Abstract: The present invention relates to a process for preparing a catalyst, at least comprising the steps of adding a protecting agent to an aqueous solution of a metal precursor to give a mixture (M1), adding a reducing agent to mixture (M1) to give a mixture (M2), adding a support material to mixture (M2) to give a mixture (M3), adjusting the pH of mixture (M3), and separating the solid and liquid phase of mixture (M3). Furthermore, the present invention relates to the catalyst as such and its use as diesel oxidation catalyst.

Abstract: A description is given of methods for collecting particles (1, 2) which are suspended in a liquid, including the following steps: providing the liquid containing the suspended particles (1, 2) in a compartment (10) having lateral surfaces (11), wherein at least one electrode (21) is arranged on at least one of the lateral surfaces (11), and generating high-frequency electric fields by means of the at least one electrode (21) so as to form at least one circulating flow (30), by means of which the particles (1, 2) are guided to at least one predetermined collecting area (40) in the compartment (10), wherein the flow (30) is formed in such a way that at least one branch of the flow runs along a longitudinal extent of the at least one electrode (21), and the flow (30) circulates about an axis (31) which is oriented perpendicular to the respectively adjacent lateral surface (11) with the electrode (21). Corresponding devices for collecting particles are also described.

Abstract: The invention relates to a measuring probe device for a probe microscope, in particular a scanning probe microscope, with a measuring probe holder and a measuring probe arranged on the measuring probe holder, which is set up for a probe microscopic investigation of a sample, wherein on the measuring probe holder, a measuring probe chamber is formed, which receives the measuring probe at least partially and is open on a side away from the measuring probe holder, and is configured to receive a liquid surrounding the measuring probe. The invention also relates to a measuring cell for receiving a liquid sample for a probe microscope, a scanning probe microscope with a measuring probe device and a scanning probe microscope with a measuring cell.

Abstract: The invention relates to a method for the combined analysis of a sample with objects to be analysed, in particular a sample with biological objects, in which measurement results for one or more of the objects to be analysed in the sample are obtained by analysing the one or more objects to be analysed by an imaging method of measurement, probe-microscopic measurement results are obtained for the one or more objects to be analysed by analysing the one or more objects to be analysed by a probe-microscopic method of measurement, and the measurement results and the probe-microscopic measurement results are assigned to one another, after optional prior intermediate processing. Furthermore, the invention relates to an apparatus for carrying out combined analysis of a sample with objects to be investigated, in particular a sample with biological objects.

Abstract: The invention relates to an electric field cage (6) for spatially fixing particles (2, 3) which are suspended in a carrier liquid, in particular in a microfluidic system, including a plurality of cage electrodes (7, 8), which can be electrically driven, for generating a capture field. It is proposed that at least one of the cage electrodes (8) is annular and surrounds the other cage electrode (7). The invention also covers an associated operating method.

Abstract: A method for high-resolution image recording of at least one object with a microscope, includes the steps of: (a) positioning the object in a receptacle being arranged in the optical axis of the microscope, (b) generating at least two first data sets per object which represent intermediate images of the object with at least two different orientations relative to the optical axis of the microscope, wherein the different orientations of the object are provided by moving the object relative to the receptacle, and (c) evaluating the data sets for obtaining quantitative three dimensional information.

Abstract: Method and arrangement for making electrical contact with a membrane-enveloped object using an electrode The invention relates, inter alia, to a method for making electrical contact with a membrane-enveloped object (30) using an electrode (10, 100). According to the invention, it is provided that at least one electrode (100) comprising a conductive carrier (110) is used for making contact, on which carrier a multiplicity of nanoneedles (120) are arranged and on which carrier adjacent nanoneedles are at a distance from one another which is smaller than the size of the object, and that the object is brought into contact with the nanoneedles.

Abstract: A memory cell array includes a number of memory cells, each of the memory cells including a source and a drain region defined by corresponding bitlines within a semiconductor substrate. Each of the bitlines has a doped semiconductor region as well as a conductive region in direct electrical contact with the doped semiconductor region.

Abstract: The present invention relates to a method for providing a measuring probe (1, 1a, 2) for a probe microscopic examination of a sample in a probe microscope, in particular a scanning probe microscope, in which the measuring probe (1), which has a probe base (1a) and a probe extension (2) formed thereon, is held on a carrier device and the measuring probe (1) is processed before or after a measurement by detaching a section of the probe extension (2). The invention further relates to an arrangement having a probe microscope for the probe microscopic examination of a sample, in particular a scanning probe microscope.

Abstract: The invention relates to a micro-fluidic system including a fluid medium channel that holds a fluid medium containing particles in suspension. According to the invention, the fluid medium channel has an expanded section with an enlarged cross-section along part of its length, in order to reduce the flow speed to allow the analysis of the particles.

