Generation of Local Diffusioosmotic Flow by Light Responsive Microgels.

Here we show that microgels trapped at a solid wall can issue liquid flow and transport over distances several times larger than the particle size. The microgel consists of cross-linked poly(N-isopropylacrylamide-co-acrylic acid) (PNIPAM-AA) polymer chains loaded with cationic azobenzene-containing surfactant, which can assume either a trans- or a cis-state depending on the wavelength of the applied irradiation. The microgel, being a selective absorber of trans-isomers, responds by changing its volume under irradiation with light of appropriate wavelength at which the cis-isomers of the surfactant molecules diffuse out of the particle interior. Together with the change in particle size, the expelled cis-isomers form an excess of the concentration and subsequent gradient in osmotic pressure generating a halo of local light-driven diffusioosmotic (l-LDDO) flow. The direction and the strength of the l-LDDO depends on the intensity and irradiation wavelength, as well as on the amount of surfactant absorbed by the microgel. The flow pattern around a microgel is directed radially outward and can be maintained quasi-indefinitely under exposure to blue light when the trans-/cis-ratio is 2/1, establishing a photostationary state. Irradiation with UV light, on the other hand, generates a radially transient flow pattern, which inverts from inward to outward over time at low intensities. By measuring the displacement of tracer particles around neutral microgels during a temperature-induced collapse, we can exclude that a change in particle shape itself causes the flow, i.e., just by expulsion or uptake of water. Ultimately, it is its ability to selectively absorb two isomers of photosensitive surfactant under different irradiation conditions that leads to an effective pumping caused by a self-induced diffusioosmotic flow.

[1]  S. Santer,et al.  How to Make a Surface Act as a Micropump , 2022, Advanced Materials Interfaces.

[2]  S. Santer,et al.  Adsorption Kinetics of a Photosensitive Surfactant Inside Microgels , 2021, Macromolecules.

[3]  E. Kramarenko,et al.  Tuning the Volume Phase Transition Temperature of Microgels by Light , 2021, Advanced Functional Materials.

[4]  S. Santer,et al.  Light-induced manipulation of passive and active microparticles , 2020, The European Physical Journal E.

[5]  Anjali Sharma,et al.  Photo-Isomerization Kinetics of Azobenzene Containing Surfactant Conjugated with Polyelectrolyte , 2020, Molecules.

[6]  S. Santer,et al.  Quantification of ordering in active light driven colloids. , 2020, Journal of colloid and interface science.

[7]  S. Santer,et al.  Light driven diffusioosmotic repulsion and attraction of colloidal particles. , 2020, The Journal of chemical physics.

[8]  S. Santer,et al.  Extremely long-range light-driven repulsion of porous microparticles. , 2020, Langmuir : the ACS journal of surfaces and colloids.

[9]  S. Santer,et al.  Kinetics of photo-isomerization of azobenzene containing surfactants. , 2020, The Journal of chemical physics.

[10]  S. Santer,et al.  Light-driven motion of self-propelled porous Janus particles , 2019 .

[11]  O. Guskova,et al.  Photosensitive Cationic Azobenzene Surfactants: Thermodynamics of Hydration and the Complex Formation with Poly(methacrylic acid). , 2018, Langmuir : the ACS journal of surfaces and colloids.

[12]  Jens Harting,et al.  Inertial focusing of finite-size particles in microchannels , 2017, Journal of Fluid Mechanics.

[13]  S. Santer Remote control of soft nano-objects by light using azobenzene containing surfactants , 2018 .

[14]  Jingyun Ma,et al.  Biomaterials Meet Microfluidics: From Synthesis Technologies to Biological Applications , 2017, Micromachines.

[15]  E. Kramarenko,et al.  Communication: Light driven remote control of microgels' size in the presence of photosensitive surfactant: Complete phase diagram. , 2017, The Journal of chemical physics.

[16]  S. Marbach,et al.  Osmotic and diffusio-osmotic flow generation at high solute concentration. I. Mechanical approaches. , 2017, The Journal of chemical physics.

[17]  M. Santer,et al.  Manipulation of small particles at solid liquid interface: light driven diffusioosmosis , 2016, Scientific Reports.

[18]  E. Kramarenko,et al.  Theory of Collapse and Overcharging of a Polyelectrolyte Microgel Induced by an Oppositely Charged Surfactant , 2014 .

[19]  H. Löhmannsröben,et al.  Interaction of photosensitive surfactant with DNA and poly acrylic acid. , 2014, The Journal of chemical physics.

[20]  R. von Klitzing,et al.  Light‐Controlled Reversible Manipulation of Microgel Particle Size Using Azobenzene‐Containing Surfactant , 2012 .

[21]  A. Ajdari,et al.  Osmotic manipulation of particles for microfluidic applications , 2009 .

[22]  A. Ajdari,et al.  Boosting migration of large particles by solute contrasts. , 2008, Nature materials.

[23]  T. Galstian,et al.  Liquid Crystal Photoalignment using New Photoisomerisable Langmuir-Blodgett Films , 2002 .

[24]  A. Khokhlov,et al.  Collapse of polyelectrolyte networks induced by their interaction with an oppositely charged surfactant. Theory , 1992 .

[25]  John L. Anderson,et al.  Diffusiophoresis caused by gradients of strongly adsorbing solutes , 1991 .

[26]  John L. Anderson,et al.  Colloid Transport by Interfacial Forces , 1989 .