Anode Chamber Research Articles

Starch – carrageenan based low-cost membrane permeability characteristic and its application for yeast microbial fuel cells

Microbial fuel cells (MFCs) are an innovative method that generates sustainable electricity by exploiting the metabolic processes of microorganisms. The membrane that divides the anode and cathode chambers is an important component of MFCs. Commercially available membranes, such as Nafion, are both costly, not sustainable, and harmful to the environment. In this study, a low-cost alternative membrane for MFCs based on a starch-carrageenan blend (SCB-LCM) was synthesized. The SCB-LCM membrane was created by combining starch and carrageenan and demonstrated a high dehydration rate of 98.87 % over six hours. SEM analysis revealed a smooth surface morphology with no pores on the membrane surface. The performance of SCB-LCM membrane-based MFCs was evaluated and compared to that of other membranes, including Nafion 117 and Nafion 212. All membranes tested over 25 hours lost significant weight, with SCB-LCM losing the least. The maximum power density (MPD) of the SCB-LCM MFCs was 15.77 ± 4.34 mW/m2, indicating comparable performance to commercial membranes. Moreover, the cost-to-power ratio for MFCs employing SCB-LCM was the lowest (0.03 USD.m2/mW) when compared to other membranes, indicating that SCB-LCM might be a viable and cost-effective alternative to Nafion in MFCs. These SCB-LCM findings lay the groundwork for future research into low-cost and sustainable membrane for MFC technologies.

A novel multifunctional cell coupled by electrodialysis and electrocatalysis for seawater desalination, wastewater decontamination and H2O2 production

There is an increasing demand for wastewater decontamination and seawater desalination in coastal areas due to severe water crisis and environmental pollution. Herein, a versatile process coupled by electrocatalysis and electrodialysis was established to achieve wastewater decontamination, seawater desalination and H2O2 production. The coupled process not only realized about 70% desalination of seawater, 90% removal of 200 mg/L ampicillin (AMP) and 3.2 g/L H2O2 production at 4 V, but also showed the ability to effectively remove various contaminants including rhodamine B, urea, nitrobenzene and quinoline. The coupled process represented a great processing capacity for 100–300 mg/L AMP and seawater with 15–45 g/L NaCl. The mechanism exploration indicated the electrodialysis and electrocatalysis worked synergistically. The electrodialysis could generate an internal potential of 0.5 V to promote the electrocatalysis, and provide Cl− and Na+ as the electrolytes for electrocatalysis. Furthermore, the chlorine evolution reaction through electrocatalysis improved efficiency of electron transfer, resulting in a higher AMP removal and H2O2 production. Radical scavenging experiments and chemical analysis indicated that •OH and reactive chlorine species (RCS) accounted for 70% and 30% for AMP removal in anode chamber. Increasing reactants (H+ and O2) could significantly improve H2O2 production in cathode chamber. The coupled process also exhibited satisfactory effectiveness to real wastewater/seawater with 100% removal of AMP and 75% desalination of seawater, accompanying with 6 g/L H2O2 production. This study provides a promising multifunctional water treatment strategy for decontamination, desalination and simultaneous production of H2O2.

Assessment of the change in the pH of water in a flow electric activator

AbstractSoil pH is important for favourable plant growth. The water used for irrigation must have an optimal pH value. Such water can be prepared by passing it through a flow electric activator. An experimental setup with a flow electric activator was created to control the pH value of the activated water. A mathematical model was developed to establish the relationship between the activated water pH value and the power supply voltage and the performance of the anode and cathode chambers. The pH value of activated water varies in direct proportion to the power supply voltage and is inversely proportional to the performance of the set chambers. The pH value of activated water can be adjusted by two parameters: the voltage of the power source and the water supply.

Электролизные растворы в санитарной обработке: прошлое и настоящее

New knowledge about biofilm microorganisms and their resistance needs new approaches to disinfection. The article traces the story of electrolysis, as well as inorganic chloractive and oxygen-active disinfectants. It describes the basic electrolysis scheme for obtaining salines and electrochemically activated substances. As a rule, their properties determine the target efficiency of the disinfectant. Certain electrochemical processes occur in anodic and cathodic chambers during electrolysis. They are associated with redox reactions of strongly adsorbed electroactive intermediate molecular forms obtained from water. They depend on the concentration of electrolyte in the solution, current power, electrolysis time, temperature, etc. The electrolytic method has good industrial prospects as it simultaneously produces chloractive anolyte solutions and alkaline catholyte solutions. They can be used as a complex for equipment sanitization purposes.

