about
Ru/Al Multilayers Integrate Maximum Energy Density and Ductility for Reactive Materials.The plasma protein fibrinogen stabilizes clusters of red blood cells in microcapillary flows.Applicability of different hydraulic parameters to describe soil detachment in eroding rills.Optical tweezers reveal relationship between microstructure and nanoparticle penetration of pulmonary mucusAssessment of the "cross-bridge"-induced interaction of red blood cells by optical trapping combined with microfluidics.Elasto-inertial turbulence.The Molecular Structure of Human Red Blood Cell Membranes from Highly Oriented, Solid Supported Multi-Lamellar Membranes.Red cell investigations: art and artefacts.A Model for the Transient Subdiffusive Behavior of Particles in Mucus.A foam model highlights the differences of the macro- and microrheology of respiratory horse mucus.The buckling instability of aggregating red blood cells.Is there a role of C-reactive protein in red blood cell aggregation?Comparing the impact of an acute exercise bout on plasma amino acid composition, intraerythrocytic Ca(2+) handling, and red cell function in athletes and untrained subjects.Serpentine channels: micro-rheometers for fluid relaxation times.Spatiotemporal characterization of interfacial Faraday waves by means of a light absorption technique.Impact height and wall distance in bloodstain pattern analysis--what patterns of round bloodstains can tell us.Numerical-experimental observation of shape bistability of red blood cells flowing in a microchannel.Direct measurement of shear-induced cross-correlations of Brownian motion.Clusters of red blood cells in microcapillary flow: hydrodynamic versus macromolecule induced interaction.Vesicle dynamics in a confined Poiseuille flow: from steady state to chaos.Quantification of depletion-induced adhesion of red blood cells.Regulation of phosphatidylserine exposure in red blood cells.Lysophosphatidic acid induced red blood cell aggregation in vitro.Stimulation of human red blood cells leads to Ca2+-mediated intercellular adhesion.Faraday waves under time-reversed excitation.Rheology of human blood plasma: viscoelastic versus Newtonian behavior.How viscoelastic is human blood plasma?Load Response of the Flagellar Beat.Sliding friction on wet and dry sand.Classification of red blood cell shapes in flow using outlier tolerant machine learning.Antimargination of Microparticles and Platelets in the Vicinity of Branching Vessels.Flagellar number governs bacterial spreading and transport efficiencyEffect of spectrin network elasticity on the shapes of erythrocyte doubletsDextran adsorption onto red blood cells revisited: single cell quantification by laser tweezers combined with microfluidicsSpontaneous Formation of Nanopatterns in Velocity-Dependent Dip-Coated Organic Films: From Dragonflies to StripesDrop Formation in Non-Newtonian FluidsNonlinear Elastic Instability in Channel Flows at Low Reynolds NumbersBouncing of polymeric droplets on liquid interfacesThe final stages of capillary break-up of polymer solutionsMeasuring the transverse magnetization of rotating ferrofluids
P50
Q27301329-D616CF9F-19CF-40D7-BDA2-E49CE30C1206Q30573855-396D5E87-0880-4D45-9DF8-A32704750F35Q34746471-19A58B0B-CB39-4772-8BAD-AA81D22485A8Q36389587-13A799CA-5C4B-473C-85D0-264E87423E22Q36411182-B2D1F324-617C-4B39-88EA-507CBB28F904Q36967683-D37CB658-94BD-4298-ADFE-0EF782344882Q37550456-2E828950-A38C-442D-AF71-9EB582306087Q38083126-3BA6023A-19ED-4204-B371-F9C178374EF3Q39026756-AEAB8C12-C0AF-4191-A8C3-8EBE5DD711D5Q40276626-7A8C1650-1B51-4637-A56E-761FC5416D83Q41367341-7136F1E4-EF71-444E-80C3-C0666E76BB2FQ41670351-E45B964C-5C66-4DF7-AB99-B222D352B849Q42494560-AE593681-F138-42BC-AD2B-86FD511D63DEQ44368405-FF29968D-D35C-4C64-9237-4C0A085DD2FAQ46767492-C883AF1D-C80F-4B12-9900-DE1398B24FD1Q47437178-D2FAFAC4-6ADE-44FA-8D15-2554B9D172E3Q50145944-C96090D2-5443-4CC9-B431-9B01F5E7298BQ50196522-3DB7A396-2126-4AFF-9A58-D981310103B5Q50227585-B2F789EA-41F0-4D67-ADC1-5EDC1326AA61Q50458505-47D2049F-BA0D-4041-8753-69699DCCFDF0Q50495667-A99ED9AF-C443-4E77-9EE5-37CEF8CA9042Q50520517-CE9366C8-B5E7-4F3A-B2E3-511C4F17A630Q50526861-4A9F8B2C-7C89-4D10-B44F-589592C7D411Q50535133-E5BC6502-54C6-439F-810C-6601645B69EAQ51244715-F8ECAE60-CE83-46FB-9110-6CEE2AA4DFE9Q51500145-18855192-EF59-4669-B805-26A378F611E1Q52348187-464E5273-4430-442F-B442-ABA7F94F41FCQ52767715-D060C2EB-27A1-4251-A1D4-2656307A5C91Q53280857-B6112535-BC7D-418A-84AA-F8BC930E7EF2Q55433575-4DB17DFE-A621-4DC3-A13C-FF4676874BADQ55716644-DBCF7BE6-5856-4340-9387-4E3A0AB12BCAQ58695883-2B42BC6C-6ED8-4CDE-A632-3D8B2FCB76F4Q60142295-D3AA4251-A235-4499-9661-6BA0B1FF547FQ62761256-EF924531-5F05-4548-9B59-C2AB0F53D135Q62761300-6D51E739-B1F4-430F-B7D1-CF17C55A3C62Q62761311-E928C042-92F8-4693-A7A9-D36E2B830F82Q62761321-CCF2F278-1D3A-4545-A672-768BA6010072Q62761329-90E2727C-A434-46DE-9383-592C8E3B6DDFQ62761337-1E1ACFC9-CC5D-45EC-AFC5-2BD7C500A7F9Q62761351-639C207B-E877-4EBD-9B19-ACB085E63A9D
P50
description
hulumtues
@sq
researcher
@en
հետազոտող
@hy
name
Christian Wagner
@ast
Christian Wagner
@en
Christian Wagner
@es
Christian Wagner
@nl
Christian Wagner
@sl
type
label
Christian Wagner
@ast
Christian Wagner
@en
Christian Wagner
@es
Christian Wagner
@nl
Christian Wagner
@sl
prefLabel
Christian Wagner
@ast
Christian Wagner
@en
Christian Wagner
@es
Christian Wagner
@nl
Christian Wagner
@sl
P106
P21
P2456
01/2903-11
P31
P496
0000-0001-7788-4594