Abstract: A method for producing printed magnetic functional elements for resistance sensors and printed magnetic functional elements. The invention refers to the field of electronics and relates to a method for producing resistance sensors, such as can be used, for example, in magnetic data storage for read sensors or in the automobile industry. The disclosure includes a simple and cost-effective production method and to obtain such printed magnetic functional elements with properties that can be adjusted as desire, in which a magnetic material is deposited onto a substrate as a film, is removed from the substrate and divided into several components and these components are applied on a substrate by means of printing technologies. Aspects are also directed to a printed magnetic functional element for resistance sensors of several components of a film, wherein at least 5% of the components of the functional element have a magnetoimpedance effect.

Abstract: A spin-wave waveguide includes a ferromagnetic thin film resembling a wire in shape. A part of the ferromagnetic thin film, large in film thickness, is formed at one end of the ferromagnetic thin film, and a part of the ferromagnetic thin film, small in film thickness, and a part of the ferromagnetic thin film, large in film thickness, are alternately formed on the same plane, for at least not less than one cycle. A part of the ferromagnetic thin film, large in film thickness, is formed at the other end of the ferromagnetic thin film, wherein an insulating film, and an electrode film are stacked in this order on the ferromagnetic thin film in the part of the ferromagnetic thin film, large in film thickness.

Abstract: An RRAM includes a resistive layer including a dielectric layer and surplus oxygen ions or nitrogen ions from a treatment on the dielectric layer after the dielectric layer is formed. When the RRAM is applied with a voltage, the oxygen ions or nitrogen ions occupy vacancies in the dielectric layer to increase resistance of the resistive layer. When the RRAM is applied with another voltage, the oxygen ions or nitrogen ions are removed from the vacancies to lower the resistance of the resistive layer.

Abstract: A memory having an array of perpendicular spin-transfer torque (STT) magnetic random access memory (MRAM) cells, wherein each cell has a magnetic layer stack. A magnetic shield disposed between the cells and having a minimum height of at least the height of the magnetic layer stacks.

Abstract: A method of producing a functional device according to the present invention includes, in this order: the functional solid material precursor layer formation step of applying a functional liquid material onto a base material to form a precursor layer of a functional solid material; the drying step of heating the precursor layer to a first temperature in a range from 80° C. to 250° C. to preliminarily decrease fluidity of the precursor layer; the imprinting step of imprinting the precursor layer that is heated to a second temperature in a range from 80° C. to 300° C. to form an imprinted structure on the precursor layer; and the functional solid material layer formation step of heat treating the precursor layer at a third temperature higher than the second temperature to transform the precursor layer into a functional solid material layer.

Abstract: In one aspect, a vertical Hall effect sensor includes a semiconductor wafer having a first conductivity type and a plurality of semiconductive electrodes disposed on the semiconductor wafer. The plurality of semiconductive electrodes have the first conductivity type and include a source electrode, a first sensing electrode and a second sensing electrode, arranged such that the source electrode is between the first sensing electrode and the sensing electrode and a first drain electrode and a second drain electrode, arranged such that the first sensing electrode, second sensing electrode, and source electrode are between the first drain electrode and the second drain electrode. The vertical Hall effect sensor also includes a plurality of semiconductor fingers disposed on the semiconductor wafer and interdigitated with the plurality of semiconductive electrodes, the semiconductor fingers having a second conductivity type.

Abstract: The present invention relates to a winding and a method for preparing a winding of inductive devices. The winding includes at least a plurality of layers, where each layer includes at least one conductive loop; the conductive loops are electrically connected to form a winding; and the conductive loop or the portion of the conductive loop of at least one layer is not spatially aligned with the conductive loop or the portion of the conductive loop of at least one another layer. Preferably, except for the conductive loop that includes a center tap, other conductive loops are each divided into 2N loop sections, each loop section is electrically connected to a corresponding loop section of another layer through a pair of crossover conductive via plugs, so as to form N windings, where N is an integer greater than or equal to 1.

Abstract: A plasma processing method is used to etch a multilayered material having a stacked structure, in which a first magnetic layer, an insulating layer, a second magnetic layer, and a mask material are stacked in sequence, in a plasma processing apparatus including a processing chamber that partitions a processing space where plasma is generated and a gas supply unit that supplies a processing gas into the processing space. The plasma processing method includes a mask forming process of forming a mask on the second magnetic layer by etching the mask material; an etching process of supplying the processing gas into the processing chamber to generate plasma, etching the second magnetic layer by the mask, and stopping the etching on a surface of the insulating layer. Further, the second magnetic layer contains CoFeB, the insulating layer contains MgO, and the processing gas contains H2 and F or a fluorine compound.

