ICMS
Artículos SCI
2026
2026
Fotocatálisis Heterogénea: Aplicaciones
Photo-assisted degradation of rhodamine B with H₂O₂: Kinetics, modern machine learning prediction, and insights into a novel iron oxide catalyst
Eddine Zahi, S; Hidalgo, MC; Navío, JA; Heddam, S; Yacine, KJournal of Photochemistry and Photobiology A; Chemistry DOI: 10.1016/j.jphotochem.2025.116739
Abstract
This study introduces a dual strategy that combines kinetic modeling and advanced machine learning (ML) models to enhance the prediction and optimization of Rhodamine B (RhB) degradation using an H2O2/UV system. As a novel scientific contribution, we report the first-time synthesis of an iron-based catalyst, integrating α-Fe2O3 with structural ions (SO₄2−, OH−, Cl−), synthesized via a microwave-assisted hydrothermal method, a rapid and energy-efficient approach conducive to scalability. The synthesized catalyst was thoroughly characterized by XRD, FTIR, SEM-EDX, XPS and BET, confirming its crystalline integrity, surface richness, and robust textural properties.
In the machine learning analysis, CatBoost regression outperformed XGBoost, ERT, and GPR, delivering the highest predictive accuracy for RhB degradation under varying operational conditions of H2O2/UV. SHAP (SHapley Additive exPlanations) interpretation revealed that reaction time held the greatest predictive importance, followed by the initial concentrations of H2O2 and RhB. Experimental results showed that the α-Fe2O3 catalyst consistently achieved complete RhB discoloration within 60 min under illuminated conditions, demonstrating exceptional photocatalytic activity. Most interestingly, the integration of the catalyst with H2O2, under both dark and illumination conditions (heterogeneous Fenton and photo-Fenton processes), resulted in complete RhB discoloration in as little as 1 min.
Overall, this work highlights the transformative potential of ML-assisted process design in environmental catalysis and introduces a robust, scalable iron-based material, for water treatment applications, particularly in scenarios with variable light exposure or energy constraints.
Marzo, 2026 · DOI: 10.1016/j.jphotochem.2025.116739
2025
2025
Fotocatálisis Heterogénea: Aplicaciones
Enhanced photocatalytic degradation of organic pollutants in water by g-C3N4/N-TiO2/Y1.97SiO5:Ce0.03 heterostructure
Pathak, M; Sacco, O; Mancuso, A; Vaiano, V; Hidalgo, MC; Iannece, P; Venditto, V; Daniel, CChemical Engineering Journal, 521 (2025) 166559 DOI: 10.1016/j.cej.2025.166559
Abstract
A novel ternary heterostructure based on g-C3N4/N-TiO2/Y1.97SiO5:Ce-0.03 was synthesized via thermal treatment and evaluated for the photocatalytic degradation of two antibiotic pollutants, chloramphenicol (CAP) and vancomycin (VAN), in aqueous solution. The composite was designed to function as a photoactive platform, in which Ce3+-doped Y2SiO5 acts as an internal light converter, emitting at similar to 430 nm upon UV excitation (365 nm) to enhance activation of the g-C3N4/N-TiO2 interface. Structural and morphological characterizations (WAXD, FTIR, XPS, TEM) confirmed the formation of a well-integrated heterostructure with strong interfacial interactions. The photocatalyst achieved near-complete removal of CAP (99.7 %) and VAN (100 %) under UV light, and also showed high efficiency under simulated solar irradiation and in real water matrices. These results demonstrate the synergistic light-conversion and charge-transfer properties of the composite, underscoring its potential as a sustainable and scalable solution for antibiotic pollutant removal in water treatment applications.
Octubre, 2025 · DOI: 10.1016/j.cej.2025.166559
Fotocatálisis Heterogénea: Aplicaciones
Enhancing the Photocatalytic Performance of WO3/AgBr Composites Through the Incorporation of Olive Waste-Derived Biochar Obtained Under Controlled Pyrolysis Conditions
Hidalgo, MC; Alcalá, MD; Navío, JA; Romero-Sarria, FMolecular Catalysis, 26 (2025) 10451 DOI: 10.3390/ijms262110451
Abstract
The integration of biochars into photocatalytic systems to increase their efficiency in the degradation of different pollutants in water has gained attention in recent years. However, systematic studies on optimizing biochar properties for photocatalysis remain limited. This work explores the incorporation of biochar from olive pruning (BCO), produced via CO2 pyrolysis at 800 °C, into WO3/AgBr photocatalysts for Rhodamine B degradation used as a model pollutant. Characterization of BCO reveals a hydrophilic, porous material (487 m2/g surface area) rich in mineral content (notably CaCO3). The study evaluates the effects of incorporation method (mechanical vs. in situ) and biochar content (1 and 10 wt. %) on photocatalytic performance. Comprehensive characterization of BCO and the resulting composites supports the observed activity trends. The findings highlight the potential of agricultural waste valorization for environmental remediation and offer insights into designing efficient biochar-based photocatalytic systems.
Octubre, 2025 · DOI: 10.3390/ijms262110451
Química de Superficies y Catálisis
Catalytic performance of NiCo-CePr oxide on FeCrAlloy micromonoliths in hydrogen production by oxidative steam reforming of ethanol
Rodríguez, C; Martínez, TM; Centeno, MA; Moreno, S; Molina, REnergy Conversion and Management, 341 (2025) 120089 DOI: 10.1016/j.enconman.2025.120089
Abstract
The conformation of a NiCo catalyst promoted by CePr on FeCrAlloy thermally pretreated micromonoliths was investigated via washcoating using a colloidal suspension of the catalytic precursor (hydrotalcite, HT) without the use of additives. A high affinity was established between the nature of the reconstructed HT and the layer of the formed alumina microstructures obtained after thermal treatment, which exhibited high material adhesion. The effect of the amount of catalyst incorporated into the sinusoidal microchannels of monoliths was also investigated. The catalytic performance was evaluated for the production of H-2 from oxidative steam reforming of ethanol (OSRE) and compared with that of a powder catalyst (slurry) and an uncoated micromonolith. The results indicated notable benefits from the micromonoliths, especially when incorporating low amounts of catalyst with low layer thicknesses-LT (8 gL-1, layer thickness similar to 0.3 mu m), achieved a hydrogen yield of 2.86 mol(H2)mol(EtOH)(-1), comparable to that of the powder catalyst benchmark (2.91 mol(H2)mol(EtOH)(-1)), but with enhanced stability at 65 h and improved heat and mass transport characteristics. Overall, this study opens the way for the promising feasibility of scaling up the OSRE reaction to produce H-2.
