Abstract: A multi-point electrical probe for testing location-specific electrical properties on circuit boards. Four generally parallel, electrically conducting probe arms are produced preferably by wafer-based techniques, although any even number of probe arms between two and 64 may be used. The precision of wafer-based manufacturing techniques permits miniaturization beyond that which is conventionally obtained by assembling discrete components. The probe arms are generally flexible, and may be shaped suitably to accommodate a particular circuit geometry. The probe and/or the sample under test may be precisely located by suitable translation and/or rotation stages, which may optionally be placed under computer control. A suitable wiring diagram is provided, and preferable manufacturing techniques are discussed.

Abstract: The multi-point probe comprises a supporting body defining a first surface, a first multitude of conductive probe arms each of the probe arms defining a proximal end and a distal end being positioned in co-planar relationship with the first surface of the supporting body. The probe arms are connected to the supporting body at the proximal ends thereof and have the distal ends freely extending from the supporting body, giving individually flexible motion to the first multitude of probe arms. The probe arms originate from a process of producing the probe arms on a wafer body in facial contact with the wafer body and removal of a part of the wafer body providing the supporting body and providing the probe arms freely extending therefrom. The multi-point probe further comprises a third multitude of tip elements extending from the distal end of the first multitude of probe arms. The tip elements originate from a process of metallization of electron beam depositions on the probe arms at the distal ends thereof.

Abstract: The present invention relates to integrated micro-cantilevers, micro-bridges or micro-membranes in micro-liquid handling systems. Such micro-liquid handling systems provide novel detection mechanisms for monitoring the physical, chemical and biological properties of fluids in such systems. The present invention further relates to micro-cantilever, micro-bridge or micro-membrane type sensors having integrated readout. Such constructions allow laminated flows of different liquids to flow in a channel without mixing, which opens up for new type of experiments and which reduces noise related to the liquid movement. The present invention even further relates to sensors having adjacent or very closely spaced micro-cantilevers, micro-bridges or micro-membranes which can be exposed to different chemical environments at the same time.

Abstract: An object of the present invention is to provide a novel testing probe allowing the testing of electronic circuits of a smaller dimension as compared to the prior art testing technique.

Abstract: A multi-point probe, a method for producing the multi-point probe and a cylindrical nano-drive for in particular driving the multi-point probe in a multi-point testing apparatus for testing electric properties on a specific location of a test sample. The multi-point probe comprises a supporting body defining a first surface, a first multitude of conductive probe arms each of the conductive probe arms defining a proximal end and a distal end being positioned in co-planar relationship with the first surface of the supporting body. The conductive probe arms are connected to the supporting body at the proximal ends thereof and have the distal ends freely extending from the supporting body, giving individually flexible motion to the first multitude of conductive probe arms.

Abstract: An object of the present invention is to provide a novel testing probe allowing the testing of electronic circuits of a smaller dimension as compared to the prior art testing technique. A particular advantage of the present invention is related to the fact that the novel testing technique involving a novel multi-point probe allows the prove to be utilized for establishing a reliable contact between any testing pin or testing tip and a specific location of a test sample, as the testing probe according to the present invention includes individually bendable or flexible testing pins.

Abstract: Atomic displacement on a material surface is detected by, in a system comprising the tip of a scanning tunneling microscope (STM) and a material in question, upon an atomic displacement operation comprising extraction of atoms on the material surface and adsorption of atoms onto the material surface through application of a pulse voltage to the tip of STM, measuring a z-piezo voltage along the time series during and after application of the pulse voltage. Furthermore, heteroatoms dissociated by a reaction between the tip surface of STM and heteromolecules in a heteromolecular atmosphere are stored on the surface of the tip of STM, and then, heteroatoms are locally adsorbed onto the material surface by causing electro-evaporation of the heteroatoms through application of a prescribed scanning voltage to the tip of STM.