Abstract: [Object] To provide a method of manufacturing a perpendicular magnetization-type magnetic element, which does not need a step of depositing MgO. [Solving Means] The method of manufacturing a magnetoresistive element 1 according to the present invention includes laminating a first layer 30 on a base 10, the first layer 30 including a material containing at least one of Co, Ni, and Fe. Next, a second layer 40 is laminated on the first layer 30, the second layer 40 including Mg. Next, the Mg in the second layer 40 is oxidized to form MgO by applying an oxidation treatment to a laminated body including the first layer 30 and the second layer 40. Next, the second layer 40 is crystallized by applying a heat treatment to the laminated body, and the first layer 30 is caused to be perpendicularly magnetized. According to the manufacturing method, it is possible to manufacture a perpendicular magnetization-type CoFeB—MgO magnetic element without causing a problem arising from the deposition of MgO.

Abstract: Embodiments are directed to STT MRAM devices. One embodiment of an STT MRAM device includes a reference layer, a tunnel barrier layer, a free layer and one or more conductive vias. The reference layer is configured to have a fixed magnetic moment. In addition, the tunnel barrier layer is configured to enable electrons to tunnel between the reference layer and the free layer through the tunnel barrier layer. The free layer is disposed beneath the tunnel barrier layer and is configured to have an adaptable magnetic moment for the storage of data. The conductive via is disposed beneath the free layer and is connected to an electrode. Further, the conductive via has a width that is smaller than a width of the free layer such that a width of an active STT area for the storage of data in the free layer is defined by the width of the conductive via.

Abstract: The three dimensional (3D) circuit includes a first tier including a semiconductor substrate, a second tier disposed adjacent to the first tier, a three dimensional inductor including an inductive element portion, the inductive element portion including a conductive via extending from the first tier to a dielectric layer of the second tier. The 3D circuit includes a ground shield surrounding at least a portion of the conductive via. In some embodiments, the ground shield includes a hollow cylindrical cage. In some embodiments, the 3D circuit is a low noise amplifier.

Abstract: According to one embodiment, a semiconductor device includes a MRAM chip including a semiconductor substrate and a memory cell array area includes magnetoresistive elements which are provided on the semiconductor substrate, and a magnetic shield layer surrounding the memory cell array area in a circumferential direction of the MRAM chip, and having a closed magnetic path.

Abstract: A magnetic junction usable in a magnetic memory and a method for providing the magnetic memory are described. The method includes providing a pinned layer, providing an engineered nonmagnetic tunneling barrier layer, and providing a free layer. The pinned layer and the free layer each include at least one ferromagnetic layer. The engineered nonmagnetic tunneling barrier layer has a tuned resistance area product. In some aspects, the step of providing the engineered nonmagnetic tunneling barrier layer further includes radio-frequency depositing a first oxide layer, depositing a metal layer, and oxidizing the metal layer to provide a second oxide.

Abstract: Method and apparatus for forming a patterned magnetic substrate are provided. A patterned resist is formed on a magnetically active surface of a substrate. An oxide layer is formed over the patterned resist by a flowable CVD process. The oxide layer is etched to expose portions of the patterned resist. The patterned resist is then etched, using the etched oxide layer as a mask, to expose portions of the magnetically active surface. A magnetic property of the exposed portions of the magnetically active surface is then modified by directing energy through the etched resist layer and the etched oxide layer, which are subsequently removed from the substrate.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device is disclosed. The method includes forming a first magnetic film containing boron, forming a second magnetic film free from boron, above the first magnetic film. The method further includes selectively etching the second magnetic film with respect to the first magnetic film using plasma of etching gas which contains oxygen and hydrogen and which is free from halogen.

Abstract: According to one embodiment, a magnetic memory is disclosed. The magnetic memory includes a substrate, and a contact plug provided on the substrate. The contact plug includes a first contact plug, and a second contact plug provided on the first contact plug and having a smaller diameter than that of the first contact plug. The magnetic memory further includes a magnetoresistive element provided on the second contact plug. The diameter of the second contact plug is smaller than that of the magnetoresistive element.