Octubre, 2025 · DOI: 10.1016/j.enconman.2025.120089
Reactividad de Sólidos
Boron nitride nanosheets as an effective strategy against the slow crack growth and hydrothermal ageing in zirconia composites
Munoz-Ferreiro, C; Morales-Rodríguez, A; Reveron, H; Guisado-Arenas, E; Cottrino, S; Moreno, P; Prada-Rodrigo, J; Chevalier, J; Gallardo-López, A; Poyato, ROpen Ceramics, 23 (2025) 100816 DOI: 10.1016/j.oceram.2025.100816
Abstract
This paper explores the effectiveness of boron nitride nanosheets in preventing the premature failure of yttriastabilized tetragonal zirconia ceramics, particularly in humid environments. A simple, low-cost and scalable technique-shear exfoliation in a kitchen blender-was used to prepare BNNS, and pure zirconia and composites with 1, 2.5 and 5 vol. % BNNS were spark plasma sintered. Accelerated hydrothermal ageing experiments in autoclave revealed a remarkable improvement of low temperature degradation resistance in all the composites. Fracture toughness and slow crack growth of the composites with 1 and 2.5 vol. % BNNS were evaluated by bending tests performed in notched specimens. Although the composites presented fracture toughness values similar to those of the reference zirconia, an increase of similar to 18 % on crack-tip toughness was achieved. Similar Rcurves evaluated in air and in oil-impregnated 2.5 vol. % BNNS composites revealed a limitation of stress-assisted corrosion by water in zirconia, thanks to the BNNS incorporation.
Septiembre, 2025 · DOI: 10.1016/j.oceram.2025.100816
Química de Superficies y Catálisis
Formic acid dehydrogenation and use as H-donor in 5-hydroxymethylfur-fural hydrodeoxygenation over Pd/C3N4 catalysts
Achour, M; Alvarez-Hernández, D; Megías-Sayago, C; Ammari, F; Centeno, MA; Ivanova, SCatalysis Today, 457 (2025) 115353 DOI: 10.1016/j.cattod.2025.115353
Abstract
This work studies the behavior of a series of Pd/C3N4 catalyst in the reaction of formic acid dehydrogenation and the use of the latter as H-donor for 2,5-hydroxymethyl furfural hydrodeoxygenation. Firstly, a series of supports have been synthesized from melamine and urea as a function of precursors ratio and temperature of their condensation. The different synthetic conditions resulted in materials with very different specific surface areas and N-containing groups on the surface which influenced Pd deposition. The resulting defects facilitated enhanced electron transfer from nitrogen to Pd due to the close positioning of Pd nanoparticles near nitrogen sites. Consequently, the physicochemical and catalytic properties of the materials were notably impacted.
Septiembre, 2025 · DOI: 10.1016/j.cattod.2025.115353
Materiales de Diseño para la Energía y Medioambiente
Multicomponent heavy metals adsorption on functionalized swelling micas: Mechanistic insights and structural evolution
Osuna, J; Chaparro, JR; Pavon, E; Alba, MDSurfaces and Interfaces, 72 (2025) 106996 DOI: 10.1016/j.surfin.2025.106996
Abstract
Heavy metal contamination is a critical environmental issue, often involving complex multicomponent systems. Swelling brittle micas, a family of designer sorbents, have demonstrated exceptional heavy metal removal capabilities, yet their behabior in competitive adsorption systems remains largely unexplored. This study systematically investigates the simultaneous uptake of Pb2*, Cd2*, and Hg2* on both as-synthesized brittle mica and its thiol-functionalized counterpart. Using X-ray diffraction (XRD) and nuclear magnetic resonance (NMR), we reveal critical structural transformations occurring at both short-and long-range scales during adsorption. Our findings demonstrate that competitive adsorption governs metal uptake, leading to a reduction in total adsorption capacity compared to single-metal systems. However, selectivity toward specific metal cations remains unchanged, irrespective of competing species or surface functionalization. Overall, this study not only improves our understanding of heavy metal adsorption but also paves the way for more effective and sustainable sorbent design in environmental remediation.
Septiembre, 2025 · DOI: 10.1016/j.surfin.2025.106996
Reactividad de Sólidos
High piezoelectric performance in lead-free BCHT fine-grained ceramics synthesized by mechanochemistry
Santiago-Andrades, L; Romero, FJ; Gotor, FJ; Sayagués, MJ; Moriche, RCeramics International, 51 (2025) 27950-27960 DOI: 10.1016/j.ceramint.2025.04.009
Abstract
Lead-free piezoelectric ceramics (Ba1-xCax) (Ti1-yHfy)O-3 with stoichiometries close to the morphotropic phase boundary (MPB) were synthesized by high-energy ball milling. The influence of Hf and Ca contents and the sintering method (conventional and hot-press) on the piezoelectric, dielectric, and ferroelectric response was investigated. It was confirmed that the different phases stabilized at room temperature and the structural distortion are strongly dependent on the stoichiometry. The coexistence of tetragonal, orthorhombic and rhombohedral phases was observed in samples with the lowest Ca and Hf contents. These samples, which are in the MPB region, also showed the greatest structural distortion, resulting in higher values of d(33). Samples with lower Hf content exhibited a higher coercive field, remnant polarization, and temperature in the ferroelectric to paraelectric transition. Despite the high sintering temperature leading to high densification, grain growth during sintering was limited because of the use of mechanochemically synthesized powders. Although Ba0.85Ca0.15Hf0.10Ti0.90O3 stoichiometry has been reported in the literature as the best for piezoelectric properties, in this work, BCHT solid solution with the lowest dopant content studied (Ba0.90Ca0.10Hf0.05Ti0.95O3) showed the best combination of functional properties. Ceramics of this composition with grain size <2 mu m exhibited a d(33) > 250 pC/N, with almost no relaxation after 24 h, and the highest permittivity. In the field of piezoelectric materials, there is considerable interest in reducing grain size while maintaining high piezoelectric performance, as this can lead to improvements in mechanical properties.
