Abstract: The present invention relates to the use of a porous polymer etched ion-track membrane as separator for batteries comprising a positive electrode, a negative electrode and a liquid electrolyte comprising at least one salt of a cationic ion in solution in a solvent, and to batteries comprising such a membrane as porous separator.

Abstract: A template based process is used for the production of the nanowire structural element, wherein the nanowires are electrochemically depositioned in the nanopores. The irradiation is carried out at different angles, such that a nanowire network is formed. The hollow chamber-like structure in the nanowire network is established through the dissolving of the template foil and removal of the dissolved template material. The interconnecting of the nanowires provides stability to the nanowire structural element and an electrical connection between the nanowires is created thereby.

Abstract: A method is disclosed for irradiation planning for the irradiation of a moving target volume located in a body with a particle beam irradiation facility by means of rescanning, which method has the steps of defining the target volume in a reference condition of the motion, dividing the target volume among a plurality of target points that can be individually approached with a particle beam, calculating a nominal dose to be deposited in each of the target points of the target volume, defining a number of rescanning passes in which each of the target points of the target volume are approached, calculating a mean motion to be expected of the target points of the target volume based on a motion model, taking into account the mean motion to be expected of the target points of the target volume in the irradiation planning in such a manner that the deviation of the expected dose deposition from the nominal dose for each target point is determined, and the nominal dose for each target point is corrected on the basis

Abstract: The invention concerns the production of segmented nanowires and components having said segmented nanowires. For the production of the nanowire structural element, a template based process is used preferably, wherein the electrochemical deposition of the nanowires in nanopores is carried out. In this manner, numerous nanowires are created in the template foil. For the electrochemical deposition of the nanowires, a reversed pulse procedure with an alternating sequence consisting of cathodic deposition pulses and anodic counter-pulses is carried out. By this means, segmented nanowires can be produced.

Abstract: Method for irradiation planning of a target volume with a scanned particle beam, comprising the following steps: defining a target volume located in a body, subdividing the target volume into a plurality of individually approachable target points, defining a number of temporally consecutive irradiation sub-plans, dividing the target points of the target volume among the irradiation sub-plans in subsets, wherein the subsets are distributed over the entire target volume, and wherein mutually adjacent target points of the target volume are each assigned to different irradiation sub-plans.

Abstract: The present disclosure relates to a mobile data center unit, which is adapted to house at least one rack being designed to provide storage space for electronic equipment. The mobile data center unit is equipped with passive cooling means in order to provide dissipation of heat being generated by the electronic equipment.

Abstract: The present disclosure relates to a method and to an irradiation system for irradiating a moving target volume with an ion beam, in particular for tumor therapy, wherein ion radiography measurements of the target volume are performed and the irradiation for deposition purposes and for radiography purposes is performed with the same ion beam but consecutively in time by alternating the energy of the ion beam between a higher radiography energy and a lower deposition energy using, for example, a passive energy modulator proximal with respect to the patient.

Abstract: To control of an irradiation installation, a particle beam is generated with a beam intensity, and a beam quality of the particle beam is monitored with a beam monitoring device. One of several adjustable measurement ranges is selected, wherein the measurement range of the beam monitoring device is set depending on the beam intensity of the particle beam and/or depending on a particle count to be applied.

Abstract: The present disclosure relates to a particle energy modulating device for variably changing the energy of the particles of a particle beam. The particle energy modulating device has a variable energy varying device with a control value correcting device for correcting a supplied control value. The control value correcting device corrects the supplied control values through the use of previously determined calibration data.

Abstract: The invention concerns a nanowire structural element suited for use in a microreactor system or microcatalyzer system. A template based process is used for the production of the nanowire structural element, wherein the nanowires are electrochemically depositioned in the nanopores. The irradiation is carried out at different angles, such that a nanowire network is formed. The hollow chamber-like structure in the nanowire network is established through the dissolving of the template foil and removal of the dissolved template material. The interconnecting of the nanowires provides stability to the nanowire structural element and an electrical connection between the nanowires is created thereby.

Abstract: The present disclosure relates to a method and to an irradiation system for irradiating a moving target volume with an ion beam, in particular for tumor therapy, wherein ion radiography measurements of the target volume are performed and the irradiation for deposition purposes and for radiography purposes is performed with the same ion beam but consecutively in time by alternating the energy of the ion beam between a higher radiography energy and a lower deposition energy using, for example, a passive energy modulator proximal with respect to the patient.