Abstract: A method of forming a ferroelectric memory cell. The method comprises forming an electrode material exhibiting a desired dominant crystallographic orientation. A hafnium-based material is formed over the electrode material and the hafnium-based material is crystallized to induce formation of a ferroelectric material having a desired crystallographic orientation. Additional methods are also described, as are semiconductor device structures including the ferroelectric material.

Abstract: Thermal treatment of a semiconductor wafer in the fabrication of integrated circuits including MOS transistors and ferroelectric capacitors, including those using lead-zirconium-titanate (PZT) ferroelectric material, to reduce variation in the electrical characteristics of the transistors. Thermal treatment of the wafer in a nitrogen-bearing atmosphere in which hydrogen is essentially absent is performed after formation of the transistors and capacitor. An optional thermal treatment of the wafer in a hydrogen-bearing atmosphere prior to deposition of the ferroelectric treatment may be performed.

Abstract: A magnetic cell includes an attracter material proximate to a magnetic region (e.g., a free region). The attracter material is formulated to have a higher chemical affinity for a diffusible species of a magnetic material, from which the magnetic region is formed, compared to a chemical affinity between the diffusible species and at least another species of the magnetic material. Thus, the diffusible species is removed from the magnetic material to the attracter material. The removal accommodates crystallization of the depleted magnetic material. The crystallized, depleted magnetic material enables a high tunnel magneto resistance, high energy barrier, and high energy barrier ratio. The magnetic region may be formed as a continuous magnetic material, thus enabling a high exchange stiffness, and positioning the magnetic region between two magnetic anisotropy-inducing oxide regions enables a high magnetic anisotropy strength. Methods of fabrication and semiconductor devices are also disclosed.

Abstract: A magnetic cell includes a free region between an intermediate oxide region (e.g., a tunnel barrier) and a secondary oxide region. Both oxide regions may be configured to induce magnetic anisotropy (“MA”) with the free region, enhancing the MA strength of the free region. A getter material proximate to the secondary oxide region is formulated and configured to remove oxygen from the secondary oxide region to reduce an oxygen concentration and, thus, an electrical resistance of the secondary oxide region. Thus, the secondary oxide region contributes only minimally to the electrical resistance of the cell core. Embodiments of the present disclosure therefore enable a high effective magnetoresistance, low resistance area product, and low programming voltage along with the enhanced MA strength. Methods of fabrication, memory arrays, memory systems, and electronic systems are also disclosed.

Abstract: A current sensor device for sensing a measuring current includes a semiconductor chip having a magnetic field sensitive element. The current sensor device further includes an encapsulant embedding the semiconductor chip. A conductor configured to carry the measuring current is electrically insulated from the magnetic field sensitive element. A redistribution structure includes a first metal layer having a first structured portion which forms part of the conductor.

Abstract: A method of manufacturing a magnetoresistive-based device includes a metal hard mask that is inert to a top electrode etch chemistry and that has low sputter yield during a magnetic stack sputter. The metal hard mask is patterned by the photo resist and the photo mask is then stripped and the top electrode (overlying magnetic materials of the magnetoresistive-based device) is patterned by the metal hard mask.

Abstract: A magnetic field sensor includes a circular vertical Hall (CVH) sensing element and at least one planar Hall element. The CVH sensing element has contacts arranged over a common implant region in a substrate. In some embodiments, the at least one planar Hall element is formed as a circular planar Hall (CPH) sensing element also having contacts disposed over the common implant region. A CPH sensing element and a method of fabricating the CPH sensing element are separately described.

Abstract: Magnetic tunnel junctions (MTJ) suitable for spin transfer torque memory (STTM) devices, include perpendicular magnetic layers and one or more anisotropy enhancing layer(s) separated from a free magnetic layer by a crystallization barrier layer. In embodiments, an anisotropy enhancing layer improves perpendicular orientation of the free magnetic layer while the crystallization barrier improves tunnel magnetoresistance (TMR) ratio with better alignment of crystalline texture of the free magnetic layer with that of a tunneling layer.

Abstract: A stacked structure according to an embodiment includes: a semiconductor layer; a first layer formed on the semiconductor layer, the first layer containing at least one element selected from Zr, Ti, and Hf, the first layer being not thinner than a monoatomic layer and not thicker than a pentatomic layer; a tunnel barrier layer formed on the first layer; and a magnetic layer formed on the tunnel barrier layer.