Agosto, 2025 · DOI: 10.1016/j.ceramint.2025.04.009
Reactividad de Sólidos
Descriptors for Predicting Single- and Multi-Phase Formation in High-Entropy Oxides: A Unified Framework Approach
Manchón-Gordón, AF; Panadero-Medianero, P; Blázquez, JSMaterials, 18 (2025) 3862 DOI: 10.3390/ma18163862
Abstract
High-entropy oxides, HEOs, represent a relatively new class of ceramic materials characterized by the incorporation of multiple cations, typically four or more, into a single-phase crystal structure. This extensive compositional flexibility allows for the introduction of specific chemical elements into a crystal lattice that would normally be unable to accommodate them, making it difficult to predict a priori their properties and crystal structures. Consequently, studying the phase stability of these single-phase materials presents significant challenges. This work examines the key parameters commonly employed to predict the stabilization of HEOs and introduces a unified framework for analyzing their stability. The proposed approach incorporates a normalized configurational entropy per mole of atoms and the relative volume occupied by cations into the mean atomic size deviation. By combining these parameters, the approach enables, as a first approximation, the identification of compositional ranges that favor the formation of single-phase and multi-phase HEO compounds with rock salt, spinel, fluorite, pyrochlore, and perovskite structures.
Agosto, 2025 · DOI: 10.3390/ma18163862
Química de Superficies y Catálisis
Integrated carbon capture and dry reforming of methane of mechanochemically synthesised dual-function materials
Merkouri, LP; Danielis, M; Braga, A; Reina, TR; Trovarelli, A; Colussi, S; Duyar, MSRSC Sustainability (2025). DOI: 10.1039/D5SU00317B
Abstract
Herein we report a green mechanochemical synthesis with low energy input of dual-function materials for integrated CO2 capture and dry reforming of methane. The materials produced syngas during the CH4 step (up to 0.6 mmol g−1 CO and 7.7 mmol g−1 H2) and CO during the CO2 step (up to 3.1 mmol g−1) via the reverse Boudouard reaction due to the carbon produced from CH4 cracking.
Agosto, 2025 · DOI: 10.1039/D5SU00317B
Materiales de Diseño para la Energía y Medioambiente
Enhanced Oxygen Ion Conductivity and Ionic Conduction Mechanistic Visualization in Tetragonal Zircon-Type Pr1-x Sr x VO4-0.5x
Hang, GQ; Li, QL; Fernandez-Carrion, AJ; Deng, SH; He, LH; Kuang, XJ; Yang, XYInorganic Chemistry, 64 (2025) 17166-17177 DOI: 10.1021/acs.inorgchem.5c01878
Abstract
Oxide-ion conductors based on tetrahedral anion-related oxides have attracted considerable attention due to their high oxygen-ion conductivity and potential applications in clean energy devices, such as solid-state fuel cells. In this study, we report the improvement of oxide-ion conductivity by Sr2+ doping in isolated tetrahedral zircon-type PrVO4. It is found that Pr0.975Sr0.025VO4-delta features the highest oxide-ion conductivity of 2.62 x 10-3 Scm-1 at 800 degrees C under air, with an oxygen transport number of 0.93. The formation and stabilization of oxygen vacancy defects, as well as the oxide-ion migration mechanism in PrVO4, were investigated through combining experimental characterizations and computing simulations. The results indicate that the concentration of oxygen vacancy defects increases with Sr2+ substitution, and the vacancies are accommodated by the formation of corner-sharing V2O7 dimers. Oxygen-ion migration proceeds via a cooperative mechanism involving V2O7-dimer breaking and reforming assisted by synergistic rotation and deformation of neighboring VO4 tetrahedra. The results provide valuable insights for further investigation and optimization of zircon-type oxides as potential oxide-ion conductors for electrochemical devices.
Agosto, 2025 · DOI: 10.1021/acs.inorgchem.5c01878
Materiales de Diseño para la Energía y Medioambiente
Laser-Induced Graphene: A Promising Conductive Platform for Cell Culture
de Almeida, HV; Inácio, JM; Pereira, C; Pinheiro, T; Calmeiro, T; Correia, R; Coelho, J; Pinto, JV; Belo, JA; Martins, R; Fortunato, EAdvanced Healthcare Materials (2025) e02255 DOI: 10.1002/adhm.202502255
Abstract
Cardiovascular mortality remains a major health challenge. Cardiomyocyte (CM)-based tissue engineering (TE) offers promising alternatives for developing therapies via in vitro models. However, the immature phenotype of CM in engineered tissues hampers progress. Recent studies introduce conductive materials like graphene to enhance CM maturation, but conventional graphene synthesis suffers from complexity, toxicity, and low yield. Laser-induced graphene (LIG) provides a sustainable, cost-effective, eco-friendly solution with efficient conductivity and biocompatibility. A LIG-based substrate is bioengineered in this study, hypothesizing that its conductive, anisotropic properties promote CM maturation and mimic the native cardiac niche. LIG is fabricated using a CO2 laser with Parylene-C as a precursor. Stem cells (SCs) and SC-derived embryoid bodies (EBs) are cultured on LIG substrates, and their viability, metabolic activity, morphology, and protein expression are evaluated through immunofluorescence and electron microscopy. Both SCs and EBs maintain viability and activity throughout the culture. Moreover, EB-derived CM exhibit spontaneous contraction and express cardiac-specific proteins, confirming functional differentiation on LIG matrices. This first report demonstrates that LIG substrates support SC culture and differentiation, highlighting their potential in developing refined in vitro cardiac models and advancing regenerative therapeutic strategies. The findings support LIG as a transformative advancement in TE.
Agosto, 2025 · DOI: 10.1002/adhm.202502255
Química de Superficies y Catálisis
Boosting Hydrogen Release: Optimized C3N4-Supported Palladium Catalysts for Formic Acid Dehydrogenation
Moreno, A; Lobo, L; Martínez, LM; Bobadilla, LF; Ivanova, S; Domínguez, MI; Centeno, MAChemCatChem (2025) e00873 DOI: 10.1002/cctc.202500873
Abstract
Carbon nitride, C3N4, was synthesized through thermal polycondensation of melamine with varying temperature and time conditions. This approach represents a cost-effective, straightforward, and environmentally friendly synthetic method with lower energy consumption to obtain hierarchically structured carbon nitride. The resulting materials were subjected to comprehensive characterization to analyze their crystalline structure, textural properties, composition, and light absorption characteristics. To evaluate their catalytic potential, the supports were impregnated with different loadings of palladium (1, 5, and 10 wt%) as the active phase and tested in the decomposition of formic acid for hydrogen production in liquid phase at mild conditions. This study revealed that the structure and composition of the C3N4 were highly dependent on the degree of polycondensation, which in turn was influenced by the temperature and the thermal synthesis process. The most promising catalytic performance was achieved with a support prepared by decomposing melamine at 650 degrees C for 4 h, followed by impregnation with 10 wt% Pd. Furthermore, a mechanistic study was conducted using operando DRIFTS-MS to explore the plausible catalytic pathways for synthesizing formic acid via CO2 hydrogenation using the aforementioned catalyst. This investigation highlights the potential of C3N4 as a support, further demonstrating its versatility in the circular economy of formic acid.
