sameAs
Cell substratum adhesion during early development of Dictyostelium discoideumChemotaxis of Dictyostelium discoideum: collective oscillation of cellular contactsA stochastic description of Dictyostelium chemotaxis.Crosstalk of cardiomyocytes and fibroblasts in co-cultures.Collective behavior of Dictyostelium discoideum monitored by impedance analysisLive cell flattening - traditional and novel approaches.Flight-crash events in turbulence.Termination of atrial fibrillation using pulsed low-energy far-field stimulationPhase-resolved analysis of the susceptibility of pinned spiral waves to far-field pacing in a two-dimensional model of excitable media.Low-energy control of electrical turbulence in the heartModeling self-organized spatio-temporal patterns of PIP₃ and PTEN during spontaneous cell polarization.Actin cytoskeleton of chemotactic amoebae operates close to the onset of oscillations.Fast propagation regions cause self-sustained reentry in excitable media.Microfluidic tools for quantitative studies of eukaryotic chemotaxis.Scanning x-ray nanodiffraction on Dictyostelium discoideum.On the swimming of Dictyostelium amoebae.Spatiotemporal transition to conduction block in canine ventricle.Double dendrite growth in solidification.Convective instability and boundary driven oscillations in a reaction-diffusion-advection model.Cilia-based flow network in the brain ventricles.Curvature of lagrangian trajectories in turbulence.Dissipative Effects on Inertial-Range Statistics at High Reynolds Numbers.Can Hail and Rain Nucleate Cloud Droplets?Variability and Order in Cytoskeletal Dynamics of Motile Amoeboid Cells.Noisy Oscillations in the Actin Cytoskeleton of Chemotactic Amoeba.Variable density turbulence tunnel facility.Unusual spiral wave dynamics in the Kessler-Levine model of an excitable medium.Continuous transition between two limits of spiral wave dynamics in an excitable medium.Single-Particle Motion and Vortex Stretching in Three-Dimensional Turbulent Flows.Rapid switching of chemical signals in microfluidic devices.Chemotaxis in microfluidic devices--a study of flow effects.Superlattice patterns in forced thermal convection.Flow-driven waves and phase-locked self-organization in quasi-one-dimensional colonies of Dictyostelium discoideum.Time-reversal-symmetry breaking in turbulence.Logarithmic spatial variations and universal f-1 power spectra of temperature fluctuations in turbulent Rayleigh-Bénard convection.Transition to the ultimate state of turbulent Rayleigh-Bénard convection.The cooperation of thehavesand thehave-notsEffects of developmental variability on the dynamics and self-organization of cell populationsGeometrical factors in propagation block and spiral wave initiationUltimate-state transition of turbulent Rayleigh-Bénard convection
P50
Q27312435-1C0503D7-FBBF-4C70-9519-0EECEC69A2C4Q27320107-D385E4EF-C590-4BAE-8098-9A0D457E4F98Q28483940-6A944EEC-1958-434E-87EE-4FB308CB4207Q30399436-ABE3E0FC-8B70-473B-99CA-89DA79A329C6Q30454381-1485972B-45EA-413E-B164-CCC34F4FFDF5Q30494587-AF2A1A90-02C8-4D15-83B9-00A50F75AD40Q30579541-C438F9EE-D84A-422B-803C-B225E988BDABQ33839378-E65EA93E-4896-426B-88E4-F9F0F3B9118BQ34150043-3EA9227F-C6C3-494F-9733-F4E027880295Q35157692-76D4D1A3-F477-460B-8B43-C42A223F0770Q35920156-32B1503A-F39E-4BED-BC1E-07C5DDD55DE1Q36672979-E61AECFA-0354-48AD-B080-E0EBBF71DE9CQ37640391-3D61E0C0-0B35-41FC-9477-754C031FAD89Q37904252-540FD9B9-57E3-4157-8F78-F617C43A59ABQ41734396-2CD6F074-D367-4B2E-A484-99D2070F0F33Q42380736-3C7AEA29-DD8D-4A80-9961-2E4970545DF5Q43893176-28139A30-EB3C-4C32-845E-664388721587Q46642472-06A9C297-6CD8-4B32-9E06-30FE45F9F5DCQ47631359-DFA21A8C-F05B-40BD-8D9C-9FC99163032CQ48635043-84FB55D5-3CF0-4653-80DB-E5B4BC3D0EB4Q48914975-20D33E19-0C0F-444F-880C-8CB268F12582Q50004917-0E05C698-91C4-468C-92F8-EC5FA771F0DEQ50005055-0942956D-7B6F-4B1A-8F90-6A03803915A5Q50101936-08EDE370-8EA0-41AF-A8E1-792FFEBCA556Q50571358-39AD7AE9-8ADF-4BDD-9D3A-9FFC63D3B9BCQ50607921-9532BF20-2376-4EE1-97A0-C31F8D76D34FQ50906545-86691F34-887F-4ABB-BB54-EA1DB1DF18C8Q51106764-FEE1657E-FDCC-413D-8F97-8D0516161F71Q51383934-A5C6F01A-25AF-4930-8C24-D4C2868CD277Q51563115-EDF7676C-A2F1-4A05-B1DE-0AE736B81125Q51572574-D692AB9F-CDEB-400E-80CD-13955DE56972Q51758555-E07A8438-7B4F-42C3-992F-5C3D0C570C67Q53331074-00F0FBC8-9235-4255-A900-0FC20008C4B2Q53472611-E3F5F64C-0DE4-4C84-B020-1400AEEB968FQ53549740-6AEC6C8A-509B-41D3-9DB9-654B3917A3C8Q53666031-AEC2A588-81FF-43F8-80AB-98FCB96E4CCAQ56991526-28FBC742-DA77-4DC7-B34D-9E3FF8E2F450Q56991535-9DD83405-8FDA-4C2D-A364-5B1E87D103A2Q56991540-A5E5F7F2-8A5C-4548-8643-1AC7E754FA36Q56991545-8CDDAA13-683A-4675-928A-3A2842B2C7E2
P50
description
Duits natuurkundige
@nl
German physicist
@en
German physicist
@en-ca
German physicist
@en-gb
Saksamaa füüsik
@et
deutscher Physiker
@de
fisiceoir Gearmánach
@ga
fizician german
@ro
fizikan gjerman
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físic alemany
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name
Eberhard Bodenschatz
@af
Eberhard Bodenschatz
@an
Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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type
label
Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
@da
altLabel
Eberhardt Bodenschatz
@en
prefLabel
Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
@bar
Eberhard Bodenschatz
@br
Eberhard Bodenschatz
@ca
Eberhard Bodenschatz
@co
Eberhard Bodenschatz
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Eberhard Bodenschatz
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Eberhard Bodenschatz
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P214
P227
P1412
P1559
Eberhard Bodenschatz
@de
P19
P21
P214
P227
1137719540
P31
P496
0000-0002-2901-0144
P569
1959-04-22T00:00:00Z
P734
P735
P7859
viaf-57246296