RT Journal Article
T1 Rotating Micro-Spheres for adsorption monitoring at a fluid interface
A1 Martín Roca, José
A1 Jiménez, M.
A1 Ortega, F.
A1 Calero, C.
A1 Valeriani, Chantal
A1 Rubio, R. G.
A1 Martínez Pedrero, F.
AB Hypothesis: A broad range of phenomena, such as emulsification and emulsion stability, foam formation or liquid evaporation, are closely related to the dynamics of adsorbing colloidal particles. Elucidation of the mechanisms implied is key to a correct design of many different types of materials. Experiments: Microspheres forced to rotate near a fluid interface exhibit a roto-translational hydrodynamic mechanism that is hindered by capillary torques as soon as the particles protrude the interface. Under these conditions, the time evolution in the ratio of moving spheres provides a direct description of the adsorption kinetics, while microscopy monitoring of particle acceleration\deceleration informs about the adsorption\desorption dynamics. In this work, the proposed strategy is applied at an air/water interface loaded with spherical magnetic particles negatively charged, forced to rotate by the action of a rotating magnetic field. Findings: The proposed method enables the adsorption/desorption dynamics to be followed during the earliest phase of the process, when desorption of a small fraction of particles is detected, as well as to estimate approximated values of the adsorption/desorption constants. The results obtained show that the addition of a monovalent salt or a cationic (anionic) surfactant promotes (inhibits) both adsorption and formation of permanent bonds between particles. (c) 2022 The Author(s). Published by Elsevier Inc. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).
PB Academic Press Inc Elsevier Science
SN 0021-9797
YR 2022
FD 2022-05-15
LK https://hdl.handle.net/20.500.14352/71500
UL https://hdl.handle.net/20.500.14352/71500
LA eng
NO CRUE-CSIC (Acuerdos Transformativos 2022)We would like to Eduardo Guzmán for fruitful discussions. This work was partially funded by Horizon 2020 program through 766972-FET-OPEN21 NANOPHLOW and Ministerio de Ciencia e Innovación (Grants No. PID2019-105343 GB-I00 and PID2019- 106557 GB-C21). F.M.-P. acknowledges support from MINECO (Grant No. RYC-2015-18495).
NO Unión Europea. Horizonte 2020
NO Ministerio de Ciencia e Innovación (MICINN)
NO Ministerio de Economía y Competitividad (MINECO)
DS Docta Complutense
RD 28 abr 2024