The dynamics of active colloids is very sensitive to the presence of boundaries and interfaces which therefore can be used to control their motion. Here we analyze the dynamics of active colloids adsorbed at a fluid-fluid interface. By using a mesoscopic numerical approach which relies on an approximated numerical solution of the Navier-Stokes equation, we show that when adsorbed at a fluid interface, an active colloid experiences a net torque even in the absence of a viscosity contrast between the two adjacent fluids. In particular, we study the dependence of this torque on the contact angle of the colloid with the fluid-fluid interface and on its surface properties. We rationalize our results via an approximate approach which accounts for...
Colloidal particle submerged in a non-equilibrium fluid with a concentration gradient of solutes exp...
Active colloids, which can be thought of as the synthetic analog of swimming bacteria, exhibit remar...
Various aspects of self-motility of chemically active colloids in Newtonian fluids can be captured b...
The dynamics of active colloids is very sensitive to the presence of boundaries and interfaces which...
We show theoretically that near a fluid-fluid interface a single active colloidal particle generatin...
An important class of inter-particle forces, known as depletion forces, is induced by the presence o...
At the surfaces of autophoretic colloids, slip velocities arise from local chemical gradients that a...
The active motion of phoretic colloids leads them to accumulate at boundaries and interfaces. Such a...
Breaking spatial symmetry is an essential requirement for phoretic active particles to swim at low R...
Active fluids comprise a variety of systems composed of elements immersed in a fluid environment whi...
It is now generally accepted that aside from liquid and gaseous phases, the solid phase is also resp...
Colloidal particles adsorbed at fluid-fluid interfaces interact via mechanisms that can be specific ...
The self-assembly of colloids at fluid interfaces is a well-studied research field both for gaining ...
Colloidal particles confined at liquid interfaces have important applications, for example in the st...
Hypothesis: The collective dynamics and self-assembly of colloids floating at a fluid/fluid interfac...
Colloidal particle submerged in a non-equilibrium fluid with a concentration gradient of solutes exp...
Active colloids, which can be thought of as the synthetic analog of swimming bacteria, exhibit remar...
Various aspects of self-motility of chemically active colloids in Newtonian fluids can be captured b...
The dynamics of active colloids is very sensitive to the presence of boundaries and interfaces which...
We show theoretically that near a fluid-fluid interface a single active colloidal particle generatin...
An important class of inter-particle forces, known as depletion forces, is induced by the presence o...
At the surfaces of autophoretic colloids, slip velocities arise from local chemical gradients that a...
The active motion of phoretic colloids leads them to accumulate at boundaries and interfaces. Such a...
Breaking spatial symmetry is an essential requirement for phoretic active particles to swim at low R...
Active fluids comprise a variety of systems composed of elements immersed in a fluid environment whi...
It is now generally accepted that aside from liquid and gaseous phases, the solid phase is also resp...
Colloidal particles adsorbed at fluid-fluid interfaces interact via mechanisms that can be specific ...
The self-assembly of colloids at fluid interfaces is a well-studied research field both for gaining ...
Colloidal particles confined at liquid interfaces have important applications, for example in the st...
Hypothesis: The collective dynamics and self-assembly of colloids floating at a fluid/fluid interfac...
Colloidal particle submerged in a non-equilibrium fluid with a concentration gradient of solutes exp...
Active colloids, which can be thought of as the synthetic analog of swimming bacteria, exhibit remar...
Various aspects of self-motility of chemically active colloids in Newtonian fluids can be captured b...