Abstract: The invention concerns a process for the deposition of an intended dose distribution in a cyclically moved target region moving cyclically (102) by means of multiple irradiations with a beam (105) approaching matrix points of a target matrix in at least two scannings, wherein in each of the scannings, matrix points are approached sequentially. It is characterized through the steps: establishing the maximal tolerance level for local deviation from the intended dose distribution, de-synchronizing the sequence of the irradiation and the cyclical motion of the target region (102), and partitioning the irradiation of the target region (102) in a sufficient number of scannings such that local deviations from the intended dose distribution correspond at most to the maximal tolerance level of deviation from the intended dose distribution.

Abstract: The present disclosure relates to a particle energy modulating device for variably changing the energy of the particles of a particle beam. The particle energy modulating device has a variable energy varying device with a control value correcting device for correcting a supplied control value. The control value correcting device corrects the supplied control values through the use of previously determined calibration data.

Abstract: The invention relates to a method for checking an irradiation installation in which a dose distribution is deposited in a target object by means of a treatment beam, said method comprising the following steps: an irradiation planning data record optimized for the irradiation of a moving target volume is provided; a movement signal that reproduces a movement of the target volume is provided; a phantom is irradiated, said phantom being formed for detecting a dose distribution deposited in the phantom during or after the irradiation, using the control parameters stored at the irradiation planning data record and the movement signal; a dose distribution deposited in the phantom is determined; a dose distribution to be expected is calculated on the basis of parameters that are related to the control of the irradiation installation during the irradiation; and the determined dose distribution deposited in the phantom is compared to the calculated dose distribution to be expected.

Abstract: The invention concerns a device and a process for adjusting the range of an ion beam, in particular for irradiation in tumor therapy. For this purpose, first the reference position of a target volume to be irradiated is determined. Subsequently, the range of an ion beam is configured such that said beam is adjusted to the reference position of the target volume, in such a manner that the Bragg peak, i.e. the maximal energy loss and thereby the maximal damage occurs in the region of the target volume which is to be destroyed. In the case that it has been determined that the reference position has been altered by a movement of the target volume, the ion beam is then deflected from the beam axis such that the ion beam is directed to various regions of a range modulator, in order that the ion beam experience a correspondingly adjusted energy loss in passing through the range modulator.

Abstract: The invention concerns the production of segmented nanowires and components having said segmented nanowires. For the production of the nanowire structural element, a template based process is used preferably, wherein the electrochemical deposition of the nanowires in nanopores is carried out. In this manner, numerous nanowires are created in the template foil. For the electrochemical deposition of the nanowires, a reversed pulse procedure with an alternating sequence consisting of cathodic deposition pulses and anodic counter-pulses is carried out. By this means, segmented nanowires can be produced.

Abstract: A method for irradiating a target volume includes defining a target region having a plurality of target points. The target points are individually approachable. The method includes defining a number of rescanning passes, in which the target region is scanned multiple times, such that the plurality of target points of the target region is approached variously often during the rescanning passes. At least some target points of the plurality of target points are not approached in all of the rescanning passes. The approaching of the plurality of target points is distributed among the rescanning passes such that for a target point of the plurality of target points that is not approached in all of the rescanning passes, at least one further rescanning pass, in which the target point is not approached, is located before a final rescanning pass, in which the target point is approached.

Abstract: The present disclosure relates to a mobile data centre unit, which is adapted to house at least one rackbeing designed to provide storage space for electronic equipment. The mobile data centre unit is equipped with passive cooling means in order to provide dissipation of heat being generated by the electronic equipment.

Abstract: To control of an irradiation installation, a particle beam is generated with a beam intensity, and a beam quality of the particle beam is monitored with a beam monitoring device. One of several adjustable measurement ranges is selected, wherein the measurement range of the beam monitoring device is set depending on the beam intensity of the particle beam and/or depending on a particle count to be applied.

Abstract: Producing a nanowire structural element with a nanowire array between two cover layers forming a hollow chamber permeated in a column-like manner with nanowires. The process includes: preparing a template foil; application of a first surface covering electroconductive cover layer on a first side of the template foil; generation of numerous nanopores in the template foil; generation of nanowires in the nanopores wherein an electroconductive material fills the nanopores by electrochemical deposition, wherein the nanowires grow within the nanopores on the first cover layer; generation of a second surface filling cover layer on the second side of the template foil thus forming a sandwich-like arrangement of the two cover layers and the template foil permeated with nanowires; and clearing the structured hollow chamber between by dissolving of the template foil and removal of the dissolved template substance, wherein the two cover layers remain intact.