Enhanced ammonia recovery from wastewater by a transmembrane electro-chemisorption system directly connecting anode chamber and cathode chamber with gas permeable membrane

A transmembrane electro-chemisorption (TMECS) system was developed via directly connecting anode chamber (AnC) and cathode chamber (CaC) with a hydrophobic gas permeable membrane (GPM). The special structure of the TMECS system with AnC and CaC at two sides of GPM contributed to both forming localized extreme pH layers at two sides of GPM and using electrical field forces to enrich NH4+, thus realizing on-site utilization of authigenic acid and base to enhance the ammonia recovery from wastewater. Increasing applied voltage (from 2.0 to 6.0 V) and salt concentration (from 80 to 500 mM) could improve the system performance by promoting water splitting and reducing internal resistance, respectively. The system showed wide applicability for the influent ammonia concentration (from 560 to 5000 mg NH4+-N/L) with the ammonia removal and recovery efficiencies of 61.9 %–77.1 % and 78.5 %–91.9 % at 24 h, respectively. For high influent ammonia concentration (5000 mg NH4+-N/L), a specific energy consumption of 21.8 kWh/kg N could be reached. Moreover, the system can be easily scaled up by stacking the TMECS units. Therefore, the system shows good prospects in saving chemicals, wide applicability and easy scale-up for ammonia recovery from wastewater.

Development of a Microwave Sensor for Real-Time Monitoring of a Micro Direct Methanol Fuel Cell

Micro direct methanol fuel cells (μDMFCs) are a promising power source for microelectronic devices and systems. As the operating state and performance of a μDMFC is generally determined by both electrochemical polarization and methanol crossover, it is important to monitor the methanol concentration in μDMFCs. Here, we design and fabricate a microwave sensor and integrate it with a μDMFC for the online detection of methanol concentration in a nonintrusive way. The sensing area is set at the bottom of the anode chamber of a μDMFC which exhibits a maximum output power density of 28.8 mW cm−2 at 30 °C. With a square ring structure, the dual-mode microwave sensor shows a sensitivity of 9.5 MHz mol−1 L. Furthermore, the importance of methanol concentration monitoring is demonstrated in the long term. A relatively smooth methanol decline curve was obtained, which indicated a normal and stable operating status of the μDMFC. Derived from real-time recording data, fuel utilization was additionally calculated as 28.5%.

Electrochemiluminescence Analysis of Multiple Glycans on Single Living Cell with a Closed Bipolar Electrode Array Chip.

The profiling of multiple glycans on a single cell is important for elucidating glycosylation mechanisms and accurately identifying disease states. Herein, we developed a closed bipolar electrode (BPE) array chip for live single-cell trapping and in situ galactose and sialic acid detection with the electrochemiluminescence (ECL) method. Methylene blue-DNA (MB-DNA) as well as biotin-DNA (Bio-DNA) codecorated AuNPs were prepared as nanoprobes, which were selectively labeled on the cell surface through chemoselective labeling techniques. The individual cell was captured and labeled in the microtrap of the cathodic chamber, under an appropriate potential, MB molecules on the cellular membrane underwent oxidation, triggering the reduction of [Ru(bpy)3]2+/TPA and consequently generating ECL signals in the anodic chamber. The abundance of MB groups on the single cell enabled selective monitoring of both sialic acid and galactosyl groups with high sensitivity using ECL. The sialic acid and galactosyl content per HepG2 cell were detected to be 0.66 and 0.82 fmol, respectively. Through comprehensive evaluation of these two types of glycans on a single cell, tumor cells, and normal cells could be effectively discriminated and the accuracy of single-cell heterogeneous analysis was improved. Additionally, dynamic monitoring of variations in galactosyl groups on the surface of the single cell was also achieved. This work introduced a straightforward and convenient approach for heterogeneity analysis among single cells.

