Abstract: A dye encompassing a donor-acceptor-donor motif having a structure according to formulae (1), (2), (3), (4), (5), (6), (7) or (8): wherein, independently from each other, R1=H, CnF2n+1, C5NH4, C4N2H3, (CH2)nQ, (C6H5?m)Qm or (OCH2CH2)nQ, wherein m=1, 2, 3 or 4, and Q is selected from: H, C(H)=CH2, OC(O)C(H)?CH2, OC(O)C(CH3)?CH2, N(H)CC(H)?CH2, N(H)CC(CH3)?CH2, Si(OH)3, Si(OCH3)3, Si(OC2H5)3, OH, SH, NH2, NO2, CN, CF3, C?CH, N?N+?N?, F, Cl, Br, I, C2H3O, C6H5, C(O)F, C(O)Cl, C(O)Br, C(O)I, CF3SO3, B(OZ)2, OZ, C(O)Z, C(O)OZ, C(O)NHZ, C(O)NZ2, and SSZ, wherein Z=H, CnH2n+1, CnF2n+1, CnH2nC(H)?CH2, CnH2nC?CH, C6H4C(H)?CH2, C6H5, CH2C6H5, C5NH4 or C4N2H3, wherein n=1 to 20; R2=H, CnF2n+1, C5NH4, C4N2H3, (CH2)nQ or (C6H5?m)Qm wherein m=1, 2, 3 or 4, and Q is selected from: H, C(H)?CH2, OC(O)C(H)?CH2, OC(O)C(CH3)?CH2, N(H)CC(H)?CH2, N(H)CC(CH3)?CH2, Si(OH)3, Si(OCH3)3, Si(OC2H5)3, OH, SH, NH2, NO2, CN, CF3, C?CH, N?N+?N?, F, Cl, Br, I, C2H3O, C6H5, C(O)F, C(O)Cl, C(O)Br, C(O)I, CF3SO3, B(OZ)2, OZ, C(O)Z, C(O

Abstract: Described are a transducer made of at least three transducer elements which approximate a sector of an elementary wave with a virtual point source, and a transducer arrangement with three transducers made of at least three transducer elements, wherein the transducers, in the cross section, are disposed along the shorter base and the two non-parallel legs of a virtual trapezoid. Moreover, the invention relates to an ultrasonic probe system comprising the transducer arrangement according to the invention and an inspection method using a transducer made of at least three transducer elements, with the number of transducer elements experiencing a virtual increase.

Abstract: The invention relates to an additive production method involving the production of a layer of geometrically compact particles, having the following steps: a) providing a particle layer depositing arrangement, comprising a first and a second semi-chamber, wherein a partition separates the first semi-chamber from the second semi-chamber, and the partition is permeable for a dispersion medium and impermeable for particles dispersed in the dispersion medium; b) providing a particle dispersion comprising the dispersion medium and particles dispersed therein in the first semi-chamber, the particle dispersion being distributed substantially homogenously in the first semi-chamber; c) generating a pressure gradient between the first and the second semi-chamber such that the pressure gradient in the first semi-chamber causes a particle dispersion flow directed towards the partition; and d) depositing a particle aggregate material comprising geometrically compact particles on the partition by transporting a dispersion a

Abstract: A method for examining a sample (50) including the steps of exciting a propagating mechanical deformation (2) in the sample (50) using a fluidic oscillator (10), and determining a characteristic of the mechanical deformation (2).

Abstract: The invention relates to a method for simulating an impact of particles/radiation on an object: (a) Providing a control memory including control memory locations and a mass memory including mass memory locations. (b) Building a simulated particle/radiation unit, wherein this particle or the radiation unit is designated for impact on the object. (c) Defining at least one property/energetic state of a particular, individual particle/radiation unit. (d) Carrying out a simulated impact of the particular individual particle/radiation unit on the object, wherein a distribution function of an impact site and/or of a velocity of the particular individual particle/radiation unit is used. (e) Determining or querying at least one local property and/or a local energetic state of at least one affected object element. (f) Determining or querying a collision event caused by the impact and acting on the individual particle/radiation unit and/or the affected object element or volume element.

Abstract: A double fluorescent particle comprises: a core with a first fluorescence; and a molecularly imprinted polymer (MIP) shell with a second fluorescence; wherein the MIP is an organic polymer comprising elements selected from the group consisting of: C, H, O, N, P, and S; wherein the MIP is adapted to selectively bind to a cell surface structure; wherein the first fluorescence is generated by an entity selected from the group consisting of: a carbon nanodot, an alkaline earth metal fluoride, a dye-doped polymer, a dye-doped stabilized micelle, a P-dot—i.e.