Abstract: The invention relates to a particle injector for introducing particles into a carrier flow of a microfluidic system, especially for injecting biological cells into the carrier flow of a cell sorter. The particle injector includes an inlet for receiving the carrier flow, an outlet for discharging the carrier flow including the introduced particles, a carrier flow channel which connects the inlet to the outlet, and an injection channel flowing into the carrier flow channel for introducing the particles into the carrier flow. The inventive particle injector is characterized in that the carrier flow channel has substantially no dead volume.

Abstract: A method is described for non-destructive measurement of vitality of biological cells, especially for determination of apoptosis, in which the at least one cell is exposed to high-frequency alternating, especially rotating, electric fields and/or impedance test fields, and at least one rotation measurement, one dielectrophoresis measurement and/or one impedance measurement is performed with the cell for at least one frequency range or individual frequencies, from which at least one measurement parameter is determined that is characteristic of the vitality state of the cell.

Abstract: A coupling device (100), particularly for liquid-tight coupling of at least one liquid line (10) to a fluidic system (20), is described, which comprises: at least one sealing device (30), which is implemented to receive an end region (11) of the liquid line (10) and has a first sealing surface (31) for placement on an external surface (22) of the fluidic system in such a way that the end of the liquid line (10) is laterally enclosed by the first sealing surface (31) and points toward an opening (23) in the external surface (22), and a clamping device (40), using which the sealing device (30) may be pressed against the fluidic system (20), so that the first sealing surface (31) produces a liquid-tight connection with the external surface (22).

Abstract: The invention relates to a microfluidic system containing a carrier current channel (1) for receiving a carrier current containing particles suspended therein, and at least one electrode arrangement (3) which is arranged in the carrier current channel and used to manipulate the suspended particles (2), the electrode arrangement (3) containing two manipulation electrodes (4, 5). According to the invention, the electrode arrangement (3) contains two centering electrodes (6, 7), in addition to the two manipulation electrodes (4, 5), for centering the particles, the two centering electrodes (6, 7) being arranged in the carrier current channel (1) respectively upstream of one of the two manipulation electrodes (4, 5). The invention also relates to a corresponding control method.

Abstract: The invention relates to a method for handling particles (1, 2) that are suspended in a carrier liquid (3). The method includes the following steps: the carrier liquid (3) is received with the particles (1, 2) in a liquid siphoning device (10) including at least one siphoning opening (11), electrical and/or magnetic separating fields are generated in the liquid siphoning device (10), a sedimentation movement of the particles (1, 2) is created in the liquid, each particle having a sedimentation speed that depends on the action of the separating fields on the particle (1, 2) and the particles (1, 2) forming a plurality of particle fractions (5, 6) according to the sedimentation speeds thereof, and the particle fractions (5, 6) are separately extracted from the liquid siphoning device (10). The invention also relates to a handling device (100) for handling suspended particles (1, 2).

Abstract: Described is a fluidic microsystem (100) including at least one channel (10) through which a particle suspension can flow; and first and second electrode devices (40, 60) which are arranged on first and second channel walls (21, 31) for generating electrical alternating-voltage fields in the channel (10); wherein the first electrode device (40) for field shaping in the channel includes at least one first structure element (41, 51); and the second electrode device (60) includes an area-like electrode layer (61) with a closed second electrode surface which includes a second passivation layer (70); wherein the effective electrode surface of the first structure element (41, 51), of which element (41, 51) there is at least one, is smaller than the second electrode surface; and the second passivation layer (70) is a closed layer which completely covers the second electrode layer (61).

Abstract: A method of discharging a fluid flow with suspended microparticles from a fluidic microsystem (10) is described, whereby the fluid flow converges with at least one output flow to form a discharge flow at the end of a discharge channel (14) of the microsystem, and the discharge flow is delivered through a conduction element (19). A microsystem with a flow output device for implementation of this method is also described.

Abstract: The invention relates to a measuring device and a measuring method for investigating particles which are suspended in a carrier liquid, including several measuring electrodes for carrying out electrical measuring of the particles. It is proposed that during electrical measuring, the particles be fixed in a field cage (4).

Abstract: The invention relates to a method for generating a convective liquid motion in a fluidic microsystem. According to this method, a liquid in a microsystem is simultaneously exposed to an electrical field and a thermal gradient. The electrical field is generated by means of an electrode arrangement which is subjected to a time-variant voltage. In this way, a time variant electrical field is formed in the liquid volume. The thermal gradient is produced by means of at least one radiation absorber located in the compartment which is exposed to at least one external radiation field.

Abstract: A memory cell array includes a number of memory cells, each of the memory cells including a source and a drain region defined by corresponding bitlines within a semiconductor substrate. Each of the bitlines has a doped semiconductor region as well as a conductive region in direct electrical contact with the doped semiconductor region.