Abstract: Ferroelectric stacks are disclosed herein that can improve retention performance of ferroelectric memory devices. An exemplary ferroelectric stack has a ferroelectric switching layer (FSL) stack disposed between a first electrode and a second electrode. The ferroelectric stack includes a barrier layer disposed between a first FSL and a second FSL, where a first crystalline condition of the barrier layer is different than a second crystalline condition of the first FSL and/or the second FSL. In some embodiments, the first crystalline condition is an amorphous phase, and the second crystalline condition is an orthorhombic phase. In some embodiments, the first FSL and/or the second FSL include a first metal oxide, and the barrier layer includes a second metal oxide. The ferroelectric stack can be a ferroelectric capacitor, a portion of a transistor, and/or connected to a transistor in a ferroelectric memory device to provide data storage in a non-volatile manner.

Abstract: Various embodiments of the present disclosure are directed towards a memory cell including a data storage structure disposed between a top electrode and a bottom electrode. The data storage structure includes a lower switching layer overlying the bottom electrode, and an upper switching layer overlying the lower switching layer. The lower switching layer comprises a dielectric material doped with a first dopant.

Abstract: Various embodiments of the present disclosure are directed towards a memory device including a data storage structure overlying a substrate. A bottom electrode overlies the substrate and a top electrode overlies the bottom electrode. The data storage structure is disposed between the bottom electrode and the top electrode. The data storage structure comprises a dielectric material doped with a first dopant and a second dopant, where the first dopant is different from the second dopant.

Abstract: In some embodiments, the present disclosure relates to an integrated chip. The integrated chip includes a bottom electrode disposed over a substrate and a top electrode disposed over the bottom electrode. A ferroelectric switching layer is arranged between the bottom electrode and the top electrode. The ferroelectric switching layer is configured to change polarization based upon one or more voltages applied to the bottom electrode or the top electrode. A seed layer is arranged between the bottom electrode and the top electrode. The seed layer and the ferroelectric switching layer have a non-monoclinic crystal phase.

Abstract: A method includes performing a plasma activation on a surface of a first package component, removing oxide regions from surfaces of metal pads of the first package component, and performing a pre-bonding to bond the first package component to a second package component.

Abstract: An integrated circuit structure includes a package component, which further includes a non-porous dielectric layer having a first porosity, and a porous dielectric layer over and contacting the non-porous dielectric layer, wherein the porous dielectric layer has a second porosity higher than the first porosity. A bond pad penetrates through the non-porous dielectric layer and the porous dielectric layer. A dielectric barrier layer is overlying, and in contact with, the porous dielectric layer. The bond pad is exposed through the dielectric barrier layer. The dielectric barrier layer has a planar top surface. The bond pad has a planar top surface higher than a bottom surface of the dielectric barrier layer.

Abstract: A method of forming a memory device is provided. In some embodiments, a memory cell is formed over a substrate, and a sidewall spacer layer is formed along the memory cell. A lower etch stop layer is formed on the sidewall spacer layer, and an upper dielectric layer is formed on the lower etch stop layer. A first etching process is performed to etch back the upper dielectric layer using the lower etch stop layer as an etch endpoint.

Abstract: Present disclosure provides chemical mechanical polishing (CMP) apparatus, including a counterface configured to support a semiconductor wafer at a first surface, a first electromagnet array under the first surface, a polishing head over the counterface and configured to hold the semiconductor wafer at a second surface, and a controller connects to the first electromagnet array. The first electromagnet array comprises a plurality of electromagnets, a polarity of each of the plurality of electromagnets is capable of being individually controlled by the controller. Present disclosure also provides a CMP slurry and a method for using a chemical mechanical polishing apparatus.

Abstract: A wafer carrier assembly includes a wafer carrier and a fluid passage. The wafer carrier comprises a retainer ring confining a wafer accommodation space. The fluid passage is inside the wafer carrier. The fluid passage includes an inlet and at least an outlet to dispense fluid into the wafer accommodation space.

Abstract: A method of fabricating a semiconductor device includes receiving a device substrate; forming an interconnect structure on a front side of the device substrate; and etching a recess into a backside of the device substrate until a portion of the interconnect structure is exposed. The recess has a recess depth and an edge of the recess is defined by a sidewall of the device substrate. A conductive bond pad is formed in the recess, and a first plurality of layers cover the conductive bond pad, extend along the sidewall of the device substrate, and cover the backside of the device substrate. The first plurality of layers collectively have a first total thickness that is less than the recess depth. A first chemical mechanical planarization is performed to remove portions of the first plurality of layers so remaining portions of the first plurality of layers cover the conductive bond pad.

Abstract: A semiconductor structure including a self-assembled monolayer for enhancing metal-dielectric adhesion and preventing metal diffusion is provided. The semiconductor structure includes a substrate and a first dielectric layer on the substrate. A contact structure is embedded in the first dielectric layer and includes a conductive line. The semiconductor structure further includes a self-assembled monolayer on the conductive line, and a second dielectric layer on the first dielectric layer and the conductive line. The self-assembled monolayer is chemically bonded to the conductive line and the second dielectric layer.

