Integrated devices comprising pinched hysteresis loop (PHL) materials in a capacitor or a transistor stack are disclosed. PHL materials include field induced ferroelectrics (FFE), anti-ferroelectric (AFE) and relaxor type ferroelectric (RFE) materials. Each integrated device includes a material stack with a PHL material layer disposed between two electrodes. Application of this material is dependent on inducing of an electric field bias over the stack. According to one option, electrodes having different workfunction values can be employed to induce the required built-in bias field and enable use of PHL materials. According to another option, a PHL material and charges, e.g., a charge interlayer, are disposed between two electrodes such that an induced built-in bias field appears. Integrated devices employing the PHL material stack include memories, transistors, and piezo- and pyroelectric devices.

An oxide semiconductor transistor includes an oxide semiconductor channel layer, a metal gate, a gate insulation layer, an internal electrode, and a ferroelectric material layer. The metal gate is disposed on the oxide semiconductor channel layer. The gate insulation layer is disposed between the metal gate and the oxide semiconductor channel layer. The internal electrode is disposed between the gate insulation layer and the metal gate. The ferroelectric material layer is disposed between the internal electrode and the metal gate. The ferroelectric material layer in the oxide semiconductor transistor of the present invention is used to enhance the electrical characteristics of the oxide semiconductor transistor.

A method for producing a cutting tool, in particular a drill bit, is specified wherein the cutting tool has a front end (F) at the front and a rear end (R) toward the rear, wherein a tool tip is formed on the front end (F), a point thinning is ground at the tool tip with a grinding tool, the point thinning being ground to be narrower toward the front than toward the rear. The point thinning is ground with a constant point thinning angle (AW). Furthermore, a corresponding cutting tool is specified.

In some embodiments, the present disclosure relates to a method of forming an integrated chip including forming a ferroelectric layer over a bottom electrode layer, forming a top electrode layer over the ferroelectric layer, performing a first removal process to remove peripheral portions of the bottom electrode layer, the ferroelectric layer, and the top electrode layer, and performing a second removal process using a second etch that is selective to the bottom electrode layer and the top electrode layer to remove portions of the bottom electrode layer and the top electrode layer, so that after the second removal process the ferroelectric layer has a surface that protrudes past a surface of the bottom electrode layer and the top electrode layer.

The present disclosure relates a device. The device includes a ferroelectric structure having a first side and a second side. A gate structure is disposed along the first side of the ferroelectric structure. An oxide semiconductor is disposed along the second side of the ferroelectric structure and has a first semiconductor conductivity type. A source and a drain are disposed on the oxide semiconductor. A semiconductor layer is arranged on the oxide semiconductor between sidewalls of the source and the drain. The semiconductor layer includes a semiconductor material having a second semiconductor conductivity type that is different than the first semiconductor conductivity type. The semiconductor layer includes p-doped silicon, p-doped germanium, n-doped silicon, or n-doped germanium.

The invention relates to a method for manufacturing a microelectronic circuit. A substrate is provided. A source contact, a bulk contact and a drain contact are each produced for a transistor and for a memory transistor. In a respective common step, an insulating layer of the transistor and an insulating layer of the memory transistor as well as a metal layer of the transistor and a metal layer of the memory transistor are produced. At least one capacitor is produced as part of the memory transistor. Gate contacts connected to the metal layer of the transistor and connected to a metal layer of the capacitor of the memory transistor, respectively, are produced. Furthermore, the invention relates to a microelectronic circuit.

A method of forming an electronic device includes forming an oxygen scavenging layer proximate to a dielectric layer in a gate region of a field effect transistor (FET). The interface layer is between the dielectric layer and a substrate of the FET. The method further includes forming a dipole layer by annealing the oxygen scavenging layer, the dielectric layer, and the interface layer.

The disclosed technology relates generally to non-volatile memory devices, and more particularly to ferroelectric non-volatile memory devices. In one aspect, a non-volatile memory cell includes a pinch-off ferroelectric memory FET and at least one select device electrically connected in series to the pinch-off ferroelectric memory FET.

This disclosure provides a negative capacitance gate stack structure with a variable positive capacitor to implement a hysteresis free negative capacitance field effect transistors (NCFETs) with improved voltage gain. The gate stack structure provides an effective ferroelectric negative capacitor by using the combination of a ferroelectric negative capacitor and the variable positive capacitor with semiconductor material (such as polysilicon), resulting in the effective ferroelectric negative capacitor's being varied with an applied gate voltage. Our simulation results show that the NCFET with the variable positive capacitor can achieve not only a non-hysteretic I.sub.D-V.sub.G curve but also a better sub-threshold slope.

A method used in forming an electronic component comprising conductive material and ferroelectric material comprises forming a non-ferroelectric metal oxide-comprising insulator material over a substrate. A composite stack comprising at least two different composition non-ferroelectric metal oxides is formed over the substrate. The composite stack has an overall conductivity of at least 110.sup.2 Siemens/cm. The composite stack is used to render the non-ferroelectric metal oxide-comprising insulator material to be ferroelectric. Conductive material is formed over the composite stack and the insulator material. Ferroelectric capacitors and ferroelectric field effect transistors independent of method of manufacture are also disclosed.