High density and program-erasable metal-insulator-silicon capacitor with a dielectric structure of SiO2∕HfO2–Al2O3 nanolaminate∕Al2O3

We demonstrate a program-erasable metal-insulator-silicon capacitor with a dielectric structure of SiO2/HfO2-Al2O3 nanolaminate (HAN)/Al2O3. The memory capacitor exhibits a high capacitance density of 4.5 fF/mu m(2), a large memory window of 1.45 V in the case of +12 V program/-12 V erase for 5 ms, nearly symmetrical positive and negative flatband voltages under the program/erase operations with the same magnitudes of voltage and time, and no erase saturation. This is attributed to the fact that the introduction of atomic-layer-deposited high-dielectric-constant HAN/Al2O3 layers increases the electric field across the tunnel oxide and reduces that across the blocking layer, hence, preventing effectively Fowler-Nordheim tunneling current through the blocking layer. Additionally, we find that the HAN is a promising charge storage layer with sufficient trapping centers for electrons and holes.

High density and program-erasable metal-insulator-silicon capacitor with a dielectric structure of SiO2∕HfO2–Al2O3 nanolaminate∕Al2O3

Synthesis of polysiloxane elastomers modified with sulfonyl side groups and their electromechanical response

Negative Capacitance in HfO2 Gate Stack Structures With and Without Metal Interlayer

Nonlinear electro-mechanical coupling and thermally stimulated currents in relaxor ferroelectrics

Negative Capacitance in HfO2 Gate Stack Structures With and Without Metal Interlayer

Synthesis of polysiloxane elastomers modified with sulfonyl side groups and their electromechanical response

Nonlinear electro-mechanical coupling and thermally stimulated currents in relaxor ferroelectrics