Agosto, 2025 · DOI: 10.1002/cctc.202500873
Materiales de Diseño para la Energía y Medioambiente
Graphene exfoliation in cyrene for the sustainable production of microsupercapacitors
Moreira, P; Carvalho, D; Abreu, R; Alba, MD; Ramírez-Rico, J; Fortunato, E; Martins, R; Pinto, JV; Carlos, E; Coelho, JJournal of Physics-Energy, 7 (2025) 035005 DOI: 10.1088/2515-7655/adca57
Abstract
Graphene and its composites have attracted much attention for applications in energy storage systems. However, the toxic solvents required for the exfoliation process have hampered the exploitation of its properties. In this work, graphene dispersions are obtained via liquid phase exfoliation (LPE) of graphite in cyrene, an environmentally friendly solvent with solubility parameters like those of N-methyl-2-pirrolidone. The obtained dispersions with a concentration of 0.2 mg ml-1 comprised multilayered graphene sheets with lateral sizes in the hundreds of nanometers, as confirmed by scanning electron microscopy, transmission electron microscopy, and Raman spectroscopy. Mixing the obtained dispersions with ethanol made it possible to collect the graphene, which was redispersed in 2-Propanol. This active material was used to fabricate supercapacitor electrodes using a scalable spray deposition method on carbon nanotube (CNT) current collectors with the aid of vinyl masks. The device, tested with a PVA/LiCl gel electrolyte, achieved a specific capacitance of 3.4 mF cm(-2) (0.015 mA cm(-2)). In addition, the devices show excellent cycling stability (>10 000 cycles at 0.5 mA cm(-2)) and good mechanical properties, losing less than 10% of initial capacitance after 1000 bending cycles. This work demonstrates the adaptability of liquid-phase exfoliation to produce graphene sustainably, providing the proof-of-concept for further 2D materials processing and green microsupercapacitor (MSC) fabrication.
Julio, 2025 · DOI: 10.1088/2515-7655/adca57
Materiales Semiconductores para la Sostenibilidad
Resonant Cavity Effect for Spectrally Tunable and Efficient Narrowband Perovskite Photodetectors
Ooi, ZY; Nie, SY; Vega, G; Lai, MC; Jiménez-Solano, A; Huang, CS; Wang, H; Liu, TJ; Galkowski, K; Nowak, MP; Nyga, P; Cheng, QX; Ducati, C; Carretero-Palacios, S; Kahmann, S; Stranks, SD; Anaya, MACS Photonics (2025). DOI: 10.1021/acsphotonics.4c01942
Abstract
Narrowband photodetectors with precise spectral control offer significant potential for applications such as color imaging and machine vision. However, existing demonstrations have encountered challenges due to restricted absorption, the need for additional filters, or the inclusion of thick absorbing layers to facilitate charge collection filtering mechanisms. These constraints have resulted in suboptimal detectivity, inadequate color control, or slow response. Here, we exploit cavity resonance enhancement to demonstrate a highly spectral selective and robust perovskite photodetector, showing 2.4-fold EQE enhancement at the main narrowband peak with respect to a broadband photodetector counterpart of the same perovskite thickness. This device architecture achieves peak external quantum efficiency of 80%, responsivity of 0.41 A W-1, and detectivity of 3.7 x 1011 Jones at the main narrowband peak, with a secondary signal below 450 nm that can be mitigated with advanced photonic crystal as proposed. Additionally, the resonant cavity-enhanced photodetector offers a rapid switching of 0.9 mu s and low noise of 0.57 pW Hz-1/2. Our demonstration shows precise tuning of the main narrowband photodetection characteristics across a 100 nm spectral range by simply varying the thickness of the perovskite layer, ensuring device efficiency and stability across the wavelength region around 560 to 660 nm, where most perovskite devices suffer from degradation due to halide segregation. This work demonstrates the practical integration of resonant cavity enhancement in perovskite photodetectors and paves the way for high-performance optical sensing, multispectral imaging, and wavelength-selective photonic devices.
Julio, 2025 · DOI: 10.1021/acsphotonics.4c01942
Materiales de Diseño para la Energía y Medioambiente
In situ TEM and synchrotron SAXS/WAXS study on the impact of different iron salts on iron-catalysed graphitization of cellulose
Hayward, EC; Takeguchi, M; Lloyd, HJ; Stratford, JM; Smith, AJ; Snow, T; Ramirez-Rico, J; Schnepp, ZJournal of Materials Chemistry A, (2025). DOI: 10.1039/d5ta03584h
Abstract
Carbon materials are essential for emerging energy applications and there is a pressing need to be able to produce carbons with controlled properties from sustainable precursors. Iron-catalysed graphitization of biomass is an attractive approach, where simple iron salts are used to convert organic matter to graphitic carbons at relatively low temperature. The choice of iron salt can have a significant impact on the chemical and structural properties of carbons derived from biomass. In this paper, we report a detailed mechanistic investigation of iron catalysed graphitization of cellulose by Fe(NO3)3 and FeCl3. In situ small and wide angle X-ray scattering and electron microscopy show that the evolution of catalyst particles from the two salts follows very different pathways. Remarkably, graphitization by FeCl3 is an order of magnitude faster than by Fe(NO3)3.
