Browsing by Author "Arbiol, Jordi"
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- Enhanced Electrochemical Hydrogenation of Benzaldehyde to Benzyl Alcohol on Pd@Ni-MOF by Modifying the Adsorption Configuration
A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä(2024-02-14) Gong, Li; Zhang, Chao Yue; Li, Junshan; Montaña-Mora, Guillem; Botifoll, Marc; Guo, Tiezhu; Arbiol, Jordi; Zhou, Jin Yuan; Kallio, Tanja; Martínez-Alanis, Paulina R.; Cabot, AndreuElectrocatalytic hydrogenation (ECH) approaches under ambient temperature and pressure offer significant potential advantages over thermal hydrogenation processes but require highly active and efficient hydrogenation electrocatalysts. The performance of such hydrogenation electrocatalysts strongly depends not only on the active phase but also on the architecture and surface chemistry of the support material. Herein, Pd nanoparticles supported on a nickel metal-organic framework (MOF), Ni-MOF-74, are prepared, and their activity toward the ECH of benzaldehyde (BZH) in a 3 M acetate (pH 5.2) aqueous electrolyte is explored. An outstanding ECH rate up to 283 μmol cm-2 h-1 with a Faradaic efficiency (FE) of 76% is reached. Besides, higher FEs of up to 96% are achieved using a step-function voltage. Materials Studio and density functional theory calculations show these outstanding performances to be associated with the Ni-MOF support that promotes H-bond formation, facilitates water desorption, and induces favorable tilted BZH adsorption on the surface of the Pd nanoparticles. In this configuration, BZH is bonded to the Pd surface by the carbonyl group rather than through the aromatic ring, thus reducing the energy barriers of the elemental reaction steps and increasing the overall reaction efficiency. - Influence of the catalyst surface chemistry on the electrochemical self-coupling of biomass-derived benzaldehyde into hydrobenzoin
A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä(2024-07-12) Gong, Li; Zhao, Shiling; Yu, Jing; Li, Junshan; Arbiol, Jordi; Kallio, Tanja; Calcabrini, Mariano; Martínez-Alanis, Paulina R.; Ibáñez, Maria; Cabot, AndreuThe electroreduction of biomass-derived benzaldehyde (BZH) provides a potentially cost-effective route to produce benzyl alcohol (BA). This reaction competes with the electrochemical self-coupling of BZH to hydrobenzoin (HDB), which holds significance as a biofuel. Herein, we demonstrate the selectivity towards one or the other product strongly depends on the surface chemistry of the catalyst, specifically on its ability to adsorb hydrogen, as showcased with Cu2S electrocatalysts. We particularly analyze the effect of surface ligands, oleylamine (OAm), on the selective conversion of BZH to BA or HDB. The effect of the electrode potential, electrolyte pH, and temperature are studied. Results indicate that bare Cu2S exhibits higher selectivity towards BA, while OAm-capped Cu2S promotes HDB formation. This difference is explained by the competing adsorption of protons and BZH. During the BZH electrochemical conversion, electrons first transfer to the C in the C=O group to form a ketyl radical. Then the radical either couples with surrounding H+ to form BA or self-couple to produce HDB, depending on the H+ availability that is affected by the electrocatalyst surface properties. The presence of OAm inhibits the H adsorption on the electrode surface therefore reducing the formation of high-energy state Had and its combination with ketyl radicals to form BA. Instead, the presence of OAm promotes the outer sphere reaction for obtaining HDB. - Mechanistic Insights and Technical Challenges in Sulfur-Based Batteries : A Comprehensive In Situ/Operando Monitoring Toolbox
A2 Katsausartikkeli tieteellisessä aikakauslehdessä(2024) Yu, Jing; Pinto-Huguet, Ivan; Zhang, Chao Yue; Zhou, Yingtang; Xu, Yaolin; Vizintin, Alen; Velasco-Vélez, Juan Jesús; Qi, Xueqiang; Pan, Xiaobo; Oney, Gozde; Olgo, Annabel; Märker, Katharina; M. Da Silva, Leonardo; Luo, Yufeng; Lu, Yan; Huang, Chen; Härk, Eneli; Fleming, Joe; Chenevier, Pascale; Cabot, Andreu; Bai, Yunfei; Botifoll, Marc; Black, Ashley P.; An, Qi; Amietszajew, Tazdin; Arbiol, JordiBatteries based on sulfur cathodes offer a promising energy storage solution due to their potential for high performance, cost-effectiveness, and sustainability. However, commercial viability is challenged by issues such as polysulfide migration, volume changes, uneven phase nucleation, limited ion transport, and sluggish sulfur redox kinetics. Addressing these challenges requires insights into the structural, morphological, and chemical evolution of phases, the associated volume changes and internal stresses, and ion and polysulfide diffusion within the battery. Such insights can only be obtained through real-time reaction monitoring within the battery’s operational environment, supported by molecular dynamics simulations and advanced artificial intelligence-driven data analysis. This review provides an overview of in situ/operando techniques for real-time tracking of these processes in sulfur-based batteries and explores the integration of simulations with experimental data to provide a holistic understanding of the critical challenges, enabling advancements in their development and commercial adoption.