of the first nano sheet stack and extending in a direction vertical to the substrate; second gate covering portions of the second nano sheet stack and extending in a direction vertical to the substrate; first common source/drain layers connected to end portions of the first nano sheets and to the first buried source/drain layers; and second common source/drain layers connected to end portions of the second nano sheets and to the second buried source/drain layers.

A semiconductor device comprises: a substrate including first and second buried source/drain layers; a first nano sheet stack including first nano sheets stacked in a direction vertical to the substrate; a second nano sheet stack including second nano sheets stacked in a direction vertical to the substrate; an isolation wall disposed between the first nano sheet stack and the second nano sheet stack; first gate covering portions of the first nano sheet stack and extending in a direction vertical to the substrate; second gate covering portions of the second nano sheet stack and extending in a direction vertical to the substrate; first common source/drain layers connected to end portions of the first nano sheets and to the first buried source/drain layers; and second common source/drain layers connected to end portions of the second nano sheets and to the second buried source/drain layers.

Vertical transistors and methods of manufacturing vertical transistors are disclosed. The method can include forming a stack of layers include a first layer stack of a first transistor structure including at least three layers of a conductive material separated by one or more layers of at least one dielectric material. The stack of layers can include a second layer stack of a second transistor structure including at least three layers of a conductive material separated by one or more layers of at least one dielectric material, the second layer stack associated with a second transistor structure. The first and second transistor structures are separated by one or more dielectric materials. The method can include forming a channel opening in the stack. The method includes selectively forming a first channel structure within the channel opening and selectively forming a second channel structure within the channel opening.

Vertical transistors and methods of manufacturing vertical transistors are disclosed. The method can include forming a stack of layers include a first layer stack of a first transistor structure including at least three layers of a conductive material separated by one or more layers of at least one dielectric material. The stack of layers can include a second layer stack of a second transistor structure including at least three layers of a conductive material separated by one or more layers of at least one dielectric material, the second layer stack associated with a second transistor structure. The first and second transistor structures are separated by one or more dielectric materials. The method can include forming a channel opening in the stack. The method includes selectively forming a first channel structure within the channel opening and selectively forming a second channel structure within the channel opening.

A method includes forming a p-well and an n-well in a substrate. The method further includes forming a stack of interleaving first semiconductor layers and second semiconductor layers over the p-well and the n-well, the first semiconductor layers having a first thickness and the second semiconductor layers having a second thickness different than the first thickness. The method further includes annealing the stack of interleaving semiconductor layers. The method further includes patterning the stack to form fin-shaped structures including a first fin-shaped structure over the n-well and a second fin-shaped structure over the p-well. The method further includes etching to remove the second semiconductor layers from the first and second fin-shaped structures, where the first semiconductor layers have a different thickness within each of the first and second fin-shaped structures after the etching. The method further includes forming a metal gate over the first and second fin-shaped structures.

An integrated circuit (IC) with a semiconductor device and an interconnect structure with carbon layers and methods of fabricating the same are disclosed. The method includes forming a fin structure on a substrate, forming a source/drain region on the fin structure, forming a contact structure on the S/D region, forming an oxide layer on the contact structure, forming a conductive carbon line within a first insulating carbon layer on the oxide layer, forming a second insulating carbon layer on the first insulating carbon layer, and forming a via within the second insulating carbon layer.

The present disclosure relates to a semiconductor structure and a manufacturing method thereof. The method includes providing a substrate, where the substrate includes a device region and a peripheral region; and forming a bit line structure in the device region, and forming a transistor structure in the peripheral region, where the transistor structure includes a gate structure, and the bit line structure includes a bit line conductive layer and a bit line protective layer; the gate structure includes a gate oxide layer, a high-k dielectric layer, a gate conductive layer and a gate protective layer; the gate conductive layer and the bit line conductive layer are obtained by patterning a same conductive material layer, and the bit line protective layer and the gate protective layer are obtained by patterning a same protective material layer.

A forksheet transistor device includes a dual dielectric pillar that includes a first dielectric and a second dielectric that is different from the first dielectric. The dual dielectric pillar physically separates pFET elements from nFET elements. For example, the first dielectric physically separates a pFET gate from a nFET gate while the second dielectric physically separates a pFET source/drain region from a nFET source drain region. When it is advantageous to electrically connect the pFET gate and the nFET gate, the first dielectric may be etched selective to the second dielectric to form a gate connector trench within the dual dielectric pillar. Subsequently, an electrically conductive gate connector strap may be formed within the gate connector trench to electrically connect the pFET gate and the nFET gate.

A forksheet transistor device includes a dual dielectric pillar that includes a first dielectric and a second dielectric that is different from the first dielectric. The dual dielectric pillar physically separates pFET elements from nFET elements. For example, the first dielectric physically separates a pFET gate from a nFET gate while the second dielectric physically separates a pFET source/drain region from a nFET source drain region. When it is advantageous to electrically connect the pFET gate and the nFET gate, the first dielectric may be etched selective to the second dielectric to form a gate connector trench within the dual dielectric pillar. Subsequently, an electrically conductive gate connector strap may be formed within the gate connector trench to electrically connect the pFET gate and the nFET gate.

A semiconductor device includes: a substrate including first and second regions, first and second active patterns in the first and second regions, respectively; first source/drain patterns and a first channel pattern including first semiconductor patterns; second source/drain patterns and a second channel pattern including second semiconductor patterns; first and second gate electrodes on the first and second channel patterns, respectively; and a first gate dielectric layer and a second gate dielectric layer. The first gate dielectric layer includes a first interface layer between the first channel pattern and the first gate electrode, and a first high-k dielectric layer. The second gate dielectric layer includes a second interface layer and a second high-k dielectric layer between the second channel pattern and the second gate electrode. A thickness of the first high-k dielectric layer is greater than that of the second high-k dielectric layer. A thickness of the first semiconductor pattern is less than that of the second semiconductor pattern