Embodiments of three-dimensional memory device architectures and fabrication methods therefore are disclosed. In an example, the memory device includes a substrate having a first layer stack on it. The first layer stack includes alternating conductor and insulator layers. A second layer stack is disposed over the first layer stack where the second layer stack also includes alternating conductor and insulator layers. One or more vertical structures extend through the first layers stack. A conductive material is disposed on a top surface of the one or more vertical structures. One or more second vertical structures extend through the second layer stack and through a portion of the conductive material.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, sacrificial spacer layers are formed on the plurality of fins, and portions of the semiconductor substrate located under the sacrificial spacer layers and located at sides of the plurality of fins are removed. Bottom source/drain regions are grown in at least part of an area where the portions of the semiconductor substrate were removed, and sacrificial epitaxial layers are grown on the bottom source/drain regions. The method also includes diffusing dopants from the bottom source/drain regions and the sacrificial epitaxial layers into portions of the semiconductor substrate under the plurality of fins. The sacrificial epitaxial layers are removed, and bottom spacers are formed in at least part of an area where the sacrificial epitaxial layers were removed.

A method of forming a fin field effect device is provided. The method includes forming one or more vertical fins on a substrate and a fin template on each of the vertical fins. The method further includes forming a gate structure on at least one of the vertical fins, and a top spacer layer on the at least one gate structure, wherein at least an upper portion of the at least one of the one or more vertical fins is exposed above the top spacer layer. The method further includes forming a top source/drain layer on the top spacer layer and the exposed upper portion of the at least one vertical fin. The method further includes forming a sacrificial spacer on opposite sides of the fin templates and the top spacer layer, and removing a portion of the top source/drain layer not covered by the sacrificial spacer to form a top source/drain electrically connected to the vertical fins.

Some embodiments include a method of forming an integrated assembly. A first stack is formed over a conductive structure. The first stack includes a second layer between first and third layers. The first and third layers are conductive. A first opening is formed through the first stack. A sacrificial material is formed within the first opening. A second stack is formed over the first stack. The second stack has alternating first and second levels. A second opening is formed through the second stack and through the sacrificial material. First semiconductor material is formed within the second opening. A third opening is formed through the second stack, through the third layer, and to the second layer. The second layer is removed, forming a conduit. Second semiconductor material is formed within the conduit. Dopant is out-diffused from the second semiconductor material into the first semiconductor material. Some embodiments include integrated assemblies.

Embodiments of three-dimensional memory device architectures and fabrication methods therefore are disclosed. In an example, the memory device includes a substrate having a first layer stack on it. The first layer stack includes alternating conductor and insulator layers. A second layer stack is disposed over the first layer stack where the second layer stack also includes alternating conductor and insulator layers. One or more vertical structures extend through the first layers stack. A conductive material is disposed on a top surface of the one or more vertical structures. One or more second vertical structures extend through the second layer stack and through a portion of the conductive material.

A method of forming a fin field effect device is provided. The method includes forming one or more vertical fins on a substrate and a fin template on each of the vertical fins. The method further includes forming a gate structure on at least one of the vertical fins, and a top spacer layer on the at least one gate structure, wherein at least an upper portion of the at least one of the one or more vertical fins is exposed above the top spacer layer. The method further includes forming a top source/drain layer on the top spacer layer and the exposed upper portion of the at least one vertical fin. The method further includes forming a sacrificial spacer on opposite sides of the fin templates and the top spacer layer, and removing a portion of the top source/drain layer not covered by the sacrificial spacer to form a top source/drain electrically connected to the vertical fins.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, sacrificial spacer layers are formed on the plurality of fins, and portions of the semiconductor substrate located under the sacrificial spacer layers and located at sides of the plurality of fins are removed. Bottom source/drain regions are grown in at least part of an area where the portions of the semiconductor substrate were removed, and sacrificial epitaxial layers are grown on the bottom source/drain regions. The method also includes diffusing dopants from the bottom source/drain regions and the sacrificial epitaxial layers into portions of the semiconductor substrate under the plurality of fins. The sacrificial epitaxial layers are removed, and bottom spacers are formed in at least part of an area where the sacrificial epitaxial layers were removed.

A method of doping a silicon-containing material. The method comprises forming at least one opening in a silicon-containing material and conformally forming a doped germanium material in the at least one opening and adjacent to the silicon-containing material. A dopant of the doped germanium material is transferred into the silicon-containing material. Methods of forming a semiconductor device are also disclosed, as are semiconductor devices comprising a doped silicon-containing material.

A method of manufacturing a semiconductor device according to an embodiment of the present disclosure may include forming a first sacrificial layer including a first portion and a second portion having a thickness thicker than a thickness of the first portion, forming a stack including first material layers and second material layers alternating with each other on the first sacrificial layer, forming a channel structure passing through the stack and extending to the first portion, forming a slit passing through the stack and extending to the second portion, removing the first sacrificial layer through the slit to form a first opening, and forming a second source layer connected to the channel structure in the first opening.

Some embodiments include a method of forming an integrated assembly. A first stack is formed over a conductive structure. The first stack includes a second layer between first and third layers. The first and third layers are conductive. A first opening is formed through the first stack. A sacrificial material is formed within the first opening. A second stack is formed over the first stack. The second stack has alternating first and second levels. A second opening is formed through the second stack and through the sacrificial material. First semiconductor material is formed within the second opening. A third opening is formed through the second stack, through the third layer, and to the second layer. The second layer is removed, forming a conduit. Second semiconductor material is formed within the conduit. Dopant is out-diffused from the second semiconductor material into the first semiconductor material. Some embodiments include integrated assemblies.