Abstract: A MTJ is disclosed with a discontinuous Mg or Mg alloy layer having a thickness from 1 to 3 Angstroms between a free layer and a capping layer in a bottom spin valve configuration. It is believed the discontinuous Mg layer serves to block conductive material in the capping layer from diffusing through the free layer and into the tunnel barrier layer thereby preventing the formation of conductive channels that function as electrical shunts within the insulation matrix of the tunnel barrier. As a result, the “low tail” percentage in a plot of magnetoresistive ratio vs Rp is minimized which means the number of high performance MTJ elements in a MTJ array is significantly increased, especially when a high temperature anneal is included in the MTJ fabrication process. The discontinuous layer is formed by a low power physical vapor deposition process.

Abstract: According to one embodiment, a magnetoresistive effect element includes a first ferromagnetic layer, a tunnel barrier provided on the first ferromagnetic layer, and a second ferromagnetic layer provided on the tunnel barrier. The tunnel barrier includes a nonmagnetic mixture containing MgO and a metal oxide with a composition which forms, in a solid phase, a single phase with MgO.

Abstract: A magnetic field sensor having a support with a top side and a bottom side, whereby a Hall plate is provided on the top side of the support and the Hall plate comprises a carbon-containing layer.

Abstract: A method of manufacturing a semiconductor device includes: forming a conductive film over a semiconductor substrate; forming a first ferroelectric film over the conductive film; forming an amorphous second ferroelectric film over the first ferroelectric film; forming a transition metal oxide material film containing ruthenium over the second ferroelectric film; forming a first conductive metal oxide film over the transition metal oxide material film without exposing the transition metal oxide material film to the air; annealing and crystallizing the second ferroelectric film; and patterning the first conductive metal oxide film, the first ferroelectric film, the second ferroelectric film, and the conductive film to form a ferroelectric capacitor.

Abstract: The presently claimed invention provides a barium strontium titanate/strontium titanate/gallium arsenide (BST/STO/GaAs) heterostructure comprising a gallium arsenide (GaAs) substrate, at least one strontium titanate (STO) layer, and at least one barium strontium titanate (BST) layer. The BST/STO/GaAs heterostructure of the present invention has a good temperature stability, high dielectric constant and low dielectric loss, which enable to fabricate tunable ferroelectric devices. A method for fabricating the BST/STO/GaAs heterostructure is also disclosed in the present invention, which comprises formation of at least one STO layer on the GaAs substrate by a first laser molecular beam epitaxial system, and formation of at least one BST layer on the STO layer by a second laser molecular beam epitaxial system.

Abstract: In accordance with a method of the present invention, a method of manufacturing a magnetic random access memory (MRAM) cell and a corresponding structure thereof are disclosed to include a multi-stage manufacturing process. The multi-stage manufacturing process includes performing a front end on-line (FEOL) stage to manufacture logic and non-magnetic portions of the memory cell by forming an intermediate interlayer dielectric (ILD) layer, forming intermediate metal pillars embedded in the intermediate ILD layer, depositing a conductive metal cap on top of the intermediate ILD layer and the metal pillars, performing magnetic fabrication stage to make a magnetic material portion of the memory cell being manufactured, and performing back end on-line (BEOL) stage to make metal and contacts of the memory cell being manufactured.

Abstract: This disclosure provides a method of fabricating a semiconductor stack and associated device, such as a capacitor and DRAM cell. In particular, a bottom electrode has a material selected for lattice matching characteristics. This material may be created from a relatively inexpensive metal oxide which is processed to adopt a conductive, but difficult-to-produce oxide state, with specific crystalline form; to provide one example, specific materials are disclosed that are compatible with the growth of rutile phase titanium dioxide (TiO2) for use as a dielectric, thereby leading to predictable and reproducible higher dielectric constant and lower effective oxide thickness and, thus, greater part density at lower cost.

Abstract: According to one embodiment, a method for manufacturing a nonvolatile memory device including a plurality of memory cells is disclosed. Each of the plurality of memory cells includes a base layer including a first electrode, a magnetic tunnel junction device provided on the base layer, and a second electrode provided on the magnetic tunnel junction device. The magnetic tunnel junction device includes a first magnetic layer, a tunneling barrier layer provided on the first magnetic layer, and a second magnetic layer provided on the tunneling barrier layer. The method can include etching a portion of the second magnetic layer and a portion of the first magnetic layer by irradiating gas clusters onto a portion of a surface of the second magnetic layer or a portion of a surface of the first magnetic layer.