Energy Production in Microbial Fuel Cells (MFCs) during the Biological Treatment of Wastewater from Soilless Plant Cultivation

The management of drainage water (DW), which is produced during the soilless cultivation of plants, requires a high energy input. At the same time, DW is characterized by a high electrolytic conductivity, a high redox potential, and is also stable and putrefaction-free. In the present study, the natural properties of drainage water and a biotreatment method employing an external organic substrate in the form of citric acid (C/N 1.0, 1.5, 2.0) were utilized for energy recovery by a microbial fuel cell (MFC). The cathode chamber served as a retention tank for DW with a carbon felt electrode fixed inside. In turn, a biological reactor with biomass attached to the filling in the form of carbon felt served as the anode chamber. The filling also played the role of an electrode. The chambers were combined by an ion exchange membrane, forming an H letter-shaped system. They were then connected in an external electrical circuit with a resistance of 1k Ω. The use of a flow-through system eliminated steps involving aeration and mixing of the chambers’ contents. Citric acid was found to be an efficient organic substrate. The voltage of the electric current increased from 44.34 ± 60.92 mV to 566.06 ± 2.47 mV for the organic substrate dose expressed by the C/N ratio ranging from 1.0 to 2.0. At the same time, the denitrification efficiency ranged from 51.47 ± 9.84 to 95.60 ± 1.99% and that of dephosphatation from 88.97 ± 2.41 to 90.48 ± 1.99% at C/N from 1.0 to 2.0. The conducted studies confirmed the possibility of recovering energy during the biological purification of drainage water in a biofilm reactor. The adopted solution only required the connection of electrodes and tanks with an ion-selective membrane. Further research should aim to biologically treat DW followed by identification of the feasibility of energy recovery by means of MFC.

Removal of Monovalent and Divalent Cations from Brine Water by Electrodialysis Using Modified Polyethersulfone Membranes

In electrodialysis, an ion exchange membrane removes unwanted ions from wastewater and toxic metal ions from effluents. Montmorillonite-based modified "polyethersulfone membranes" have been studied as a potential small-scale electrodialysis approach for removing ions from wastewater. The study featured several steps, including solid polymerization, electrolyte balance, and removal of each component from the water. The study used three distinct “cation-exchange membranes (CEM)" types. The selected water body was diluted 100 times before being added to the electrodialysis cell in amounts of the center, cathodic, and anodic chambers, each containing 55, 30, and 40 mL. The initial pH for the real solutions of the water body was 7.16 at 25°C. Compared to "Sulfonated poly arylene ether sulfone (S-PESOS)" (23.23%) and Nafion® (35.34%), "hexamethylenediamine (HEXCl)" stands out as the only cross-linked material with significantly high-water content. When the membrane water content is too high, the membrane may lose its mechanical strength and cannot provide enough ionic conductivity. The semi-empirical model's parameters were estimated to simulate the elimination of Na+, K+, Ca2+, and Mg2+ by three membranes. HEXCl and S-PESOS were electrodialyzed and used to treat the serial dilution from the water with cationics. The removal rate gradually rose after the electrodialysis started.

Generation of Bioelectricity in Microbial Fuel Cell using Kitchen Waste Obtained from Dutse Urban, Nigeria

Microbial fuel cells (MFCs) have shown promise as a sustainable technology for wastewater treatment and energy recovery. In this study, cattle dung was used as an inoculum and kitchen waste (KW) from Dutse urban, Nigeria was used as a substrate for bioelectricity generation in MFC. The MFC was operated in a fed-batch mode over 37 days, spanning three cycles. During characterization, the chemical oxygen demand (COD) of the KW was found to be 30421 ± 124 mg/L, indicating a high concentration of organic pollutants. The MFC's performance was evaluated based on the voltage generated, with the first cycle reaching a peak of 254 mV, the second cycle 247 mV, and the third cycle 242 mV. Current and power densities during the three cycles decreased gradually from 66.84 mA/m² and 16.84 mW/m² in the first cycle to 63.68 mA/m² and 15.41 mW/m² in the third cycle respectively. Furthermore, there was a notable reduction in COD from the influent diluted from initial measured COD, from 1120 ± 63 mg/L to an effluent level of 226 ± 49 mg/L, indicating approximately 80% removal rate. The pH of the anolyte progressively dropped with each cycle, reflecting the metabolic activities of bacteria in the anode chamber. The findings underscore MFC's potential for organic waste management and electricity generation, with results outperforming some contemporary studies.

