Bursting the Bubble: Membraneless Electrolyzers and High-Surface Oxide Coated Electrodes for Brine Management

Fraga Alvarez, Daniela Valeska

January 2023

High levels of water stress and increased demand for potable water generated via desalination pose significant challenges for sustainable waste brine management in arid regions. Electrochemical techniques, like brine electrolysis, offer an approach for treating brine, preventing environmentally harmful disposal, and facilitating the recycling of valuable ions found in brine. As the large concentration of ions can precipitate and degrade conventional electrolyzer components, membraneless electrolyzers, which lack membranes, can be an alternative for direct brine electrolysis. The absence of membranes enables operation in the presence of impurities and a wide range of pH environments. However, membraneless electrolyzers suffer from a trade-off between current density and current utilization that stems from undesired back-reactions that arise from the crossover of gaseous and aqueous products between the anode and cathode. In this dissertation work, a combination of in situ high-speed video, colorimetric pH imaging, modeling, and electroanalytical methods were used to evaluate how the performance of a porous flow-through cathode is affected by operating current density, electrolyte flow rate, and choice of catalyst placement on a porous support. It was found that catalyst placement is a key knob to control the location of product generation and thereby minimize product crossover and maximize pH differential. Placing the catalyst on the outer surface of the cathode resulted in an average increase of 51% in current utilization, a metric for measuring crossover, compared to the opposite configuration. This finding is explained by the ability of the porous electrode support to serve as a barrier to suppress crossover for the outward-facing catalyst configuration. In addition, the outward-facing catalyst configuration leads to more stable operation while incurring minor increases (90-170 mV) in overpotentials. For both catalyst configurations, it was also shown that the Damköhler number (𝐷𝑎) is a practical descriptor for predicting operating conditions that maximize the concentration of OH⁻ in the cathode effluent stream. Furthermore, this dissertation evaluated the performance of a platinized cathode within a membraneless electrolyzer in the presence of Mg²⁺ impurities. In a 3-hour stability test at 50 mA cm⁻² during brine electrolysis, electrolytes with Mg²+ concentration below 5 mM showed a negligible influence on cathode performance. Electrolytes with Mg²⁺ concentration below 1.2 mM at similar operating conditions exhibited improved cathode performance compared to Mg-free brine. All learnings during this study were captured in a mathematical model that predicts the tolerance threshold at which the cathode would cease to operate due to accumulations of Mg(OH)₂ deposits at different current densities and superficial velocities. Overall, these studies demonstrated the potential of membraneless electrolyzers as an emerging technology for treating brine and converting it into high-value products. Finally, applying an oxide overlayer to planar electrodes has been demonstrated to improve their stability, activity, and/or selectivity. This is relevant for direct brine electrolysis, as brine contains many impurities that can compromise the integrity of electrodes and promote undesirable reactions, generating toxic products like chlorine gas. However, given that high-surface electrodes are required for industrial applications, it is necessary to develop a method to encapsulate high-surface-area electrodes. Applying nanoscopic oxide encapsulation layers to high-surface-area electrodes such as nanoparticle-supported porous electrodes is not an easy task. This dissertation work demonstrated that the recently developed condensed layer deposition (CLD) method can be used for depositing nanoscopic (sub-10 nm thick) titanium oxide (TiO₂) overlayers onto high surface area platinized carbon foam electrodes. Characterization of the overlayers by transmission electron microscopy (TEM) and electron energy loss spectroscopy (EELS) showed they are amorphous, while X-ray photoelectron microscopy confirmed that they exhibit TiO₂ stoichiometry. Electrodes were also characterized by hydrogen underpotential deposition (Hupd) and carbon monoxide (CO) stripping, demonstrating that the Pt electrocatalysts remain electrochemically active after encapsulation. Furthermore, copper underpotential deposition (Cuupd) measurements for bare Pt and TiO₂-encapsulated Pt electrocatalysts revealed that the TiO₂ overlayer effectively prevented Cu₂+ from reaching the buried, allowing this method to determine the coverage of the TiOx coating. In summary, this portion of the dissertation demonstrated that CLD is a promising method for applying nanoscopic overlayers on high-surface electrodes.

Engineering

Water resources development--Management

Saline water conversion

Electrolytic cells

Electrodes, Oxide

Electrodes, Porous

Magnesium

Titanium dioxide

Copper

High-speed video recording

Design and Implementation of a Custom Force Pole Assembly for the Measurement of Primate Locomotor Kinetics

Hosseininejad, Justin

03 September 2013

No description available.