Abstract: According to one embodiment, a semiconductor device includes a MRAM chip including a semiconductor substrate and a memory cell array area includes magnetoresistive elements which are provided on the semiconductor substrate, and a magnetic shield layer separated from the MRAM chip, surrounding the memory cell array area in a circumferential direction of the MRAM chip, and having a closed magnetic path.

Abstract: According to one embodiment, a magnetic memory includes a magnetoresistive effect element provided in a memory cell, the magnetoresistive effect element including a multilayer structure including a first magnetic layer, a second magnetic layer, and a nonmagnetic layer between the first magnetic layer and the second magnetic layer, a first electrode provided on an upper portion of the multilayer structure and including a first material, and a first film provided on a side surface of the first electrode and including a second material which is different from the first material of the first electrode.

Abstract: According to one embodiment, a magnetoresistive element is disclosed. The element includes a lower electrode, a stacked body provided on the lower electrode and including a first magnetic layer, a tunnel barrier layer and a second magnetic layer. The first magnetic layer is under the tunnel barrier layer, the second magnetic layer is on the tunnel barrier layer. The first magnetic layer includes a first region and a second region outside the first region to surround the first region. The second region includes an element in the first region and other element being different from the element.

Abstract: A device and a method of forming a device are presented. A substrate is provided. Front end of line processing is performed to form circuit component on the substrate and back end of line processing is performed to include the uppermost inter level dielectric (ILD) layer. The uppermost ILD layer includes first and second interconnects. A pad level is formed over the uppermost ILD layer. A storage unit of a memory cell is provided in the pad level. The storage unit is coupled to the first interconnect of the uppermost ILD layer. A cell interconnect and a pad interconnect are formed in the pad level. The cell interconnect is formed on top of and coupled to the storage unit and the pad interconnect is coupled to the second interconnect in the uppermost ILD layer.

Abstract: Ferroelectric capacitors used in ferroelectric random access memories (F-RAM) and methods for fabricating the same to reduce sidewall leakage are described. In one embodiment, the method includes depositing over a surface of a substrate, a ferro stack including a bottom electrode layer electrically coupled to a bottom electrode contact extending through the substrate, a top electrode layer and ferroelectric layer there between. A hard-mask is formed over the ferro stack, and a top electrode formed by etching through the top electrode layer and at least partially through the ferroelectric layer. A non-conductive barrier is formed on sidewalls formed by etching through the top electrode layer and at least partially through the ferroelectric layer, and then a bottom electrode is formed by etching the bottom electrode layer so that conductive residues generated by the etching are electrically isolated from the top electrode by the non-conductive barrier.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes a magnetoresistive element formed on a semiconductor substrate, a first contact plug which extends through an interlayer dielectric film formed on the semiconductor substrate and immediately below the magnetoresistive element, has a bottom surface in contact with an upper surface of the semiconductor substrate, and is adjacent to the magnetoresistive element, and an insulating film formed between the magnetoresistive element and the first contact plug and on the interlayer dielectric film, wherein the insulating film includes a first region positioned on a side of the interlayer dielectric film, and a second region positioned in the insulating film and on an upper surface of the first region, the insulating film is made of SiN, and the first region is a nitrogen rich film compared to the second region.

Abstract: According to one embodiment, a magnetic memory device includes a magnetoresistance effect element having a structure in which a first magnetic layer, a nonmagnetic layer, a second magnetic layer, and a third magnetic layer are stacked, wherein the third magnetic layer comprises a first region and a plurality of second regions, and each of the second regions is surrounded by the first region, has conductivity, and has a greater magnetic property than the first region.

Abstract: A vertical Hall Effect sensor is provided having a high degree of symmetry between its bias modes, can be adapted to exhibit a small pre-spinning systematic offset, and complies with the minimal spacing requirements allowed by the manufacturing technology (e.g., CMOS) between the inner contacts. These characteristics enable the vertical Hall Effect sensor to have optimal performance with regard to offset and sensitivity.

Abstract: According to one embodiment, a magnetic memory is disclosed. The memory includes a conductive layer containing a first metallic material, a stacked body formed above the conductive layer and including a first magnetic layer containing a second metallic material, a second magnetic layer, and a tunnel barrier layer formed between the first magnetic layer and the second magnetic layer, and an insulating layer formed on a side face of the stacked body and containing an oxide of the first metallic material. A standard electrode potential of the first metallic material is lower than the standard electrode potential of the second metallic material.

