0000000001324769

AUTHOR

Jan Borovsky

showing 8 related works from this author

M6_Microfluidics_for_CNT

2018

The hydrodynamic trap holds an incoming droplet until the arrival of following droplet. The previous droplet leaves the trap in very rapid manner.

Condensed Matter::Quantum GasesPhysics::Fluid Dynamicsendocrine systemtrap occupation timetechnology industry and agriculturePhysics::Atomic and Molecular ClustersmicrofluidicsPhysics::Atomic Physicscomplex mixturesdroplet trapeye diseases
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M8_Microfluidics_for_CNT

2018

A comparation of two sorting strategies. While the shallow channel guides the droplets more precisely to the sorting point, the confined droplets are more vulnerable to coalescence and break-up. The deep channel lowers the positioning precision, however, the droplets are more stable.

Physics::Fluid Dynamicsshallow sortingconfined regimePhysics::Atomic and Molecular Clustersmicrofluidicsfree regimedeep sorting
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M11_Microfluidics_for_CNT

2018

The subtle solubility of water in n-decane causes leaking of the droplet content. If the n-decane flows by static droplets, it carries the water slowly away up to the total disappearance of the droplets.

endocrine systemdroplet stabilitytechnology industry and agriculturemicrofluidicscontent leakingwater solubility in n-decanecomplex mixtureseye diseases
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M1_Microfluidics_for_CNT

2018

High-frequency droplet production in step-emulsification microfluidic device. The abrupt change in channel cross section causes creation of the droplets. The closely-packed droplets automatically order in hexagonal pattern.

Physics::Fluid Dynamicsendocrine systemdroplet formationstep-emulsificationtechnology industry and agriculturePhysics::Atomic and Molecular Clustersmicrofluidicshexagonal patterncomplex mixtureseye diseases
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M7_Microfluidics_for_CNT

2018

A comparation of two designs of a droplet trap. While the droplet exchange is mediated by direct droplet contact in the symmetric design, a short continuous phase plug mediated the droplet exchange in the asymmetric design.

Physics::Fluid Dynamicsendocrine systemasymmetric droplet traptechnology industry and agriculturePhysics::Atomic and Molecular Clustersmicrofluidicscomplex mixtureseye diseasessymmetric droplet trap
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M2_Microfluidics_for_CNT

2018

Droplet production in flow-focusing microfluidic device. The droplets are cut off from the water phase flow by pressure of oil from the side channels. The movement of the droplets proves laminar flow in the device.

Physics::Fluid Dynamicsdroplet formationPhysics::Atomic and Molecular Clustersmicrofluidicslinear flowflow-focusing
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M10_Microfluidics_for_CNT

2018

Droplets are preferentially directed to the channel with higher flow rate in the passive sorting junction. When the droplets are exposed to DEP field, the DEP force pull them to the narrower channel.

Physics::Fluid DynamicsDEPtechnology industry and agriculturePhysics::Atomic and Molecular Clustersmicrofluidicsrespiratory systemcomplex mixtureseye diseasesPhysics::History of Physicssortingrespiratory tract diseasesComputer Science::Information Theory
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M9_Microfluidics_for_CNT

2018

The droplets in contact coalesce when exposed to DEP filed.

Physics::Fluid DynamicsDEPelectrocoalescencePhysics::Atomic and Molecular ClustersmicrofluidicsQuantitative Biology::Populations and EvolutionComputer Science::Operating SystemsPhysics::History of Physics
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