%AHauke, Adam [Novel Devices Laboratory School of Electronics and Computing Systems University of Cincinnati Cincinnati, Ohio 45221 USA]%AHauke, Adam [Novel Devices Laboratory, School of Electronics and Computing Systems, University of Cincinnati, Cincinnati, Ohio 45221 USA]%AEhrlich, Said [ALine, Inc., Accelerated Microfluidic Development, Rancho Dominguez, California 90220 USA]%AEhrlich, Said [ALine, Inc., Accelerated Microfluidic Development Rancho Dominguez, California 90220 USA]%ALevine, Leanna [ALine, Inc., Accelerated Microfluidic Development Rancho Dominguez, California 90220 USA]%ALevine, Leanna [ALine, Inc., Accelerated Microfluidic Development, Rancho Dominguez, California 90220 USA]%AHeikenfeld, Jason [Novel Devices Laboratory School of Electronics and Computing Systems University of Cincinnati Cincinnati, Ohio 45221 USA]%AHeikenfeld, Jason [Novel Devices Laboratory, School of Electronics and Computing Systems, University of Cincinnati, Cincinnati, Ohio 45221 USA]%BJournal Name: Electroanalysis; Journal Volume: 31; Journal Issue: 1; Related Information: CHORUS Timestamp: 2023-09-14 15:11:56 %D2018%IWiley Blackwell (John Wiley & Sons) %JJournal Name: Electroanalysis; Journal Volume: 31; Journal Issue: 1; Related Information: CHORUS Timestamp: 2023-09-14 15:11:56 %K %MOSTI ID: 10079428 %PMedium: X %TAn Improved Design and Versatile New Lamination Fabrication Method for Twin Electrode Thin Layer Cells Utilizing Track‐etch Membranes %XAbstract

Reported here are laminated membrane electrodes, an improved design and more advantageous method of fabrication for previously reported thin layer cell electrode systems developed on track‐etch membranes. The laminated membrane approach potentially further improves flow resistance by dramatically reducing the surface area to volume ratio, but also produces a cohesive device that can be more readily applied to a broad range of applications. In addition, this new fabrication method was implemented in a scalable, commercial process and resulting product demonstrations indicate that volume manufacturing is feasible. Characterization of laminated membrane electrodes reveal redox cycling amplification factors as high as 30 with linear responses to variable concentrations of redox couple. These performance characteristics are shown to be comparable to similar generator‐collector systems fabricated through much more laborious laboratory methods. This combination of added versatility, cost‐reduced fabrication and exceptional performance clearly reveals unrealized potential of track‐etch membrane approaches and boosts their candidacy as powerful new options for generator‐collector electrode systems.

%0Journal Article