Julio, 2025 · DOI: 10.1039/d5ta03584h
Nanotecnología en Superficies y Plasma
Improving energy storage properties of carbon felt electrodes for vanadium redox flow batteries via ZIF modifications
Lobato-Peralta, DR; Molina-Serrano, AJ; Luque-Centeno, JM; Sánchez-Laganga, B; Sebastián, D; Carrasco-Marín, F; Lázaro, MJ; Alegre, CChemical Engineering Journal, 515 (2025) 163534 DOI: 10.1016/j.cej.2025.163534
Abstract
In this study, we successfully enhanced the electrochemical energy storage properties of commercial carbon felts by modifying their surface with metal-organic frameworks (MOFs) of the zeolitic imidazolate framework (ZIF) type, incorporating Fe, Co, Ni, Cu, and Zn as metal centres. These modifications were achieved through two distinct processes: layer-by-layer deposition and a hydrothermal synthesis method. The resulting materials were thoroughly characterized using scanning electron microscopy with energy-dispersive X-ray spectroscopy (SEM/ EDX), X-ray diffraction (XRD), inductively coupled plasma spectroscopy (ICP), and cyclic voltammetry (CV) in a three-electrode cell. Our findings indicate that the materials synthesized via the hydrothermal process exhibited superior electrochemical performance compared to those obtained through the layer-by-layer method. In light of the findings, the study progressed to the device stage, specifically a single-cell vanadium redox flow battery. In this stage of the study, the modified electrodes were characterized using two key techniques: galvanostatic charge-discharge and electrochemical impedance spectroscopy. This characterization revealed that electrodes modified with ZIF structures displayed significantly reduced polarization compared to those fabricated with the unmodified commercial felt. The ZIFs that exhibited the most significant enhancements in electrocatalytic performance were those based on Zn, Cu, and Ni (in this order), as these metals demonstrated higher deposition levels on the carbon felt electrodes and exhibited superior dispersion. The enhancements resulted in significant performance improvements, with energy efficiency increases of up to 29 % and accessible capacity improvements of up to 33 %. This research demonstrates the potential of ZIF-modified carbon felt as a highly effective electrode material for vanadium redox flow batteries, paving the way for more efficient and scalable energy storage systems. Despite the minimal metal content present in the MOFs, our results demonstrate a significant enhancement in electrode performance, highlighting the efficiency of this approach and its potential to optimize the electrochemical activity of VRFB electrodes with minimal material usage.
Julio, 2025 · DOI: 10.1016/j.cej.2025.163534
Reactividad de Sólidos
Thermal stability and electrical properties of XFe2O4 (X = Co,Cu,Fe,Mg,Mn Ni) high-entropy spinel ferrites prepared by reactive flash sintering
Manchón-Gordón, AF; Molina-Molina, S; Almanza-Vergara, GE; Perejón, A; Sánchez-Jiménez, PE; Pérez-Maqueda, LAJournal of Alloys and Compounds, 1036 (2025) 1851662 DOI: 10.1016/j.jallcom.2025.181662
Abstract
This study investigates the high-temperature stability and phase composition of two high-entropy oxides (HEOs), (Mn0.2Co0.2Ni0.2Cu0.2Fe0.2)Fe2O4 and (Mn0.2Co0.2Ni0.2Cu0.2Mg0.2)Fe2O4, prepared as single-phase samples using the reactive flash sintering technique. Results show that the annealing temperature in a nitrogen atmosphere has a significant impact on the stability of the compounds. The destabilization of the spinel structure occurs in a twostep process: spinel HEO -> spinel HEO + Fe2O3 -> spinel HEO + Cu based-oxide. This sequence is inferred from in-situ XRD experiments and calorimetric analysis, and confirmed by TEM observations. Impedance spectroscopy analysis revealed a complex, thermally activated electrical response comprising bulk and grain boundary contributions. AC conductivity follows Jonscher's universal power law, with a temperature dependence of the S parameter consistent with overlapping large polaron tunneling. These findings provide insight into charge transport and relaxation processes in the prepared HEOs, improving their understanding for potential electrical applications.
Julio, 2025 · DOI: 10.1016/j.jallcom.2025.181662
Nanotecnología en Superficies y Plasma - Tribología y Protección de Superficies
Voids and nanopores in nanocolumnar platinum thin films grown by magnetron sputtering and evaporation at oblique angles: A comparative analysis
Garcia-Valenzuela, A; Acosta-Rivera, H; Liedke, MO; Butterling, M; Hirschmann, E; Attallah, AG; Wagnerb, A; Rojas, TC; Alvarez, R; Rico, V; Palmero, A; Gonzalez-Elipe, ARSurfaces and Interfaces, 68 (2025) 106667 DOI: 10.1016/j.surfin.2025.106667
Abstract
Nanocolumnar thin films deposited at oblique angle (OA) by magnetron sputtering or evaporation often show common structural aspects when grown under equivalent geometrical conditions. This is the case of the column tilt angle as a function of the geometrical deposition arrangement, which coincides for some materials no matter the technique. This feature has usually been taken as a sign of a common type of growth, even though no other morphological aspects have been systematically compared. In this paper, a comparison between nanocolumnar Pt thin films grown at OA by evaporation and magnetron sputtering has been carried out, demonstrating the existence of profound differences in film density, columnar width or preferential crystalline texture, despite exhibiting the same nanocolumnar tilt. Moreover, the size distribution of voids and nanopores embedded in the nanocolumns has been specifically analyzed by means of two Positron Annihilation Spectroscopy techniques, demonstrating the existence of large variations depending on the preparation method. With the help of a growth model, these differences are discussed under the light of the atomistic processes present in evaporation and magnetron sputtering and, more specifically, on mobility processes triggered by the arrival of deposition atoms with relatively high kinetic energy.
Julio, 2025 · DOI: 10.1016/j.surfin.2025.106667
Reactividad de Sólidos
Plasma-flash sintering II: Flashing ZnO at room temperature using low AC voltage
Gil-González, E; Manchón-Gordón, AF; Perejón, A; Sánchez-Jiménez, PE; Pérez-Maqueda, LAJournal of the American Ceramic Society (2025) e70129 DOI: 10.1111/jace.70129
Abstract
In this study, we have advanced the plasma-flash sintering (PFS) technique by demonstrating the preparation of dense ZnO ceramics at room temperature using a moderate electric field of 250 V cm-1 under a low-pressure nitrogen atmosphere. This specific environment facilitates the sequential occurrence of plasma generation followed by the flash sintering event. Compared to traditional flash sintering technique, our approach significantly reduces both energy consumption and processing time, while eliminating the need for a furnace. Impedance spectroscopy confirms that ZnO ceramic produced via this method exhibits enhanced electrical conductivity. Hence, PFS is shown to be a potential tool for tuning the electrical properties of sintered materials at room temperature while boosting energy efficiency.
Julio, 2025 · DOI: 10.1111/jace.70129
Materiales Nanoestructurados y Microestructura
Microstructure and composition evolution of He charged solid-gas nanocomposite films of different matrix elements during thermal annealing in vacuum
Fernandez, A; de Haro, MCJ; Hufschmidt, D; Montes, O; Sauvage, T; Ferrer, FJ; Caillard, A; Brault, P; Thomann, ALScientific Reports, 15 (2025) 1 DOI: 10.1038/s41598-025-06889-8
Abstract
Sputtering of cobalt, silicon and zirconium in a helium magnetron discharge (MS) is reported as a bottom-up procedure to obtain He-charged films (i.e. He-4 and He-3 filled nanopores encapsulated in the matrix material). Composition and microstructural analyses are presented from ion beam analysis (IBA) and scanning and transmission electron microscopies (SEM and TEM). Helium desorption was investigated by IBA in a dedicated chamber for "in situ" thermal evolution in vacuum. The simultaneous recording of the helium and matrix-element signals shows different behaviors of the different matrix elements (i.e. Co, Si and Zr) and deposition conditions (i.e., DC or RF discharge modes and dynamic or quasistatic vacuum). Effusion, blistering, delamination and flaking have been observed for the different samples leading to the formation of nano-porous/nanostructured thin films. The methodology is being envisaged as a process for nanostructured thin-films fabrication with potential applications.
