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1. Concentration Profiles in a Cylindrical Cell under Electrophoretic and Electroosmotic Forces

   Walsh, Gavlin I; Eperjesi, Sean P; Oyanader, Mario A (November 2025, American Institute of Chemical Engineers (AIChE))

   Due to rising concerns with environmental issues, electroosmosis and electrokinetic techniques are currently being explored in various applications within the field of environmental engineering. Current techniques include desalination and the remediation of soil due to the necessity of non-polluted soil and safe water. Mathematical modeling approaches to electroosmosis and electrokinetic techniques have been proven to be effective; unfortunately, existing models are often specialized to a specific set of circumstances and lack flexibility for other situations (e.g., drug delivery and biomedical engineering). This work introduces a generalized mathematical model for describing the concentration gradient of a molar species within a cylindrical channel undergoing electroosmotic and electrokinetic influence. The model couples electrostatic potential in a cylindrical channel with the velocity profile to obtain concentration predictions. Core to the formulation are established fluid mechanics equations, including the Poisson–Boltzmann equation, the Navier–Stokes equation, and the molar species continuity equation, with parameters such as diffusivity, susceptibility, and electrostatic potential treated as variables. A distinct aspect of this study is its use of area-averaging techniques to resolve the molar continuity equation. The study provides analysis of the cylindrical model and highlights patterns under standard parameters (e.g., higher susceptibility yields a more uniform concentration gradient from the wall to the channel center), with further research directions discussed. 

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2. Impact and Role of Temperature on Electrostatic Potentials and Velocity Profiles Prediction

   Thibault, Ruth A; Oyanader, Mario A (November 2025, American Institute of Chemical Engineers (AIChE))

   Electrostatic potential profiles are vital for understanding and controlling electroosmosis as well as particle mixing. The shape and magnitude of this profile—particularly a key parameter called the zeta potential (ζ)—directly dictate the speed and direction of fluid flow when an electric field is applied. The role of temperature in modifying this important parameter has not been analyzed from a mathematical approach, and it is relevant for improving the design of microfluidic devices and technologies involving capillary electrophoresis for non-isothermal systems. In this study, two electrophoretic cell geometries are investigated under non-isothermal conditions. A heat-transport model (with heat generation and Dirichlet boundary conditions) is coupled into the Poisson–Boltzmann equation to obtain zeta potential profiles for different temperature distributions. In addition, the Navier–Stokes equation for the electroosmotic case is solved to obtain velocity profiles, including examples of flow reversal under temperature development. Numerical analysis for rectangular and cylindrical geometries indicates that large temperature gradients produce significant zeta-potential changes and can induce multiple flow reversals; effects are more pronounced at high Joule-heating values, while small temperature differences yield approximately linear electrostatic potential behavior and typical laminar profiles. 

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3. Concentration Profiles in a Cylindrical Cell under Electrophoretic and Electroosmotic Forces — PAR ID 10662905 Area Averaging Analysis of Electroosmosis and Electro migration in a Rectangular Cell — PAR ID 10662906 Analytical Solution of the Effects of Applied Electrical Field to Drug Delivery in Electrochemotherapy — PAR ID 10662907 Impact and Role of Temperature on Electrostatic Potentials and Velocity Profiles Prediction — PAR ID 10662908 AIChE (Ricky Rivero; Oyanader, Mario — this looks like the title field may have saved incorrectly) — PAR ID 10662909 Combining Research, Teaching, and Mentorship in STEM Bridge Programs: The 3 Pasos Undergrad Student Experience — PAR ID 10662910

   Rivero, Ricky J; Oyanader, Mario A (November 2025, American Institute of Chemical Engineers (AIChE))

   This study explores how electroosmosis and buoyancy forces affect flow regimes in electrokinetic systems within rectangular capillaries and how these regimes shape concentration profiles under varying temperature and non-symmetric conditions caused by uneven wall convection. The advective impact of Joule heating and convection on solute migration is investigated, with emphasis on determining which force dominates and how non-symmetric environments influence flow regimes and dispersion—key considerations for designing efficient electrokinetic devices and effective soil-remediation protocols. Using generalized (Robin-type) boundary conditions, the study introduces a skewness parameter 𝑅2 to help predict flow reversal behavior and mixing issues based on system parameters. The analysis applies heat-transfer modeling, solves the Navier–Stokes equation for buoyancy-driven cases limited by 𝑅2, and solves the molar species continuity equation to obtain concentration profiles across scenarios of 𝑅2 values and Joule heating. The area-averaging method is used for the advective case and limiting scenarios (including insulation and uneven environments) are reported, along with reverse-flow conditions and their mixing impact on concentration profiles. 