An energy efficient hybrid membrane technique for the removal of toxic metals from aquatic environment

Electrodeionization (EDI), integrates electrodialysis (ED) and ion exchange (IE) technology. The purpose of this study is to utilize an EDI unit for eliminating copper from wastewater. This process was demonstrated using a three-compartment system, comprising a central compartment filled with a cation exchange resin (CER), separated from the anodic and cathodic chambers by two cationic exchange membranes (CEM), with the anode and cathode placed in the anodic and cathodic chambers, respectively. Purolite C 160 was used to showcase how operational variables, such as initial concentration, contact duration, resin dosage, and temperature, were optimized for the most effective copper removal during batch mode operation. The optimized conditions were an initial concentration of 100 ppm, a Purolite C dose of 0.5 g/L, a contact time of 1 h, and a pH of 8. At an initial copper concentration of 100 ppm and a supply voltage in the range of 10 to 25 V, the highest copper removal achieved was close to 99.98 per cent. For this study, copper was eliminated in the described experiments up to 99.98%, with energy consumption in the EDI unit varying between 3.87 and 25.29 kWh per kg of removed copper.

Bioelectrocatalytic reduction by integrating pyrite assisted manganese cobalt-doped carbon nanofiber anode and bacteria for sustainable antimony catalytic removal

A novel manganese cobalt metal–organic framework based carbon nanofiber electrode (MnCo/CNF) was prepared and used as microbial fuel cell (MFC) anode. Pyrite was introduced into the anode chamber (MnCoPy_MFC). Synergistic function between pyrite and MnCo/CNF facilitated the pollutants removal and energy generation in MnCoPy_MFC. MnCoPy_MFC showed the highest chemical oxygen demand removal efficiency (82 ± 1%) and the highest coulombic efficiency (35 ± 1%). MnCoPy_MFC achieved both efficient electricity generation (maximum voltage: 658 mV; maximum power density: 3.2 W/m3) and total antimony (Sb) removal efficiency (99%). The application of MnCo/CNF significantly enhanced the biocatalytic efficiency of MnCoPy_MFC, attributed to its large surface area and abundant porous structure that provided ample attachment sites for electroactive microorganisms. This study revealed the synergistic interaction between pyrite and MnCo/CNF anode, which provided a new strategy for the application of composite anode MFC in heavy metal removal and energy recovery.

Treatment of metronidazole pharmaceutical wastewater using pulsed switching peroxi-coagulation combined with electro-Fenton process

The aim of this study was to investigate the metronidazole (MNZ) degradation and real MNZ pharmaceutical wastewater treatment in the pulsed switching peroxi-coagulation (PSPC) process. Different pulsed switching frequencies and running times of H2O2 and Fe2+ productions were tested in the PSPC process. Results demonstrated that MNZ removal of 96.9 ± 1.2 % was realized in the PSPC process with a 200 mg/L MNZ and 0.1 M Na2SO4 solution within 80 min under a pulsed switching frequency of 6s: 1s and a current density of 20 mA/cm2 (H2O2) and 20 mA/cm2 (Fe2+). High MNZ removal could be attributed to efficient •OH production with the highest •OH concentration reached 321 ± 15 μM in the PSPC process. The hydroxyl and carboxyl groups of MNZ were sequentially oxidated by •OH and mineralized based on seven identified intermediates during the MNZ degradation. However, only 56.9 ± 6.7 % of COD was removed in the real MNZ wastewater treatment by the PSPC process within 90 min. A PSPC combined with electro-Fenton (EF) process was developed to enhance the COD removal in the MNZ wastewater. With MNZ wastewater as electrolytes, 3.3 ± 0.3 g/L of H2O2 was produced in a conventional EF reactor. The final COD removal reached 86–90 % using the mixture of effluent from the PSPC, the anode, and cathode chambers of the EF reactor, resulting in less than 80 mg/L COD in the effluent. Results from this study should provide a useful way to enhance real MNZ pharmaceutical wastewater treatment.