Julio, 2025 · DOI: 10.1038/s41598-025-06889-8
Materiales y Procesos Catalíticos de Interés Ambiental y Energético
Zn-MIL53(Fe) as an electro-Fenton catalyst: Application in organic pollutant degradation and pathogen inactivation
Terrón, D; Holgado-Vázquez, JP; Rosales, E; Sanromán, MA; Pazos, MSeparation and purification technology, 360 (2025) 130881 DOI: 10.1016/j.seppur.2024.130881
Abstract
In this study, the potential of a bimetallic Metal-Organic Framework Zn-MIL53(Fe) for electro-Fenton catalysis was evaluated. After the material characterisation, its catalytic activity was validated in Fenton reaction to degrade a model organic pollutant: Rhodamine B. After that, the evaluation of Zn-MIL53(Fe) as electro-Fenton catalyst was performed and improved outcomes were reached by electro-Fenton regarding anodic oxidation. Then, electro-Fenton treatment optimisation was carried out using response surface methodology assays considering different catalyst dosages (7.2-43.2 mg), current intensities (5-45 mA) and treatment time (30-90 min) in a volume of 0.1 L. Under optimal conditions, a degradation rate over 90 % for Fluoxetine and Sulfamethoxazole in synthetic wastewater was achieved within 90 min, using graphite sheet as anode and nickel foam as cathode (25 mA), with a catalyst dosage of 43.2 mg in a volume of 0.1 L. Additionally, its application in the pathogen inactivation was evaluated using different gram-negative and gram-positive bacteria. Complete eliminations of both types of bacteria were reached in 5 min using the optimal conditions. In the end, Zn-MIL53(Fe) was proven as a reusable material, capable of performing 3 complete cycles of electro-Fenton treatment for both types of pollutants bacteria and pharmaceuticals, which makes it a promising candidate for more efficient wastewater treatment applications which involve the Fenton reaction.
Julio, 2025 · DOI: 10.1016/j.seppur.2024.130881
Nanotecnología en Superficies y Plasma
Mechanisms of De-icing by Surface Rayleigh and Plate Lamb Acoustic Waves
Pandey, S; del Moral, J; Jacob, S; Montes, L; Gil-Rostra, J; Frechilla, A; Karimzadeh, A; Rico, VJ; Kantar, R; Kandelin, N; López-Santos, C; Koivuluoto, H; Angurel, L; Winkler, A; Borrás, A; González-Elipe, ARAdvanced Engineering Materials, 27 (2025) 2401820 DOI: 10.1002/adem.202401820
Abstract
Acoustic waves (AW) have recently emerged as an energy-efficient ice-removal procedure compatible with functional and industrial-relevant substrates. However, critical aspects at fundamental and experimental levels have yet to be disclosed to optimize their operational conditions. Identifying the processes and mechanisms by which different types of AWs induce de-icing are some of these issues. Herein, using model LiNbO3 systems and two types of interdigitated transducers, the e-icing and anti-icing efficiencies and mechanisms driven by Rayleigh surface acoustic waves (R-SAW) and Lamb waves with 120 and 510 mu m wavelengths, respectively, are analyzed. Through the experimental analysis of de-icing and active anti-icing processes and the finite element simulation of the AW generation, propagation, and interaction with small ice aggregates, it is disclosed that Lamb waves are more favorable than R-SAWs to induce de-icing and/or prevent the freezing of small ice droplets. Prospects for applications of this study are supported by proof of concept experiments, including de-icing in an icing wind tunnel, demonstrating that Lamb waves can efficiently remove ice layers covering large LN substrates. Results indicate that the de-icing mechanism may differ for Lamb waves or R-SAWs and that the wavelength must be considered as an important parameter for controlling the efficiency.
Julio, 2025 · DOI: 10.1002/adem.202401820
Materiales de Diseño para la Energía y Medioambiente - Reactividad de Sólidos
Microstructural control by freeze-casting of CaO architectures for improved and stable thermochemical energy storage performance
Amghar, N; Ivorra-Martínez, J; Perejón, A; Hanaor, D; Gurlo, A; Ramírez-Rico, J; Pérez-Maqueda, LA; Sánchez-Jiménez, PEJournal of Energy Storage, 125 (2025) 116681 DOI: 10.1016/j.est.2025.116681
Abstract
This study investigates the development of porous calcium-based monoliths via freeze-casting (FC) as a novel approach for thermochemical energy storage, particularly within the Calcium Looping (CaL) process. The freeze-casting technique enabled the fabrication of scaffolds with controlled porosity using polyvinyl alcohol (PVA) as a binder. Experimental results demonstrated that freeze-cast monoliths exhibited superior multicycle performance under various carbonation and calcination conditions. The FC-CaCO3 monolith achieved the highest residual conversion of 68.1 % under mild vacuum calcination conditions (780 degrees C, 0.1 bar CO2), significantly surpassing other configurations. Tests conducted in an inert atmosphere also yielded favorable results, with a conversion of 56.1 %, outperforming equivalent raw powder samples. The enhanced performance is attributed to improved CO2 interaction with the porous structure, mitigating sintering effects and preserving active surface area. Morphological observations by X-ray tomography and SEM confirmed limited particle sintering after multiple cycles, maintaining a reactive surface that supported consistent conversion rates. The pore size distribution of the material evolves upon cycling resulting in an increased microporosity, while the pore network maintains a low tortuosity (tau similar to 1.5-2.0). The addition of dopants such as ZrO2 and SiO2 did not enhance performance, as the monoliths' inherent structure provided sufficient stability. These findings highlight freeze-casting as a promising method for creating advanced porous materials suitable for energy storage applications.
