Abstract: A semiconductor device fabricated in the semiconductor substrate includes a FinFET transistor having opposed source and drain pillars, and a fin interposed between the source and drain pillars. A cavity is formed in the semiconductor substrate extending at least partially between the fin and the semiconductor substrate. The cavity may be formed within a shallow trench isolation structure, and it may also extend at least partially between the semiconductor substrate and one or both of the pillars. The cavities increase the impedance between the semiconductor substrate and the fin and/or pillars to decrease the sub-threshold leakage of the FinFET transistor.

Abstract: Some embodiments include methods of recessing multiple materials to a common depth utilizing etchant comprising C4F6 and C4F3. The recessed materials may be within isolation regions, and the recessing may be utilized to form trenches for receiving gatelines. Some embodiments include structures having an island of semiconductor material laterally surrounded by electrically insulative material. Two gatelines extend across the insulative material and across the island of semiconductor material. One of the gatelines is recessed deeper into the electrically insulative material than the other.

Abstract: A method of forming a vertical field effect transistor includes etching an opening into semiconductor material. Sidewalls and radially outermost portions of the opening base are lined with masking material. A semiconductive material pillar is epitaxially grown to within the opening adjacent the masking material from the semiconductor material at the opening base. At least some of the masking material is removed from the opening. A gate dielectric is formed radially about the pillar. Conductive gate material is formed radially about the gate dielectric. An upper portion of the pillar is formed to comprise one source/drain region of the vertical transistor. Semiconductive material of the pillar received below the upper portion is formed to comprise a channel region of the vertical transistor. Semiconductor material adjacent the opening is formed to comprise another source/drain region of the vertical transistor. Other aspects and implementations are contemplated.

Abstract: Some embodiments include methods of recessing multiple materials to a common depth utilizing etchant comprising C4F6 and C4F8. The recessed materials may be within isolation regions, and the recessing may be utilized to form trenches for receiving gatelines. Some embodiments include structures having an island of semiconductor material laterally surrounded by electrically insulative material. Two gatelines extend across the insulative material and across the island of semiconductor material. One of the gatelines is recessed deeper into the electrically insulative material than the other.

Abstract: Fin-FET (fin field effect transistor) devices and methods of fabrication are disclosed. The Fin-FET devices include dual fin structures that may form a channel region between a source region and a drain region. In some embodiments, the dual fin structures are formed by forming shallow trench isolation structures, using a pair of shallow trench isolation (STI) structures as a mask to define a recess in a portion of the substrate between the pair of STI structures, and recessing the STI structures so that the resulting dual fin structure protrudes from an active surface of the substrate. The dual fin structure may be used to form single-gate, double-gate or triple-gate fin-FET devices. Electronic systems including such fin-FET devices are also disclosed.

Abstract: A semiconductor device fabricated in the semiconductor substrate includes a FinFET transistor having opposed source and drain pillars, and a fin interposed between the source and drain pillars. A cavity is formed in the semiconductor substrate extending at least partially between the fin and the semiconductor substrate. The cavity may be formed within a shallow trench isolation structure, and it may also extend at least partially between the semiconductor substrate and one or both of the pillars. The cavities increase the impedance between the semiconductor substrate and the fin and/or pillars to decrease the sub-threshold leakage of the FinFET transistor.

Abstract: Some embodiments include methods of recessing multiple materials to a common depth utilizing etchant comprising C4F6 and C4F8. The recessed materials may be within isolation regions, and the recessing may be utilized to form trenches for receiving gatelines. Some embodiments include structures having an island of semiconductor material laterally surrounded by electrically insulative material. Two gatelines extend across the insulative material and across the island of semiconductor material. One of the gatelines is recessed deeper into the electrically insulative material than the other.

Abstract: Methods for independently controlling one or more etching parameters in the manufacture of microfeature devices are disclosed herein. One particular embodiment of such a method comprises fabricating a microfeature device on a microfeature workpiece. The workpiece includes a first portion with features having first critical dimensions and a second portion with features having second critical dimensions different than the first critical dimensions. The workpiece also includes a carbon-based layer over at least a portion of the first portion and the second portion. The method includes setting an etching parameter to control the etching process in the first portion of the workpiece relative to and independently of the etching process in the second portion of the workpiece, and etching the carbon-based layer.