Redox-active materials hold great promise as platforms for selective liquid-phase
separations. In contrast to capacitive electrodes that rely purely on double-layer charge for …

Redox species have been explored extensively for catalysis, energy storage, and molecular
recognition. It is shown that nanostructured pseudocapacitive electrodes functionalized with …

Adsorption at charged interfaces plays an important role across all aspects of physical
chemistry, from biological interactions within living organisms to chemical processes such as …

The molecular design of polymer interfaces has been key for advancing electrochemical
separation processes. Precise control of molecular interactions at electrochemical interfaces …

The design of molecularly selective interfaces can lead to efficient electrochemically-
mediated separation processes. The fast growing development of electroactive materials …

Electrochemically mediated redox‐active processes are gaining momentum as a promising
liquid‐phase separation technology. Compared to conventional systems, they offer potential …

Electrochemically mediated adsorption is an emerging technology that utilizes redox active
(or Faradaic) materials and has exhibited high salt adsorption capacity and superb ion …

We report the development of a dual-electrode pseudocapacitive separation technology
(PSST) to capture quantitatively, remotely, and in a reversible manner value-added …

Ion-selective electrochemical systems are promising for liquid phase separations,
particularly for water purification and environmental remediation, as well as in chemical …

Advanced redox‐polymer materials offer a powerful platform for integrating
electroseparations and electrocatalysis, especially for water purification and environmental …