Abstract: Some embodiments include memory cells having vertically-stacked charge-trapping zones spaced from one another by dielectric material. The dielectric material may comprise high-k material. One or more of the charge-trapping zones may comprise metallic material. Such metallic material may be present as a plurality of discrete isolated islands, such as nanodots. Some embodiments include methods of forming memory cells in which two charge-trapping zones are formed over tunnel dielectric, with the zones being vertically displaced relative to one another, and with the zone closest to the tunnel dielectric having deeper traps than the other zone. Some embodiments include electronic systems comprising memory cells. Some embodiments include methods of programming memory cells having vertically-stacked charge-trapping zones.

Abstract: The invention includes methods of forming PMOS transistors and NMOS transistors. The NMOS transistors can be formed to have a thin silicon-containing material between a pair of metal nitride materials, while the PMOS transistors are formed to have the metal nitride materials directly against one another. The invention also includes constructions which contain an NMOS transistor gate stack having a thin silicon-containing material between a pair of metal nitride materials. The silicon-containing material can, for example, consist of silicon, conductively-doped silicon, or silicon oxide; and can have a thickness of less than or equal to about 30 angstroms.

Abstract: The invention includes semiconductor processing methods in which openings are formed to extend into a semiconductor substrate, and the substrate is then annealed around the openings to form cavities. The substrate is etched to expose the cavities, and the cavities are substantially filled with insulative material. The semiconductor substrate having the filled cavities therein can be utilized as a semiconductor-on-insulator-type structure, and transistor devices can be formed to be supported by the semiconductor material and to be over the cavities. In some aspects, the transistor devices have channel regions over the filled cavities, and in other aspects the transistor devices have source/drain regions over the filled cavities. The transistor devices can be incorporated into dynamic random access memory, and can be utilized in electronic systems.

Abstract: The invention includes semiconductor processing methods in which openings are formed to extend into a semiconductor substrate, and the substrate is then annealed around the openings to form cavities. The substrate is etched to expose the cavities, and the cavities are substantially filled with insulative material. The semiconductor substrate having the filled cavities therein can be utilized as a semiconductor-on-insulator-type structure, and transistor devices can be formed to be supported by the semiconductor material and to be over the cavities. In some aspects, the transistor devices have channel regions over the filled cavities, and in other aspects the transistor devices have source/drain regions over the filled cavities. The transistor devices can be incorporated into dynamic random access memory, and can be utilized in electronic systems.

Abstract: A transistor gate forming method includes forming a first and a second transistor gate. Each of the two gates includes a lower metal layer and an upper metal layer. The lower metal layer of the first gate originates from an as-deposited material exhibiting a work function the same as exhibited in an as-deposited material from which the lower metal layer of the second gate originates. However, the first gate's lower metal layer exhibits a modified work function different from a work function exhibited by the second gate's lower metal layer. The first gate's lower metal layer may contain less oxygen and/or carbon in comparison to the second gate's lower metal layer. The first gate's lower metal layer may contain more nitrogen in comparison to the second gate's lower metal layer. The first gate may be a n-channel gate and the second gate may be a p-channel gate.