An Efficient Bias‐Free Si Photocathode Coupled BiVO4‐Triethanolamine Photoelectrochemical Fuel Cell for Simultaneous Pollutant Treatment and Hydrogen Production

AbstractPhotoelectrochemical (PEC) fuel cells that enable organic pollutants degradation while generating H2 are regarded as a viable approach in addressing global energy and environmental issues. Herein, an efficient PEC fuel cell is constructed using oxygen vacancy‐rich BiVO4 (OV:BiVO4) as the photoanode and triethanolamine (TEOA) pollutant as the fuel. Under AM 1.5 G, this OV:BiVO4–TEOA PEC fuel cell shows an ultra‐high photo‐driven current density of 20.40 mA cm−2 at 1.23 V versus reversible hydrogen electrode, which is superior to most reported PEC fuel cells. The Faradic efficiency of H2 production is about 97.26%, and no CO2 is released in the anode chamber due to the strong CO2 adsorption by excess TEOA. Further integration of a Pt/C cocatalyst coated Si photocathode in the OV:BiVO4–TEOA PEC fuel cell can achieve bias‐free H2 production with a current density of 10.17 mA cm−2. The experimental and theoretical calculation results reveal the importance of the robust complexation between the OV:BiVO4 photoanode and TEOA, which ensures thorough conversion of chemical energy in TEOA and high activity of the PEC fuel cell. This work will guide the design of efficient PEC fuel cells for simultaneous pollutant treatment and H2 production.

The effect of ammonia concentration on the treatment of bio electrochemical leachate using MFCs technology.

Microbial fuel cells (MFCs) have garnered attention in bio-electrochemical leachate treatment systems. The most common forms of inorganic ammonia nitrogen are ammonium ([Formula: see text]) and free ammonia. Anaerobic digestion can be inhibited in both direct (changes in environmental conditions, such as fluctuations in temperature or pH, can indirectly hinder microbial activity and the efficiency of the digestion process) and indirect (inadequate nutrient levels, or other conditions that indirectly compromise the microbial community's ability to carry out anaerobic digestion effectively) ways by both kinds. The performance of a double-chamber MFC system-composed of an anodic chamber, a cathode chamber with fixed biofilm carriers (carbon felt material), and a Nafion 117 exchange membrane is examined in this work to determine the impact of ammonium nitrogen ([Formula: see text]) inhibition. MFCs may hold up to 100mL of fluid. Therefore, the bacteria involved were analysed using 16S rRNA. At room temperature, with a concentration of 800mg L-1 of ammonium nitrogen and 13,225mg L-1 of chemical oxygen demand (COD), the study produced a considerable power density of 234 mWm-3. It was found that [Formula: see text] concentrations above 800mg L-1 have an inhibitory influence on power output and treatment effectiveness. Multiple routes removed the most nitrogen ([Formula: see text]-N: 87.11 ± 0.7%, NO2 -N: 93.17 ± 0.2% and TN: 75.24 ± 0.3%). Results from sequencing indicate that the anode is home to a rich microbial community, with anammox (6%), denitrifying (6.4%), and electrogenic bacteria (18.2%) making up the bulk of the population. Microbial fuel cells can efficiently and cost-effectively execute anammox, a green nitrogen removal process, in landfill leachate.

Reducing Chloride Ion Permeation during Seawater Electrolysis Using Double-Polyamide Thin-Film Composite Membranes.

Low-cost polyamide thin-film composite membranes are being explored as alternatives to expensive cation exchange membranes for seawater electrolysis. However, transport of chloride from seawater to the anode chamber must be reduced to minimize the production of chlorine gas. A double-polyamide composite structure was created that reduced the level of chloride transport. Adding five polyamide layers on the back of a conventional polyamide composite membrane reduced the chloride ion transport by 53% and did not increase the applied voltage. Decreased chloride permeation was attributed to enhanced electrostatic and steric repulsion created by the new polyamide layers. Charge was balanced through increased sodium ion transport (52%) from the anolyte to the catholyte rather than through a change in the transport of protons and hydroxides. As a result, the Nernstian loss arising from the pH difference between the anolyte and catholyte remained relatively constant during electrolysis despite membrane modifications. This lack of a change in pH showed that transport of protons and hydroxides during electrolysis was independent of salt ion transport. Therefore, only sodium ion transport could compensate for the reduction of chloride flux to maintain the set current. Overall, these results prove the feasibility of using a double-polyamide structure to control chloride permeation during seawater electrolysis without sacrificing energy consumption.