Abstract: An analysis device for a gaseous sample includes a mass spectrometer (6) having a measurement chamber and an inlet (5) leading into the measurement chamber, and a laser irradiation unit (30, 3). The analysis device is designed to convey the gaseous sample to the inlet by a flow including the gaseous sample. The laser irradiation unit (30, 3) is designed to ignite a plasma (1) by a laser beam (2?) in the flow (4).

Abstract: Described are a transducer made of at least three transducer elements which approximate a sector of an elementary wave with a virtual point source, and a transducer arrangement with three transducers made of at least three transducer elements, wherein the transducers, in the cross section, are disposed along the shorter base and the two non-parallel legs of a virtual trapezoid. Moreover, the invention relates to an ultrasonic probe system comprising the transducer arrangement according to the invention and an inspection method using a transducer made of at least three transducer elements, with the number of transducer elements experiencing a virtual increase.

Abstract: The present invention relates to a molecularly imprinted polymer for binding glycans, wherein the molecularly imprinted polymer is obtainable by providing a saccharide template such as a glycan; providing at least two functional monomers capable of cooperatively; interacting with the template; providing a crosslinking monomer; polymerizing the monomers optionally dissolved in a solvent, in presence of the saccharide template; and removing the template from the formed polymer. The invention is also related to a method for their production and use of the molecularly imprinted polymer.

Abstract: The invention relates to an additive production method involving the production of a layer of geometrically compact particles, having the following steps: a) providing a particle layer depositing arrangement, comprising a first and a second semi-chamber, wherein a partition separates the first semi-chamber from the second semi-chamber, and the partition is permeable for a dispersion medium and impermeable for particles dispersed in the dispersion medium; b) providing a particle dispersion comprising the dispersion medium and particles dispersed therein in the first semi-chamber, the particle dispersion being distributed substantially homogenously in the first semi-chamber; c) generating a pressure gradient between the first and the second semi-chamber such that the pressure gradient in the first semi-chamber causes a particle dispersion flow directed towards the partition; and d) depositing a particle aggregate material comprising geometrically compact particles on the partition by transporting a dispersion a

Abstract: The invention relates to an additive production method involving the production of a layer of geometrically compact particles, having the following steps: a) providing a particle layer depositing arrangement, comprising a first and a second semi-chamber, wherein a partition separates the first semi-chamber from the second semi-chamber, and the partition is permeable for a dispersion medium and impermeable for particles dispersed in the dispersion medium; b) providing a particle dispersion comprising the dispersion medium and particles dispersed therein in the first semi-chamber, the particle dispersion being distributed substantially homogenously in the first semi-chamber; c) generating a pressure gradient between the first and the second semi-chamber such that the pressure gradient in the first semi-chamber causes a particle dispersion flow directed towards the partition; and d) depositing a particle aggregate material comprising geometrically compact particles on the partition by transporting a dispersion a

Abstract: A method for examining a sample (50) including the steps of exciting a propagating mechanical deformation (2) in the sample (50) using a fluidic oscillator (10), and determining a characteristic of the mechanical deformation (2).

Abstract: The invention relates to a method for simulating an impact of particles/radiation on an object: (a) Providing a control memory including control memory locations and a mass memory including mass memory locations. (b) Building a simulated particle/radiation unit, wherein this particle or the radiation unit is designated for impact on the object. (c) Defining at least one property/energetic state of a particular, individual particle/radiation unit. (d) Carrying out a simulated impact of the particular individual particle/radiation unit on the object, wherein a distribution function of an impact site and/or of a velocity of the particular individual particle/radiation unit is used. (e) Determining or querying at least one local property and/or a local energetic state of at least one affected object element. (f) Determining or querying a collision event caused by the impact and acting on the individual particle/radiation unit and/or the affected object element or volume element.

Abstract: An analysis device for a gaseous sample includes a mass spectrometer (6) having a measurement chamber and an inlet (5) leading into the measurement chamber, and a laser irradiation unit (30, 3). The analysis device is designed to convey the gaseous sample to the inlet by a flow including the gaseous sample. The laser irradiation unit (30, 3) is designed to ignite a plasma (1) by a laser beam (2?) in the flow (4).

Abstract: The invention relates to an additive production method involving the production of a layer of geometrically compact particles, having the following steps: a) providing a particle layer depositing arrangement, comprising a first and a second semi-chamber, wherein a partition separates the first semi-chamber from the second semi-chamber, and the partition is permeable for a dispersion medium and impermeable for particles dispersed in the dispersion medium; b) providing a particle dispersion comprising the dispersion medium and particles dispersed therein in the first semi-chamber, the particle dispersion being distributed substantially homogenously in the first semi-chamber; c) generating a pressure gradient between the first and the second semi-chamber such that the pressure gradient in the first semi-chamber causes a particle dispersion flow directed towards the partition; and d) depositing a particle aggregate material comprising geometrically compact particles on the partition by transporting a dispersion a