Biomechanics

Electrical Engineering

Engineering

force transducer

Wheatstone bridge

accelerometer

strain gauge

high-speed video camera

data acquisition system

DAQ

primate locomotor kinetics

arboreal stability

biomechanics

Etude de la diversité phénotypique et génotypique des dyskinésies ciliaires primitives : vers une prise en charge personnalisée / Study of the phenotype and genotype diversity in primary ciliary dyskinesia : tomward a personalized care

Blanchon, Sylvain

09 December 2016

Résumé non transmis / Summary not transmitted

Cils

Mouvement ciliaire

Vidéo-Microscopie à haute vitesse

Dyskinésies ciliaires primitives

Correlation phenotype:genotype

Explorations fonctioenlles respiratoires

Cilia

Ciliary motion

High speed video-Microscopy

Primary ciliary dyskinesia

Phenotype:genotype correlation

Lung function tests

610

Increasing temporal, structural, and spectral resolution in images using exemplar-based priors

Holloway, Jason

16 September 2013

In the past decade, camera manufacturers have offered smaller form factors, smaller pixel sizes (leading to higher resolution images), and faster processing chips to increase the performance of consumer cameras. However, these conventional approaches have failed to capitalize on the spatio-temporal redundancy inherent in images, nor have they adequately provided a solution for finding $3$D point correspondences for cameras sampling different bands of the visible spectrum. In this thesis, we pose the following question---given the repetitious nature of image patches, and appropriate camera architectures, can statistical models be used to increase temporal, structural, or spectral resolution? While many techniques have been suggested to tackle individual aspects of this question, the proposed solutions either require prohibitively expensive hardware modifications and/or require overly simplistic assumptions about the geometry of the scene. We propose a two-stage solution to facilitate image reconstruction; 1) design a linear camera system that optically encodes scene information and 2) recover full scene information using prior models learned from statistics of natural images. By leveraging the tendency of small regions to repeat throughout an image or video, we are able to learn prior models from patches pulled from exemplar images. The quality of this approach will be demonstrated for two application domains, using low-speed video cameras for high-speed video acquisition and multi-spectral fusion using an array of cameras. We also investigate a conventional approach for finding 3D correspondence that enables a generalized assorted array of cameras to operate in multiple modalities, including multi-spectral, high dynamic range, and polarization imaging of dynamic scenes.

high speed video

compressive sensing

flutter shutter video camera

FSVC

multi-spectral imaging

multispectral imaging

camera array

3D stereo

cross channel point correspondence

HDR imaging

generalized assorted cameras

GAC

Characterization and Control of an Electrospinning Process

Liu, Kaiyi

18 June 2013

No description available.

Materials Science

Nanotechnology

Polymers

electrospinning

polymer liquid jet

illumination

high speed video

stereo pictures

bending frequency

handedness

coil mergence

Brewster's angle

polarized glint

glint trace

birefringence

multiple jet

Taylor cone

external initiation

jet motion

A Study of Flow Patterns and Surface Wetting in Gas-Oil-Water Flow

Kee, Kok Eng

24 September 2014

No description available.

Fluid Dynamics

Petroleum Engineering

Chemical Engineering

Mechanical Engineering

flow patterns

surface wetting

water wetting

gas-oil-water flow

oil-water flow, three-phase flow

flow loop

conductivity pins

tomography

Experimental Investigations and Theoretical/Empirical Analyses of Forced-Convective Boiling of Confined Impinging Jets and Flows through Annuli and Channels

V.S. Devahdhanush (13119831)

21 July 2022

<p>This study comprises experimental investigations and theoretical/empirical analyses of three forced-convective (pumped) boiling schemes: (i) confined round single jet and jet array impingement boiling, and flow boiling through conventional-sized (ii) concentric circular annuli and (iii) rectangular channels. These schemes could be utilized in the thermal management of various applications including high-heat-flux electronic devices, power devices, electric vehicle charging cables, avionics, future space vehicles, etc.</p>

Turbulent flows

two-phase flows

forced-convective boiling

flow boiling

critical heat flux

jet impingement

confined jets

thermal management

electric vehicles

charging system

design recommendations

two-phase heat transfer coefficient

high-speed-video photography

orientation effects

nucleate boiling degradation

subcooled liquid inlet

saturated liquid-vapor-mixture inlet

Earth gravity

partial heating

Partikelmodellierung der Strukturbildung akustischer Kavitationsblasen in Wechselwirkung mit dem Schalldruckfeld / Particle modeling of acoustic cavitation bubble structure formation and interaction with the acoustic pressure field

Koch, Philipp

29 August 2006

No description available.

530 Physik

Mathematics and Computer Science

akustische Kavitation

Strukturbildung

akustische Lichtenbergfigur

nichtlineare radiale Blasendynamik

Keller-Miksis-Modell

Oberflächenstabilität

Gasdiffusion

Partikelmodellierung

primäre und sekundäre Bjerkneskraft

Reibungskraft

virtuelle Masse

Ultraschallfeld

Helmholtz-Gleichung

stehende Schallfeldmode

Resonanzverschiebung

Blasen-Flüssigkeits-Gemisch

van Wijngaarden-Wellengleichung

Einzelblase

Vielblasensysteme

Hochgeschwindigkeitsaufnahme

acoustic cavitation

structure formation

acoustic Lichtenberg figur

nonlinear radial bubble oscillation

Keller-Miksis model

surface stability

gas diffusion

particel modeling

primary and sekundary Bjerknes force

drag force

added mass

ultrasonic field

Helmholtz equation

standing wave field

resonance shift

bubble liquid mixture

van Wijngaarden wave equation

single bubble

multi bubble systems

high-speed video observations

33.12

30.20

RHK 000: Ultraschall {Physik: Akustik}

RHH 150: Schallausbreitung

-reflexion

in Flüssigkeiten {Physik: Akustik}