Resource-efficient nitrogen and salinity removal in a synergistic partial nitritation-anammox bioelectrochemical system

We investigated the performance of a two-stage partial-nitritation-anammox biocathode integrated microbial desalination cell (TNiAmoxMDC) for concurrent nitrogen removal, desalination, and bioelectricity generation at different aeration rates in the nitritation chamber. The TNiAmoxMDC system achieved a maximum total nitrogen removal rate of 50.4 ± 8.2 g-TN/m3/d with 300 mW/m2 of maximum power production utilizing 500 mg/L of glucose chemical oxygen demand (COD) in the anode. The organic removal in the anode chamber showed a good fit to first order reaction model with a rate constant of 0.036 h−1. The biocatalytic activity of anammox bacteria in the biocathode produced a current density of 0.7 A/m2 in the absence of oxygen. More than 98% of the salinity was removed at a rate of 1.48 mg/h. The energy consumption values for nitrogen removal at aeration rates of 0.7, 2.2, and 10 ml/min were 0.022, 0.55, and 0.20 kWh/kg-N, respectively. The maximum energy produced by the TNiAmoxMDC was 0.0157 kWh/m3. Excluding the energy consumption by the system, the net energy recovery was 0.0023 kWh/m3 at an airflow rate of 10 ml/min. Thus, the integration of the partial nitritation-anammox process with microbial desalination cell (MDC) provides energy-and resource-efficient synergy for bioelectrochemical wastewater treatment.

Recovery of Bio-Based Fumaric Acid By Electrochemically Induced pH Shift Crystallization

The heterotrophic microbial production of platform chemicals is gaining increasing interest due to the growing need to replace fossil resources by renewable alternatives. Carboxylic acids such as fumaric acid are important building blocks for high-value bio-based chemicals [1]. Fumaric acid is used as an acidulant, as an antibacterial agent, and as a precursor for polymers and pharmaceuticals [2,3].A major challenge commercializing the microbial production route is the recovery and the purification of fumaric acid after fermentation. Bio-production of fumaric acid has not yet reached industrial scale due to high additive consumption during the acid- and base-induced pH shift in the downstream process. The inevitable co-production of saline waste deteriorates process economics further and raises ecological concerns.Therefore, we propose a new electrochemical downstream process, which reduces the use of pH adjustment agents [4]. This downstream process incorporates an electrolysis cell to adjust the pH value. During electrolysis, protons are produced at the anode and hydroxide ions are produced at the cathode by the electrochemical splitting of water. In conventional water electrolysis, protons or hydroxide ions migrate through a membrane to balance the charge in the electrolysis cell. Consequently, the pH value is constant in the electrolysis cell chambers. In pH shift electrolysis, a salt is added to the electrolyte. The salt provides additional ions to maintain electroneutrality in both electrolysis cell chambers. In this way, protons and hydroxide ions are retained in their respective chambers of the electrolysis cell and a pH difference is created between the anode and cathode. During acidification in the anode chamber, the fumaric acid salt from the fermentation is protonated. Subsequently, fumaric acid crystallizes in the electrolysis cell in high yields due to its low solubility. Afterwards, fumaric acid crystals can be easily separated from fermentation broth. Simultaneously, a base is produced at the cathode, which can be used to maintain a neutral pH in the fermentation. Consequently, saline waste production and its drawbacks are avoided.This work presents the pH shift with an electrolysis cell and the simultaneous crystallization of fumaric acid in the anode chamber. Next, the process is analyzed using on-line and off-line analytics such as Raman spectroscopy and high-performance liquid chromatography.[1] Bozell, J. J., & Petersen, G. R. (2010). Technology development for the production of biobased products from biorefinery carbohydrates - The US Department of Energy’s “Top 10” revisited. Green Chem, 12(4), 525-728. DOI: 10.1039/B922014C[2] Xu, Q., Li, S., Huang, H., & Wen, J. (2012). Key technologies for the industrial production of fumaric acid by fermentation. Biotechnol Adv, 30(6), 1685-1696. DOI: 10.1016/j.biotechadv.2012.08.007[3] Roa Engel, C. A., Straathof, A. J., Zijlmans, T. W., van Gulik, W. M., & van der Wielen, L. A. (2008). Fumaric acid production by fermentation. Appl Microbiol Biotechnol, 78, 379-389. DOI: 10.1007/s00253-007-1341-x[4] Kocks, C., Wall, D., & Jupke, A. (2022). Evaluation of a Prototype for Electrochemical pH-Shift Crystallization of Succinic Acid. Materials, 15(23), 8412. DOI: 10.3390/ma15238412