Abstract: According to one embodiment, a first magnetic layer, a first nonmagnetic layer on the first magnetic layer, a second magnetic layer on the first nonmagnetic layer, a second nonmagnetic layer on the second magnetic layer, and a third magnetic layer on the second nonmagnetic layer, the third magnetic layer having a sidewall includes a material which is included in the second nonmagnetic layer.

Abstract: According to one embodiment, a magnetoresistive element is disclosed. The magnetoresistive element includes a reference layer. The reference layer includes a first region, and a second region provided outside the first region to surround the same. The second region contains an element contained in the first region and another element being different from the element. The magnetoresistive element further includes a storage layer, and a tunnel barrier layer provided between the reference layer and the storage layer. The storage layer is free from the another element.

Abstract: A method of forming a line of magnetic tunnel junctions includes forming magnetic recording material over a substrate, non-magnetic material over the recording material, and magnetic reference material over the non-magnetic material. The substrate has alternating outer regions of reactant source material and insulator material along at least one cross-section. The reference material is patterned into a longitudinally elongated line passing over the alternating outer regions. The recording material is subjected to a set of temperature and pressure conditions to react with the reactant of the reactant source material to form regions of the dielectric material which longitudinally alternate with the recording material along the line and to form magnetic tunnel junctions along the line which individually comprise the recording material, the non-magnetic material, and the reference material that are longitudinally between the dielectric material regions.

Abstract: Magnetic memory devices and methods of manufacturing the same are disclosed. A method may include forming a magnetic tunnel junction layer on a substrate, forming mask patterns on the magnetic tunnel junction layer, and sequentially performing a plurality of ion implantation processes using the mask patterns as ion implantation masks to form an isolation region in the magnetic tunnel junction layer. The isolation region may thereby define magnetic tunnel junction parts that are disposed under corresponding ones of the mask patterns. A magnetic memory device may include a plurality of magnetic tunnel junction parts electrically and magnetically isolated from each other through the isolation region.

Abstract: Some embodiments of the present disclosure relate to a method that achieves a substantially uniform pattern of magnetic random access memory (MRAM) cells with a minimum dimension below the lower resolution limit of some optical lithography techniques. A copolymer solution comprising first and second polymer species is spin-coated over a heterostructure which resides over a surface of a substrate. The heterostructure comprises first and second ferromagnetic layers which are separated by an insulating layer. The copolymer solution is subjected to self-assembly into a phase-separated material comprising a pattern of micro-domains of the second polymer species within a polymer matrix comprising the first polymer species. The first polymer species is then removed, leaving a pattern of micro-domains of the second polymer species. A pattern of magnetic memory cells within the heterostructure is formed by etching through the heterostructure while utilizing the pattern of micro-domains as a hardmask.

Abstract: According to one embodiment, a magnetic memory includes a cell transistor including a first source/drain diffusion layer and a second source/drain diffusion layer, a first contact on the first source/drain diffusion layer, a memory element on the first contact, and a second contact on the second source/drain diffusion layer, the second contact including a first plug on the second source/drain diffusion layer, and a second plug on the first plug.

Abstract: According to one embodiment, a magnetic memory is disclosed. The magnetic memory includes a substrate, a first magnetoresistive element provided on the substrate. A second magnetoresistive element which is provided on the substrate and is arranged next to the first magnetoresistive element. Each of the first and second magnetoresistive elements includes a first magnetic layer, a tunnel barrier layer and a second magnetic layer. The tunnel barrier layer is provided on the first magnetic layer, the second magnetic layer is provided on the tunnel barrier layer. A first stress member having a tensile stress as an internal stress is provided on an area including a side face of the stacked body.

Abstract: A method of etching a ferroelectric capacitor stack structure including conductive upper and lower plates with a ferroelectric material, such as lead-zirconium-titanate (PZT), therebetween, with each of these layers defined by the same hard mask element. The stack etch process involves a plasma etch with a fluorine-bearing species as an active species in the etch of the conductive plates, and a non-fluorine-bearing chemistry for etching the PZT ferroelectric material. An example of the fluorine-bearing species is CF4. Endpoint detection can be used to detect the point at which the upper plate etch reaches the PZT, at which point the gases in the chamber are purged to avoid etching the PZT material with fluorine. A steeper sidewall angle for the capacitor structure can be obtained.