A method for fabricating a crown capacitor includes: forming a first supporting layer over a substrate; forming a second supporting layer above the first supporting layer; alternately stacking first and second sacrificial layers between the first and second supporting layers to collectively form a stacking structure; forming a recess extending through the stacking structure; performing an etching process to the first sacrificial layers at a first etching rate and the second sacrificial layers at a second etching rate greater than the first etching rate, such that each second sacrificial layer and immediately-adjacent two of the first sacrificial layers collectively define a concave portion; forming a first electrode layer over a surface of the recess in which the first electrode layer has a wavy structure; removing the first and second sacrificial layers; and forming a dielectric layer and a second electrode layer over the first electrode layer.

A method for fabricating a crown capacitor includes: forming a first supporting layer over a substrate; forming a second supporting layer above the first supporting layer; alternately stacking first and second sacrificial layers between the first and second supporting layers to collectively form a stacking structure; forming a recess extending through the stacking structure; performing an etching process to the first sacrificial layers at a first etching rate and the second sacrificial layers at a second etching rate greater than the first etching rate, such that each second sacrificial layer and immediately-adjacent two of the first sacrificial layers collectively define a concave portion; forming a first electrode layer over a surface of the recess in which the first electrode layer has a wavy structure; removing the first and second sacrificial layers; and forming a dielectric layer and a second electrode layer over the first electrode layer.

A selector device may include a first electrode, a tunneling layer, and a ferroelectric layer. The tunneling layer may be between the first electrode and the ferroelectric layer, and a thickness and dielectric constant of the tunneling layer relative to a thickness and dielectric constant of the ferroelectric layer may cause a depolarizing electric field induced in the first tunneling layer to be greater than or approximately equal to an electric field induced in an opposite direction by ferroelectric dipoles in the ferroelectric layer when a voltage is applied across the selector device. The device may also include a second electrode, and the ferroelectric layer may be between the tunneling layer and the second electrode. A second ing layer may also be added between the ferroelectric layer and the second electrode for bipolar selectors.

A selector device may include a first electrode, a tunneling layer, and a ferroelectric layer. The tunneling layer may be between the first electrode and the ferroelectric layer, and a thickness and dielectric constant of the tunneling layer relative to a thickness and dielectric constant of the ferroelectric layer may cause a depolarizing electric field induced in the first tunneling layer to be greater than or approximately equal to an electric field induced in an opposite direction by ferroelectric dipoles in the ferroelectric layer when a voltage is applied across the selector device. The device may also include a second electrode, and the ferroelectric layer may be between the tunneling layer and the second electrode. A second ing layer may also be added between the ferroelectric layer and the second electrode for bipolar selectors.

A method for fabricating a crown capacitor includes: forming a first supporting layer over a substrate; forming a second supporting layer above the first supporting layer; alternatively stacking first and second sacrificial layers between the first and second supporting layers to collectively form a stacking structure; forming a recess extending through the stacking structure; performing an etching process to the first sacrificial layers at a first etching rate and the second sacrificial layers at a second etching rate greater than the first etching rate, such that each second sacrificial layer and immediately-adjacent two of the first sacrificial layers collectively define a concave portion; forming a first electrode layer over a surface of the recess in which the first electrode layer has a wavy structure; removing the first and second sacrificial layers; and forming a dielectric layer and a second electrode layer over the first electrode layer.

Multi-gate NOR flash thin-film transistor (TFT) string arrays are organized as three dimensional stacks of active strips. Each active strip includes a shared source sublayer and a shared drain sublayer that is connected to substrate circuits. Data storage in the active strip is provided by charge-storage elements between the active strip and a multiplicity of control gates provided by adjacent local word-lines. The parasitic capacitance of each active strip is used to eliminate hard-wire ground connection to the shared source making it a semi-floating, or virtual source. Pre-charge voltages temporarily supplied from the substrate through a single port per active strip provide the appropriate voltages on the source and drain required during read, program, program-inhibit and erase operations. TFTs on multiple active strips can be pre-charged separately and then read, programmed or erased together in a massively parallel operation.

Multi-gate NOR flash thin-film transistor (TFT) string arrays are organized as three dimensional stacks of active strips. Each active strip includes a shared source sublayer and a shared drain sublayer that is connected to substrate circuits. Data storage in the active strip is provided by charge-storage elements between the active strip and a multiplicity of control gates provided by adjacent local word-lines. The parasitic capacitance of each active strip is used to eliminate hard-wire ground connection to the shared source making it a semi-floating, or virtual source. Pre-charge voltages temporarily supplied from the substrate through a single port per active strip provide the appropriate voltages on the source and drain required during read, program, program-inhibit and erase operations. TFTs on multiple active strips can be pre-charged separately and then read, programmed or erased together in a massively parallel operation.

A capacitor device includes a first electrode having a first metal alloy or a metal oxide, a relaxor ferroelectric layer adjacent to the first electrode, where the ferroelectric layer includes oxygen and two or more of lead, barium, manganese, zirconium, titanium, iron, bismuth, strontium, neodymium, potassium, or niobium and a second electrode coupled with the relaxor ferroelectric layer, where the second electrode includes a second metal alloy or a second metal oxide.

A capacitor device includes a first electrode having a first metal alloy or a metal oxide, a relaxor ferroelectric layer adjacent to the first electrode, where the ferroelectric layer includes oxygen and two or more of lead, barium, manganese, zirconium, titanium, iron, bismuth, strontium, neodymium, potassium, or niobium and a second electrode coupled with the relaxor ferroelectric layer, where the second electrode includes a second metal alloy or a second metal oxide.

An MIM capacitor and a manufacturing method therefor. The manufacturing method comprises: providing a semiconductor substrate, and forming a first metal layer on the semiconductor substrate; forming an anti-reflection layer on the first metal layer; performing photoetching and etching on the first metal layer and the anti-reflection layer so as to define an MIM capacitor region, wherein the first metal layer in the MIM capacitor region serves as a lower electrode plate of the MIM capacitor, and the anti-reflection layer in the MIM capacitor region serves as a dielectric layer of the MIM capacitor; and forming an upper electrode plate of the MIM capacitor on the anti-reflection layer in the MIM capacitor region.