Minimizing Coke Formation at La0.3Ca0.7Fe0.7Cr0.3O3-δ Perovskite Anodes in a Syngas Fed-SOFC

As the world moves to decarbonize the fossil fuel sector, transition technologies are needed that bridge the gap between natural gas power plants and more sustainable low-carbon energy sources. These newer technologies often still rely on fossil fuels but have improved energy conversion efficiencies and lower net carbon dioxide (CO2) outputs over conventional fossil fuel based electric power generation systems. In this work, we are exploring one such technology, namely the use of a syngas-fed solid oxide fuel cell (SOFC) to generate heat, electricity, steam, and captured CO2. Core to this technology is the mixed ion electron conductor deployed at the anode and cathode that catalyzes all of the relevant reactions, namely electrochemical oxidation of hydrogen (H2) and carbon monoxide (CO) at the anode, producing steam and CO2, and reduction of oxygen at the cathode.Carbon formation (coking) is normally a significant problem affecting SOFCs operating on carbon-based fuels, as it leads to a rapid decline in electrochemical performance by blocking catalytically active sites and pores with various carbon species, e.g., amorphous, graphitic, or nanotubular carbon.1 The formation of carbon species from syngas is known to occur through various mechanisms, with the Boudouard reaction (∆H= -172 kJ/mol) and the reduction of CO (∆H= -131 kJ/mol) being the most prominent.2 As such, temperature is a key parameter to optimize as it determines the propensity for carbon formation at equilibrium. In addition, the kinetics of carbon formation can be significantly reduced by introducing oxygen to the fuel gas stream in the form of O2, CO2, or H2O.3 The catalyst materials investigated here are mixed conducting perovskite oxides (La0.3Ca0.7Fe0.7Cr0.3O3- δ, LCFCr) that have been optimized and modified recently by our group, both in the as-prepared undoped form and after B-site doping with variable quantities of transition metals (M), e.g., Ni,4 forming nanoparticle (NP)-decorated ABO3-Mx surfaces. Our catalyst is highly active for H2 and CO oxidation, CO2 reduction, and O2 reduction, where it was demonstrated that the un-doped parent material can deliver a stable power density of 0.2 W/cm2 for several hundred hours with negligible performance degradation in 3% humidified H2.5 In more recent work, excellent resilience to carbon deposition for exsolved Fe-Ni@LCFCr up to 70:30 CO:CO2 was demonstrated.4 Herein, we show that minimal coke forms during exposure of these materials to dry syngas at 600oC, even under open circuit conditions.The catalysts were prepared using combustion synthesis and were characterized by XRD, SEM EDX, and TPO-MS in order to confirm morphology, crystal structure, and composition as a function of temperature and gas environment.4 Symmetrical electrolyte-supported SOFCs were constructed using our catalyst as both the anode and cathode. Catalyst layers of 1 cm2 were screen printed to a thickness of 25 µm on both sides of commercially available 130 µm thick samaria-doped ceria (SDC)-buffered scandia-stabilized zirconia (ScSZ) electrolyte, followed by sintering at 1100°C for 2 h,4 with porous metal current collectors used. The cells were mounted and tested in a Fiaxel SOFC test station with gas flow controlled by mass flow controllers.Preliminary electrochemistry experiments were conducted in 5:95 H2:N2, or 1:1 H2:CO (syngas) balanced by CO2 in a 1:2 ratio of fuel to oxidant into the anode chamber, and air into the cathode chamber at 600 oC, with performance evaluation carried out using CV, EIS and chronopotentiometry. The power density was found to be ca. 2x higher in dry H2 vs. in syngas, as expected, considering that H2 is a more active fuel vs. CO. Additionally, EIS exhibited ca. 2x higher resistance in the low frequency arc in syngas, which can be attributed to sluggish CO oxidation kinetics.4 Chronopotentiometry was performed for 20 h at 10 mA cm-2, showing a degradation rate of only 0.08 mV h-1, suspected to be primarily due to current collector delamination. Coking studies were also conducted on button cells at 600 oC in 1:1 H2:CO for 25 h at open circuit, comparing to a NiO standard that was painted on the electrolyte just next to the LCFCr-Ni working electrode. Imaging by SEM showed negligible carbon formation on the perovskite surface, supported by EDX analysis, compared to the extensive degree of coking observed at the standard. Further quantification was conducted by TPO-MS, also confirming minimal carbon formation. References Bengaard et al., Journal of Catalysis, 2002, 209, 365–384.Farshchi Tabrizi et al., Energy Conversion and Management, 2015, 103, 1065–1077.Sasaki et al., Journal of The Electrochemical Society, 2003, 150.Ansari et al., Journal of Materials Chemistry A, 2022, 10, 2280–2294.Addo et al., ECS Transactions, 2015, 66, 219–228.