Julio, 2025 · DOI: 10.1016/j.est.2025.116681
Materiales Coloidales
From the lab to the river: Bimetallic clinoptilolite photocatalyst for antibiotic-resistant bacteria and emerging contaminants removal
Prieto-Laria, P; Jiménez-Rodríguez, A; Ruiz-Salvador, AR; Canosa, I; Flores, A; Coll, Y; Borrego, K; Nuñez, NO; Alonso, E; Fernandez-Ibáñez, P; Farias, T; Ballesteros, MJournal of Environmental Chemical Engineering, 13 (2025) 116663. DOI: 10.1016/j.jece.2025.116663
Abstract
The presence of contaminants of emerging concern and antibiotic-resistant bacteria in aquatic environments is a major global challenge. Heterogeneous photo-Fenton-type treatments have proven effective; however, affordable and sustainable catalysts are needed to address real-world water treatment challenges. For the first time, we report the efficacy of a heterogeneous bimetallic Fe-Cu clinoptilolite catalyst, which can remove up to 29 contaminants of emerging concern (pharmaceuticals, metabolites, industrial products, herbicides and insecticides) at concentrations ranging from 6.38 to 2358 ng/L, and inactivate naturally occurring bacteria (Escherichia coli and total coliforms) from Guadaira River water (Spain) to the detection limit of 1 CFU/100 mL. Heterogeneous photo-Fenton (1 g/L of NZ-Fe-Cu catalyst, 2.9 mM H2O2 and visible light: 410-710 nm / 9 W/m2) was the selected method for treating real river water. The successful synthesis of the material was demonstrated by X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and scanning electron microscopy (SEM/ EDX). DR-UV-Vis measurements allowed the estimation of the optical band gap, which was used to evaluate the photocatalytic performance of the bimetallic zeolite. X-ray photoelectron spectroscopy (XPS) allowed the determination of the charge of iron and copper cations in the zeolite. The photocatalytic mechanism of this new material was investigated, including hydroxyl radical detection, reusability, and stability (Fe-and Cu-leaching tests). Complete inactivation of antibiotic-resistant bacteria Pseudomonas aeruginosa and Staphilococcus aureus (initial concentration approximate to 106 CFU/mL) without further regrowth for 24 h was achieved. These results highlight the potential of this new catalyst for the decontamination and disinfection of river water, supporting its suitability for reclaimed water in agricultural irrigation and its promising applicability in broader wastewater treatment applications.
Junio, 2025 · DOI: 10.1016/j.jece.2025.116663
Química de Superficies y Catálisis
Multifunctional Sustainable Carbon Catalyst for Glucose to Fructose Isomerization Reaction
Bounoukta, CE; Lara, B; Martín, GD; Domínguez, MI; Penkova, A; Ammari, F; Ivanova, S; Centeno, MAChemCatChem, 17 (2025) 12 DOI: 10.1002/cctc.202500440
Abstract
Two series of functionalized activated carbons have been prepared and used for the glucose to fructose isomerization reaction. Alkali earth chlorides and alkali halides have been chosen for the functionalization with the final goal to study the effect of cation and anion variation on isomerization activity. A part of the samples has been subjected to an activation procedure giving rise to the formation of new active sites of a distinct type and composition. The active site nature and density greatly influenced the reaction mechanism, giving rise to combined pathways catalyst with increased activity and fructose selectivity. The functionalization with MgCl2 resulted in a very stable and performant catalyst with an optimal fructose yield of 33% at 140 degrees C in only 20 min reaction time and during four cycles of reutilization.
Junio, 2025 · DOI: 10.1002/cctc.202500440
Química de Superficies y Catálisis
An efficient strategy for simultaneous gold deposition and obtention of hierarchical Au/TS-1 applied to liquid-phase propylene epoxidation
Centeno-Vega, I; González-Rubio, LJ; Megías-Sayago, C; Ivanova, SMaterials Advances, (2025) DOI: 10.1039/d5ma00203f
Abstract
A novel and straightforward one-step method has been developed for the controlled deposition of gold nanoparticles (AuNPs) with uniform diameters onto the titanosilicate (TS-1) zeolitic surface via a direct anionic exchange (DAE) approach. This innovative process simultaneously introduces auxiliary mesoporosity into the zeolite framework, overcoming critical limitations associated with traditional microporous catalysts, including diffusion constraints and rapid deactivation. The resultant hierarchical Au/TS-1 catalyst demonstrates remarkable enhancements in catalytic performance for the liquid-phase propylene epoxidation with H2O2 coupled with outstanding stability, a challenge that has long hindered the application of such materials. With its exceptional catalytic properties and simplified preparation procedure, this system represents a significant advancement in catalyst design. The developed material shows great potential for industrial applications and paves the way for the creation of next-generation catalysts essential for sustainable development.
Junio, 2025 · DOI: 10.1039/d5ma00203f
Fotocatálisis Heterogénea: Aplicaciones
Solar light-driven degradation of thiacloprid by polymer composites based on P-doped TiO2 as photoactive phase: Theoretical and experimental assessment of the reaction mechanism and degradation pathway
Rescigno, R; Summa, FF; Monaco, G; Iannece, P; Hidalgo, MC; Sacco, O; Vaiano, V; Venditto, VJournal of Environmental Chemical Engineering, 13 (2025) 116255. DOI: 10.1016/j.jece.2025.116255
Abstract
In this paper, visible light-activated phosphorus-doped TiO2 (P-TiO2) was used as a photoactive phase to prepare polymer composites for the degradation of the pesticide thiacloprid under direct sunlight irradiation. In particular, a monolithic composite aerogel, consisting of P-TiO2 embedded in syndiotactic polystyrene (PTsPS), and a composite polymer film, consisting of P-TiO2 immobilized on the surface of a Corona-pretreated polypropylene film (PT/PP), were prepared and characterized by XPS, TEM, XRD and N2 adsorption at-196 degrees C. The latter were then tested for the degradation of thiacloprid under solar irradiation. The best results were obtained using the PT/PP composite film, which allowed the total degradation of thiacloprid after 180 min of treatment. This performance remained almost unchanged even after several reuse cycles. The effect of pH and the concentration of bicarbonate (HCO3-), calcium (Ca2+), and chloride (Cl-) ions on the PT/PP film photocatalytic activity was also investigated. In addition, the photocatalytic activity of the PT/PP film remained high even in the presence of drinking water spiked with the target pollutant. Photocatalytic tests in the presence of scavenger molecules clarified that the hydroxyl radical is the main reactive oxygen species (ROS) responsible for the photodegradation mechanism of the target pollutant with P-TiO2, even if a possible role of superoxide cannot be excluded. Finally, DFT studies and ESI(+)-FT-ICR-MS analysis were conducted to formulate a hypothesis on the degradation pathway, identifying possible reaction intermediates.