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4. Modulation of electrophoresis, electroosmosis and diffusion for electrical transport of proteins through a solid-state nanopore

   https://doi.org/10.1039/D1RA03903B  

   Saharia, Jugal; Bandara, Y. M.; Karawdeniya, Buddini I.; Hammond, Cassandra; Alexandrakis, George; Kim, Min Jun (July 2021, RSC Advances)

   null (Ed.)

   Nanopore probing of molecular level transport of proteins is strongly influenced by electrolyte type, concentration, and solution pH. As a result, electrolyte chemistry and applied voltage are critical for protein transport and impact, for example, capture rate ( C R ), transport mechanism ( i.e. , electrophoresis, electroosmosis or diffusion), and 3D conformation ( e.g. , chaotropic vs. kosmotropic effects). In this study, we explored these using 0.5–4 M LiCl and KCl electrolytes with holo-human serum transferrin (hSTf) protein as the model protein in both low (±50 mV) and high (±400 mV) electric field regimes. Unlike in KCl, where events were purely electrophoretic, the transport in LiCl transitioned from electrophoretic to electroosmotic with decreasing salt concentration while intermediate concentrations ( i.e. , 2 M and 2.5 M) were influenced by diffusion. Segregating diffusion-limited capture rate ( R diff ) into electrophoretic ( R diff,EP ) and electroosmotic ( R diff,EO ) components provided an approach to calculate the zeta-potential of hSTf ( ζ hSTf ) with the aid of C R and zeta potential of the nanopore surface ( ζ pore ) with ( ζ pore – ζ hSTf ) governing the transport mechanism. Scrutinization of the conventional excluded volume model revealed its shortcomings in capturing surface contributions and a new model was then developed to fit the translocation characteristics of proteins. 

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5. A Pore-Scale Model for Electrokinetic In situ Recovery of Copper: The Influence of Mineral Occurrence, Zeta Potential, and Electric Potential

   https://doi.org/10.1007/s11242-023-02023-2  

   Tang, Kunning; Li, Zhe; Da Wang, Ying; McClure, James; Su, Hongli; Mostaghimi, Peyman; Armstrong, Ryan T (December 2023, Transport in Porous Media)

   AbstractElectrokinetic in-situ recovery is an alternative to conventional mining, relying on the application of an electric potential to enhance the subsurface flow of ions. Understanding the pore-scale flow and ion transport under electric potential is essential for petrophysical properties estimation and flow behavior characterization. The governing physics of electrokinetic transport is electromigration and electroosmotic flow, which depend on the electric potential gradient, mineral occurrence, domain morphology (tortuosity and porosity, grain size and distribution, etc.), and electrolyte properties (local pH distribution and lixiviant type and concentration, etc.). Herein, mineral occurrence and its associated zeta potential are investigated for EK transport. The new Ek model which is designed to solve the EK flow in complex porous media in a highly parallelizable manner includes three coupled equations: (1) Poisson equation, (2) Nernst–Planck equation, and (3) Navier–Stokes equation. These equations were solved using the lattice Boltzmann method within X-ray computed microtomography images. The proposed model is validated against COMSOL multiphysics in a two-dimensional microchannel in terms of fluid flow behavior when the electrical double layer is both resolvable and unresolvable. A more complex chalcopyrite-silica system is then obtained by micro-CT scanning to evaluate the model performance. The effects of mineral occurrence, zeta potential, and electric potential on the three-dimensional chalcopyrite-silica system were evaluated. Although the positive zeta potential of chalcopyrite can induce a flow of ferric ion counter to the direction of electromigration, the net effect is dependent on the occurrence of chalcopyrite. However, the ion flux induced by electromigration was the dominant transport mechanism, whereas advection induced by electroosmosis made a lower contribution. Overall, a pore-scale EK model is proposed for direct simulation on pore-scale images. The proposed model can be coupled with other geochemical models for full physicochemical transport simulations. Meanwhile, electrokinetic transport shows promise as a human-controllable technique because the electromigration of ions and the applied electric potential can be easily controlled externally. Graphical abstract 

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