Active Porous Electrodes Prepared by Ultrasonic‐bath and their Application in Glucose/O 2 Electrochemical Reactions

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The combination of energy and chemical conversion can be achieved by designing glycerol fuel cells. However, the anode must promote the reaction at onset potentials low enough to allow a spontaneous reaction, when coupled to the cathodic reaction, and must be selective. Here, we build a threedimensional (3D)-printed glycerol microfluidic fuel cell that produces power concomitantly to glycolate and formate at zero bias. The balance between energy and the two carbonyl compounds is tuned by decorating the Pt/C/CP anode in situ (before feeding the cell reactants) or in operando (while feeding the cell with reactants) with Bi. The Bi-modified anodes improve glycerol conversion and output power while decreasing the formation of the carbonyl compounds. The in operando method builds dendrites of rodlike Bi oxides that are inactive for the anodic reaction and cover active sites. The in situ strategy promotes homogeneous Bi decoration, decreasing activation losses, increasing the open-circuit voltage to 1.0 V, and augmenting maximum power density 6.5 times and the glycerol conversion to 72% at 25 °C while producing 0.2 mmoL L −1 of glycolate and formate (each) at 100 μL min −1 . Such a performance is attributed to the low CO poisoning of the anode, which leads the glycerol electrooxidation toward a more complete reaction, harvesting more electrons at the device. Printing the microfluidic fuel cell takes 23 min and costs ∼US$1.85 and can be used for other coupled reactions since the methods of modification presented here are applied to any existing and assembled systems.

“…This technique increases the dispersion of the NPs. 36 Finally, the porous Pt/C/CP electrodes were dried at 50 °C for 24 h and used for half-cell and cell measurements.…”

Section: Methodsmentioning

confidence: 99%

“…Thus, strips (10 × 1 mm 2 ) of CP (Toray TGP-060) were immersed in the ink and sonicated for 15 min. This technique increases the dispersion of the NPs . Finally, the porous Pt/C/CP electrodes were dried at 50 °C for 24 h and used for half-cell and cell measurements.…”

Section: Methodsmentioning

confidence: 99%

Glycerol Is Converted into Energy and Carbonyl Compounds in a 3D-Printed Microfluidic Fuel Cell: In Situ and In Operando Bi-Modified Pt Anodes

Souza

Guima

Fernández

et al. 2022

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“…The catalyst in the dark shows no obvious electrochemical features but a slight increase in current at approximately −0.1 V and a reduction centered at approximately −0.45 V, which is due to the formation and reduction of Pt oxides in aqueous electrolytes. Figure A evidences detectable currents from the Pt surface, which is due to the good distribution of the 0.75%Pt-BiVO 4 powder on the high surface area CP, induced by its preparation in an ultrasonic bath …”

Section: Resultsmentioning

confidence: 94%

“…Figure 4A evidences detectable currents from the Pt surface, which is due to the good distribution of the 0.75%Pt-BiVO 4 powder on the high surface area CP, induced by its preparation in an ultrasonic bath. 45 The light induces h + on the surface of the catalyst, which partially electrooxidizes adsorbed intact or fragments of rhodamine B, leading to a net current, starting at around 0.2− 0.3 V (red curve in Figure 4A). However, the presence of CP capacitive current makes it difficult for the visualization of such current.…”

Section: Resultsmentioning

confidence: 99%

Harvesting Energy from an Organic Pollutant Model Using a New 3D-Printed Microfluidic Photo Fuel Cell

