25 research outputs found
Experimental characterization of the PT asymmetry with balanced inflow and outflow at different Reynolds numbers
This research focused on characterizing the PT asymmetry with balanced inflow and outflow conditions at different Reynolds number using experimental method. The characterization process utilized PIV data to explore the relationship between PT asymmetry and Reynolds number in two different experiments. In the first experiment, balanced inflow and outflow are used to generate the flow field in a cuboid test section with different Reynolds number, the inflow and outflow are located at the central of left side and right side of the test section. In the second experiment, a main flow is introduced to the first experiment by adding another inflow and outflow which locate at a symmetric position on the bottom side of the test section. The flow field is generated by the two inflows and outflows with different Reynolds number. The results show that there is a linear relationship between PT asymmetry and Reynolds number when Reynolds number is less than 200 for a balanced inflow/outflow situation. They also show that there is a decreasing trend of PTasymmetry when Reynolds number increases for balanced inflow/outflow combined with main flow
Effects of shear-thinning viscosity and viscoelastic stresses on flagellated bacteria motility
The behavior of flagellated bacteria swimming in non-Newtonian media remains an area with contradictory and conflicting results. We report on the behavior of wild-type and smooth-swimming E. coli in Newtonian, shear-thinning, and viscoelastic media, measuring their trajectories and swimming speed using a three-dimensional real-time tracking microscope. We conclude that the speed enhancement in Methocel solution at higher concentrations is due to shear thinning and an analytical model is used to support our experimental result. We argue that shear-induced normal stresses reduce wobbling behavior during cell swimming but do not significantly affect swimming speed. However, the normal stresses play an important role in decreasing the flagellar bundling time, which changes the swimming-speed distribution. A dimensionless number, the āstrangulation numberā (Str) is proposed and used to characterize this effect
Changes in the flagellar bundling time account for variations in swimming behavior of flagellated bacteria in viscous media
Although the motility of the flagellated bacteria, Escherichia coli, has been
widely studied, the effect of viscosity on swimming speed remains
controversial. The swimming mode of wild-type E.coli is often idealized as a
"run-and- tumble" sequence in which periods of swimming at a constant speed are
randomly interrupted by a sudden change of direction at a very low speed. Using
a tracking microscope, we follow cells for extended periods of time in
Newtonian liquids of varying viscosity, and find that the swimming behavior of
a single cell can exhibit a variety of behaviors including run-and-tumble and
"slow-random-walk" in which the cells move at relatively low speed. Although
the characteristic swimming speed varies between individuals and in different
polymer solutions, we find that the skewness of the speed distribution is
solely a function of viscosity and can be used, in concert with the measured
average swimming speed, to determine the effective running speed of each cell.
We hypothesize that differences in the swimming behavior observed in solutions
of different viscosity are due to changes in the flagellar bundling time, which
increases as the viscosity rises, due to the lower rotation rate of the
flagellar motor. A numerical simulation and the use of Resistive Force theory
provide support for this hypothesis
Public opinion on types of voice systems for older adults
Public opinion may influence the adoption of technologies for older adults, yet studies on different contexts of technology for older adults is limited. In an online YouGov survey (N = 500) with text-and-image vignettes, participants gave more positive ratings of social acceptability, trust, and perceived impact on eldercare when the voice assistant (āVAā system) shown in the vignette performed a functional task (medication adherence) versus when it performed a social task (companionship). The VA received more positive sentiment comments when it appeared to use a machine learning (ML)-based dialogue system compared to when it appeared to be using a rule-based dialogue system. These results may assist designers and stakeholders select what type of voice system to develop or use with older adults
Controlling Organization and Forces in Active Matter Through Optically-Defined Boundaries
Living systems are capable of locomotion, reconfiguration, and replication.
To perform these tasks, cells spatiotemporally coordinate the interactions of
force-generating, "active" molecules that create and manipulate non-equilibrium
structures and force fields that span up to millimeter length scales [1-3].
Experimental active matter systems of biological or synthetic molecules are
capable of spontaneously organizing into structures [4,5] and generating global
flows [6-9]. However, these experimental systems lack the spatiotemporal
control found in cells, limiting their utility for studying non-equilibrium
phenomena and bioinspired engineering. Here, we uncover non-equilibrium
phenomena and principles by optically controlling structures and fluid flow in
an engineered system of active biomolecules. Our engineered system consists of
purified microtubules and light-activatable motor proteins that crosslink and
organize microtubules into distinct structures upon illumination. We develop
basic operations, defined as sets of light patterns, to create, move, and merge
microtubule structures. By composing these basic operations, we are able to
create microtubule networks that span several hundred microns in length and
contract at speeds up to an order of magnitude faster than the speed of an
individual motor. We manipulate these contractile networks to generate and
sculpt persistent fluid flows. The principles of boundary-mediated control we
uncover may be used to study emergent cellular structures and forces and to
develop programmable active matter devices
Persistent fluid flows defined by active matter boundaries
Biological systems achieve precise control over ambient fluids through the self-organization of active protein structures including flagella, cilia, and cytoskeletal networks. In active structures individual proteins consume chemical energy to generate force and motion at molecular length scales. Self-organization of protein components enables the control and modulation of fluid flow fields on micron scales. The physical principles underlying the organization and control of active-matter driven fluid flows are poorly understood. Here, we apply an optically-controlled active-matter system composed of microtubule filaments and light-switchable kinesin motor proteins to analyze the emergence of persistent flow fields in a model active matter system. Using light, we form contractile microtubule networks of varying shape. We analyze the fluid flow fields generated by a wide range of microtubule network geometries and explain the resulting flow fields within a unified theoretical framework. We specifically demonstrate that the geometry of microtubule flux at the boundary of contracting microtubule networks predicts the steady-state fluid flow fields across polygonal network geometries through finite-element simulations. Our work provides a foundation for programming microscopic fluid-flows with controllable active matter and could enable the engineering of versatile and dynamic microfluidic devices
Controlling Organization and Forces in Active Matter Through Optically-Defined Boundaries
Living systems are capable of locomotion, reconfiguration and replication. To perform these tasks, cells spatiotemporally coordinate the interactions of force-generating, āactiveā molecules that create and manipulate non-equilibrium structures and force fields of up to millimetre length scales. Experimental active-matter systems of biological or synthetic molecules are capable of spontaneously organizing into structures and generating global flows. However, these experimental systems lack the spatiotemporal control found in cells, limiting their utility for studying non-equilibrium phenomena and bioinspired engineering. Here we uncover non-equilibrium phenomena and principles of boundary-mediated control by optically modulating structures and fluid flow in an engineered system of active biomolecules. Our system consists of purified microtubules and light-activatable motor proteins that crosslink and organize the microtubules into distinct structures upon illumination. We develop basic operationsādefined as sets of light patternsāto create, move and merge the microtubule structures. By combining these operations, we create microtubule networks that span several hundred micrometres in length and contract at speeds up to an order of magnitude higher than the speed of an individual motor protein. We manipulate these contractile networks to generate and sculpt persistent fluid flows. The principles of boundary-mediated control that we uncover may be used to study emergent cellular structures and forces and to develop programmable active-matter devices
Persistent fluid flows defined by active matter boundaries
Experimental data for active matter (microtubule and kinesin motor) contraction and fluid flow. Hollow square cases