Abstract: A method includes performing a plasma activation on a surface of a first package component, removing oxide regions from surfaces of metal pads of the first package component, and performing a pre-bonding to bond the first package component to a second package component.

Abstract: Some embodiments relate to an integrated chip. The integrated chip includes a memory cell over a substrate, where the memory cell comprises a data storage structure. A conductive interconnect is over the data storage structure and comprises a first protrusion adjacent to a first side of the data storage structure, where the first protrusion comprises a flat bottom surface. A spacer structure is disposed on the first side of the data storage structure. The spacer structure directly contacts the flat bottom surface of the first protrusion.

Abstract: Various embodiments of the present disclosure are directed towards a memory device including a data storage structure overlying a substrate. A bottom electrode overlies the substrate and a top electrode overlies the bottom electrode. The data storage structure is disposed between the bottom electrode and the top electrode. The data storage structure comprises a dielectric material doped with a first dopant and a second dopant, where the first dopant is different from the second dopant.

Abstract: A method includes forming a bottom electrode layer, and depositing a first ferroelectric layer over the bottom electrode layer. The first ferroelectric layer is amorphous. A second ferroelectric layer is deposited over the first ferroelectric layer, and the second ferroelectric layer has a polycrystalline structure. The method further includes depositing a third ferroelectric layer over the second ferroelectric layer, with the third ferroelectric layer being amorphous, depositing a top electrode layer over the third ferroelectric layer, and patterning the top electrode layer, the third ferroelectric layer, the second ferroelectric layer, the first ferroelectric layer, and the bottom electrode layer to form a Ferroelectric Random Access Memory cell.

Abstract: A memory device includes a field effect transistor and a variable-capacitance capacitor. A gate structure includes a gate dielectric and an intermediate electrode. The variable-capacitance capacitor includes a lower capacitor plate comprising the intermediate electrode, an upper capacitor plate comprising a control gate electrode, and a variable-capacitance node dielectric and including an electrical-field-programmable metal oxide material. The electrical-field-programmable metal oxide material provides a variable effective dielectric constant, and a data bit may be stored as a dielectric state of the variable-capacitance node dielectric in the memory device. The variable-capacitance node dielectric provides reversible electrical field-dependent resistivity modulation, or reversible electrical field-dependent movement of metal atoms therein.

Abstract: The problem of forming top electrode vias that provide consistent results in devices that include resistance switching RAM cells of varying heights is solved using a dielectric composite that fills areas between resistance switching RAM cells and varies in height to align with the tops of both the taller and the shorter resistance switching RAM cells. An etch stop layer may be formed over the dielectric composite providing an equal thickness of etch-resistant dielectric over both taller and shorter resistance switching RAM cells. The dielectric composite causes the etch stop layer to extend laterally away from the resistance switching RAM cells to maintain separation between the via openings and the resistance switching RAM cell sides even when the openings are misaligned.

Abstract: A memory cell with an etch stop layer is provided. The memory cell comprises a bottom electrode disposed over a substrate. A switching dielectric is disposed over the bottom electrode and having a variable resistance. A top electrode is disposed over the switching dielectric. A sidewall spacer layer extends along sidewalls of the bottom electrode, the switching dielectric, and the top electrode and an upper surface of a lower dielectric layer. A lower etch stop layer is disposed over the lower dielectric layer and lining an outer sidewall of the sidewall spacer layer. The the sidewall spacer layer separates the lower etch stop layer from the lower dielectric layer.

Abstract: Some embodiments relate to a memory device. The memory device includes a memory cell overlying a substrate, the memory cell includes a data storage structure disposed between a lower electrode and an upper electrode. An upper interconnect wire overlying the upper electrode. A first inter-level dielectric (ILD) layer surrounding the memory cell and the upper interconnect wire. A second ILD layer overlying the first ILD layer and surrounding the upper interconnect wire. A sidewall spacer laterally surrounding the memory cell. The sidewall spacer has a first sidewall abutting the first ILD layer and a second sidewall abutting the second ILD layer.

Abstract: In some embodiments, the present disclosure relates to method for trimming and cleaning an edge of a wafer. The method includes trimming an outer edge portion of the wafer with a blade along a continuously connected trim path to define a new sidewall of the wafer. The trimming produces contaminant particles on the wafer. Further, the method includes applying deionized water to the new sidewall of the wafer with water nozzles to remove the contaminant particles. The method also includes applying pressurized gas to the wafer at a first top surface area of the wafer with an air jet nozzle. The pressurized gas is directed outward from a center of the wafer to remove remaining contaminant particles. The applying of deionized water and the applying of pressurized gas are performed in a same chamber as the trimming.