Guima

Gomes

Fernandes

et al. 2020

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The combination of a fuel cell and photocatalysis in the same device, called a photo fuel cell, is the next generation of energy converters. These systems aim to convert organic pollutants and oxidants into energy using solar energy as the driving force. However, they are mostly designed in conventional stationary batch systems, generating low power besides being barely applicable. In this context, membraneless microfluidics allows the use of flow, porous electrodes, and mixed media, improving reactant utilization and output power accordingly. Here, we report an unprecedented reusable three-dimensional (3D) printed microfluidic photo fuel cell (μpFC) assembled with low-content PtO x /Pt dispersed on a BiVO4 photoanode and a Pt/C dark cathode, both immobilized on carbon paper. We use fused deposition modeling for additive manufacturing a US$ 2.5 μpFC with a polylactic acid filament. The system shows stable colaminar flow and a short time light distance. As a proof-of-concept, we used the pollutant-model rhodamine B as fuel, and O2 in an acidic medium at the cathode side. The mixed-media 3D printed μpFC with porous electrodes produces remarkable 0.48 mW cm–2 and 4.09 mA cm–2 as maximum power and current densities, respectively. The system operates continuously for more than 5 h and converts 73.6% rhodamine by photoelectrochemical processes. The 3D printed μpFC developed here shows promising potential for pollutant mitigation concomitantly to power generation, besides being a potential platform of tests for new (photo)electrocatalysts.

“…Here, we used the Cu NPs synthesized in an ultrasonic bath due to the high activity and efficient conversion shown in half-cell and spectroelectrochemical measurements, as discussed later. The anode was prepared by immersing a 19 mm × 1 mm CP solution in a 25 mg mL –1 Cu aqueous suspension in a sonic bath for 5 min and dried in oven at 50 °C for 6 h. This protocol developed by Caneppele et al improves particle dispersion . It is worth noting that we used Cu directly dispersed on CP instead of previously building an ink with Cu on a carbon support such as carbon black.…”

Section: Methodsmentioning

confidence: 99%

A Comprehensive Investigation of Methanol Electrooxidation on Copper Anodes: Spectroelectrochemical Insights and Energy Conversion in Microfluidic Fuel Cells

Queiroz,

Vital,

Budke

et al. 2024

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Here, we comprehensively investigated methanol electrooxidation on Cu-based catalysts, allowing us to build the first microfluidic fuel cell (μFC) equipped with a Cu anode and a metal-free cathode that converts energy from methanol. We applied a simple, fast, small-scale, and surfactant-free strategy for synthesizing Cu-based nanoparticles at room temperature in steady state (ST), under mechanical stirring (MS), or under ultrasonication (US). The morphology evaluation of the Cu-based samples reveals that they have the same nanoparticle (NP) needle-like form. The elemental mapping composition spectra revealed that pure Cu or Cu oxides were obtained for all synthesized materials. In addition to having more Cu 2 O on the surface, sample US had more Cu(OH) 2 than the others, according to X-ray diffractograms and X-ray photoelectron spectroscopy. The sample US is less carbon-contaminated because of the local heating of the sonic bath, which also enhances the cleanliness of the Cu surface. The activity of the Cu NPs was investigated for methanol electrooxidation in an alkaline medium through electrochemical and spectroelectrochemical measurements. The potentiodynamic and potentiostatic experiments showed higher current densities for the NPs synthesized in the US. In situ FTIR experiments revealed that the three synthesized NP materials eletcrooxidize methanol completely to carbonate through formate. Most importantly, all pathways were led without detectable CO, a poisoning molecule not found at high overpotentials. The reaction path using the US electrode experienced an additional round of formate formation and conversion into carbonate (or CO 2 in the thin layer) after 1.0 V (vs. Ag/Ag/Cl), suggesting improved catalysis. The high activity of NPs synthesized in the US is attributed to effective dissociative adsorption of the fuel due to the site's availability and the presence of hydroxyl groups that may fasten the oxidation of adsorbates from the surface. After understanding the surface reaction, we built a mixed-media μFC fed by methanol in alkaline medium and sodium persulfate in acidic medium. The μFC was equipped with Cu NPs synthesized in ultrasonic-bath-modified carbon paper as the anode and metal-free carbon paper as the cathode. Since the onset potential for methanol electrooxidation was 0.45 V and the reduction reaction revealed 0.90 V, the theoretical OCV is 0.45 V, which provides a spontaneous coupled redox reaction to produce power. The μFC displayed 0.56 mA cm −2 of maximum current density and 26 μW cm −2 of peak power density at 100 μL min −1 . This membraneless system optimizes each half-cell individually, making it possible to build fuel cells with noble metal-free anodes and metal-free cathodes.