Patent application number | Description | Published |
20090046414 | METHOD FOR FABRICATING A CAPACITOR AND A CAPACITOR - The method comprises fabricating a layer stack on a substrate, the layer stack comprising at least two electrically conducting layers and at least one electrically insulating layer arranged between the two electrically conducting layers, and displacing a first portion of the layer stack away from its original position, the first portion comprising an edge portion of the layer stack, and bending the first portion back towards a second portion of the layer stack. The bending may comprise a rolling-up of the first portion of the layer stack. | 02-19-2009 |
20120140379 | METHOD FOR FABRICATING A MULTI-LAYER CAPACITOR AND A MULTI-LAYER CAPACITOR - The method comprises fabricating a layer stack on a substrate, the layer stack comprising at least two electrically conducting layers and at least one electrically insulating layer arranged between the two electrically conducting layers, and displacing a first portion of the layer stack away from its original position, the first portion comprising an edge portion of the layer stack, and bending the first portion back towards a second portion of the layer stack. The bending may comprise a rolling-up of the first portion of the layer stack. | 06-07-2012 |
20120326714 | METHOD FOR THE PRODUCTION OF PRINTED MAGNETIC FUNCTIONAL ELEMENTS FOR RESISTIVE SENSORS AND PRINTED MAGNETIC FUNCTIONAL ELEMENTS - 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. | 12-27-2012 |
20140030553 | MAGNETO-ELECTRONIC COMPONENT, AND METHOD FOR THE PRODUCTION THEREOF - The invention relates to the fields of physics and materials science, more particularly to a magneto-electronic component that can he used as a digital memory, for example. The aim of the invention is to design a magneto-electronic component which can be used as a racetrack memory. Said aim is achieved by a magneto-electronic component consisting of an insulating thin film, on which an elongate element made of a magnetic material and electrically conductive contacts are located, and another insulating thin film, said arrangement being jointly rolled up. Said aim is also achieved by a method in which at least one elongate element made of a magnetic material is applied to an insulating thin film, electrical contacts are also applied, and another insulating thin film is applied thereto, the stack of layers being arranged so as to have a strain gradient. | 01-30-2014 |
20140234977 | ROLLED-UP, THREE-DIMENSIONAL FIELD-EFFECT TRANSISTORS AND THE USE THEREOF IN ELECTRONICS, SENSORS AND MICROFLUIDICS - Field-effect transistors include at least two thin layers of a semiconductor material and of an electrically conductive gate material that are rolled up together. These two layers are arranged separated from one another by one or multiple barrier layers and this rolled-up multi-layer structure is integratable as field-effect transistors in circuits and/or in microfluid systems as sensors for the detection of fluids. | 08-21-2014 |
20140291143 | CARRIER MATERIAL FOR ELECTRICALLY POLARIZABLE BIOMATERIALS, POLYELECTROLYTE MATERIALS, ATOMS, IONS AND MOLECULES; ITS MANUFACTURE AND USE - Carriers for biomaterials, for polyelectrolyte materials, for electrically polarizable atoms, ions, molecules are provided wherein the material of the carriers is compatible with materials that are used in microelectronics. The arrangement of the biomaterials or biomolecules and optionally of biomolecules, biomaterials, biological functional units or cells adsorbed thereon can be affected with the carrier in a specific manner. Complex molecular machines can be built and tested by the carriers. | 10-02-2014 |
20140347046 | USE OF FLEXIBLE MAGNETIC THIN LAYER SENSOR ELEMENTS - The invention concerns the field of electrical, materials and mechanical engineering and relates to the use of flexible magnetic thin layer sensor elements, which can be used for measuring magnetic flux density in electromagnetic energy converters and magnetomechanical energy converters. The aim of the invention is to specify the use of flexible magnetic thin layer sensor elements in electric machines and magnetic bearings, which can be placed in air gaps without substantially limiting the air gap widths. Said aim is achieved by the use of at least one flexible magnetic thin layer sensor element, which is attached to non-planar surfaces in the air gap on at least one of the main elements of electromagnetic energy converters and magnetomechanical energy converters and at least partially covers the non-planar surface of at least one of the main elements in the air gap in order to measure the magnetic flux density in the air gap and/or to regulate and/or monitor electromagnetic energy converters and magnetomechanical energy converters. | 11-27-2014 |
Patent application number | Description | Published |
20090124027 | Structure and Method for Placement, Sizing and Shaping of Dummy Structures - A material layer on a substrate being processed, e.g. to form chips, includes one or more functional structures. In order to control pattern density during fabrication of the chip, dummy fill structures of different sizes and shapes are added to the chip at different distances from the functional structures of the material layer. In particular, the placement, size and shape of the dummy structures are determined as a function of a distance to, and density of, the functional structures of the material layer. | 05-14-2009 |
20100321656 | TRANSMISSION MASK WITH DIFFERENTIAL ATTENUATION TO IMPROVE ISO-DENSE PROXIMITY - A system and method to compensate for the proximity effects in the imaging of patterns in a photolithography process. A light exposure of a photoresist layer is effectuated in predetermined patterns through an exposure mask having light-transmissive openings in correspondence to the predetermined patterns. The exposure mask has areas densely populated with the light-transmissive openings and areas sparsely populated with the light-transmissive openings. Light is attenuated through the densely populated light-transmissive openings by a different amount than through the sparsely populated light-transmissive openings. | 12-23-2010 |
20110133304 | Structure and Method for Placement, Sizing and Shaping of Dummy Structures - A chip includes a number a plurality of functional areas of a layer and a number of dummy structures within the layer. The dummy structures are spaced from the functional areas. Each dummy structure has a size that is a function of the size and density of the functional areas. | 06-09-2011 |
20130267048 | Structure and Method for Placement, Sizing and Shaping of Dummy Structures - A chip includes a number a plurality of functional areas of a layer and a number of dummy structures within the layer. The dummy structures are spaced from the functional areas. Each dummy structure has a size that is a function of the size and density of the functional areas. | 10-10-2013 |