Electro-Oxidation of Diols in Polymer Recycling: Facilitating Separation and Refining Products

Increasing environmental awareness has highlighted the importance of plastic recycling and rightfully so, considering plastic pollution and an ever-increasing consumption of plastic products. Currently, numerous recycling strategies are being investigated with varying approaches depending on the type of polymer [1]. One attractive process is the chemical recycling of polyesters via alkaline hydrolysis which produces the dicarboxylic acid salts and diols of the respective polyester. The dicarboxylic acids can be separated by crystallization, while the diol separation remains a challenge. A process concept is proposed that utilizes two electrochemical separation technologies to process the polyester hydrolysis solution. A selective electro-oxidation of diols is proposed to mediate and simplify the challenging diol separation. The dicarboxylic acids can be crystalized using an electrochemical pH shift crystallization, which can simultaneously provide the base required for the alkaline hydrolysis of polyesters.The electrochemical pH shift crystallization utilizes water electrolysis in a membrane-separated parallel plate electrolyzer. The pH of the anode and cathode chambers is shifted towards acidic and basic pH values, respectively [2]. The acidification of the anolyte shifts the dissociation equilibrium of the respective dicarboxylic acid salt to the less water-soluble, fully protonated dicarboxylic acid. Crystallization is carried out within the electrolyzer, while the alkaline catholyte solution may be applied in the polyester hydrolysis.To circumvent the challenging removal of diols from aqueous solution [3], a selective electro-oxidation of said diols is proposed. The oxidation towards hydroxycarboxylic acids or dicarboxylic acids facilitates simplified separation processes such as pH shift extraction or crystallization, respectively. Rather than a closed-loop recycling towards both monomers, the proposed process suggests an upgrading of the diols to value-added molecules and crystallization of the dicarboxylic acid, which facilitates and simplifies separation.The study investigates the selective electro-oxidation of diols from three different polyesters: polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT), and polybutylene succinate (PBS). A three-electrode setup utilizing plate electrodes as working electrodes is used in a custom cyclic voltammetry cell. Electro-oxidation is carried out in 1M KOH as electrolyte with diol concentrations ranging from 0.2 to 1M. Following the electrocatalyst activity studies, the selectivity of the electro-oxidation utilizing the most promising catalyst is studied in membrane-separated parallel plate electrolyzer experiments. A custom Luggin-Haber capillary setup monitors and controls the oxidation potential during the experiment. This presentation features the preliminary results of plate electrode catalysts’ electro-oxidation of three different diols in alkaline media. Selectivity studies for the oxidation of the three diols (ethylene glycol, 1,3-propane diol, and 1,4-butane diol) in the membrane-separated parallel plate electrolyzer are presented.[1] Hamad, K., Kaseem, M., & Deri, F. (2013). Recycling of waste from polymer materials: An overview of the recent works. Polymer Degradation and Stability, 98(12), 2801–2812. DOI: 10.1016/j.polymdegradstab.2013.09.025[2] Kocks, C., Wall, D., & Jupke, A. (2022). Evaluation of a Prototype for Electrochemical pH-Shift Crystallization of Succinic Acid. Materials (Basel, Switzerland), 15(23), 8412. DOI: 10.3390/ma15238412[3] Garcia-Chavez, L. Y., Hermans, A. J., Schuur, B., & Haan, A. B. de (2012). COSMO-RS assisted solvent screening for liquid–liquid extraction of mono ethylene glycol from aqueous streams. Separation and Purification Technology, 97, 2–10. DOI: 10.1016/j.seppur.2011.11.041