Junio, 2025 · DOI: 10.1016/j.jece.2025.116255
Química de Superficies y Catálisis
Exploring the Synergistic Interaction between Nickel- and Ruthenium-Based Catalysts for Carbon Dioxide Methanation Reaction
de Miguel, JCN; Bobadilla, LF; Centeno, MA; Laguna, OH; Odriozola, JAACS Sustainable Resource Management, 13 (2025) 8532-8545 DOI: 10.1021/acssuschemeng.4c10845
Abstract
The utilization of nickel-ruthenium as bimetallic catalysts is widely recognized for its efficacy in enhancing the catalytic performance in the carbon dioxide methanation reaction. The present study focuses on the synergistic interplay between both active sites and their respective roles in the reaction mechanism through operando DRIFT-MS analysis. Findings reveal that the bimetallic catalyst is constituted by NiRu nanocrystallites with Ru atoms segregated at defect edge/corner sites, promoting the dissociation of carbon dioxide and the formation of CH x species. Furthermore, Ni atoms predominantly occupy facets or terrace sites, characterized by higher electron density conducive to carbon monoxide hydrogenation to methane. This research offers a comprehensive elucidation of the carbon dioxide methanation mechanism within a bimetallic system and underscores the efficacy of the operando methodology in advancing our fundamental understanding of heterogeneous catalysis.
Junio, 2025 · DOI: 10.1021/acssuschemeng.4c10845
Química de Superficies y Catálisis
Upcycling textile derived microplastics waste collected from washer and dryers to carbonaceous products using hydrothermal carbonization
Parrilla-Lahoz, S; Jiménez-Páez, E; Masteghin, MG; Pawlak, JJ; Venditti, RA; Bird, R; Servin, P; Odriozola, JA; Reina, TR; Duyar, MSWaste Management, 200 (2025) 114740 DOI: 10.1016/j.wasman.2025.114740
Abstract
Microplastics are an emerging pollutant of concern. Many microplastics in the waters arise from washing synthetic textiles in residential and commercial washing machines. The present research evaluated the upcycling of this waste to carbon materials by hydrothermal carbonization. Real microfiber waste was collected using clothes washer and dryer microfilters. Via temperature and residence time screening (200 degrees C, 250 degrees C, 300 degrees C and 1 h, 4 h, 8 h) two temperatures of interest were determined (250 degrees C and 300 degrees C) for hydrothermal carbonization, for a residence time of 4 h. The results obtained in this research demonstrated that by varying the reaction conditions carbon production can be tailored, producing amorphous carbon or graphene/graphite. To this end, Raman spectroscopy results indicated the production of carbon nanomaterials; smaller particle sizes were detected after 250 degrees C-4h and 300 degrees C-4h treatments, (29.6 nm and 33.1 nm, respectively). Transforming microfibers into useful carbon nanoparticles via hydrothermal carbonization prolongs their lifecycle and mitigates environmental pollution. This process is an intriguing method of incorporating textile residue (microfibers) into the circular economy, where resources are perpetually recycled, and waste is avoided.
Junio, 2025 · DOI: 10.1016/j.wasman.2025.114740
Fotocatálisis Heterogénea: Aplicaciones
Treatment of Dairy Industry Wastewater and Crop Irrigation Water Using AgBr-Coupled Photocatalysts
Hernández-Laverde, M; Murcia, JJ; Navío, JA; Hidalgo, MC; Puga, FNanomaterials, 15 (2025) 848 DOI: 10.3390/nano15110848
Abstract
This work describes the application of three different AgBr heterojunctions with TiO2, SnO2 and WO3 in the treatment of two water sources: wastewater from a dairy industry facility (WDI) and water from a polluted river (WPR). All heterojunctions were widely characterised, and it was observed that the physicochemical properties of all the coupled materials were similar; however, the highest elimination of Enterobacteriaceae (>90%) was obtained with the AgBr/WO3(20%) photocatalyst in WDI. Under the same conditions, with this photocatalyst, the complete removal of bacteria (i.e., E. coli, total coliforms and other Enterobacteriaceae) was achieved in WPR. The chlorides, hardness and colour in the two water samples decreased after photocatalytic treatment with all the coupled materials. However, nitrate levels and chemical oxygen demand increased due to the possible formation of intermediary species from the photodegradation of organic pollutants and the release of metabolic intermediates from bacterial degradation during the photocatalytic process. Overall, heterogeneous photocatalysis based on AgBr-coupled materials shows potential as a tertiary treatment for WDI and for the purification of vegetable irrigation water. However, it is still important to consider the need to optimise the integrity of photocatalytic materials in order to maintain their bactericidal effectiveness through continuous reuse.
Junio, 2025 · DOI: 10.3390/nano15110848
Reactividad de Sólidos
Piezoelectric and Dielectric Response of BaTiO3/PVDF-TrFE Composites with High β-Phase Content
Otero, A; Sayagués, MJ; Romero, FJ; Gotor, FJ; Moriche, RACS Applied Polymer Materials, 7 (2025) 7848-7858 DOI: 10.1021/acsapm.5c00620
Abstract
The search for flexible piezoelectric materials to build adaptable sensors, electronics, and nanogenerators has become a key area of interest. The addition of piezoceramic particles to piezoelectric polymers, such as the copolymer poly(vinylidene fluoride-trifluoroethylene) (PVDF-TrFE), is one of the strategies used to enhance the piezoelectric response. In this work, the effect of BaTiO3 content on the beta-phase formation, crystallization, and piezoelectric and dielectric properties of the polymer-based composites is investigated. High-energy ball milling was used as an effective, greener technique to achieve well-dispersed mixtures compared to those obtained using organic solvents. During the dispersion process, amorphization and reduction of the crystalline domain size occur. After compression molding and postprocessing, the crystallinity was recovered and was strongly dependent on the filler content. Although significant differences in the beta-phase fraction were not observed, conformational defects are induced with high BaTiO3 contents. The interlayer distances became smaller due to the presence of the ceramic particles after compression molding and remained almost unchanged after postprocessing. For the composites, the minimum voltage required to obtain a measurable piezoelectric coefficient (d 33 ) was significantly reduced compared to neat PVDF-TrFE, even for low contents, which is key for real applications. Three different piezoelectric behaviors were found depending on the BaTiO3 fraction. For composites with 40 vol %, where both matrix and filler contribute to the overall piezoelectric response, the use of a two-step poling method induced a synergistic effect with an increase in d 33 of similar to 180%. However, the relaxation of the ceramic contribution after 24 h returns the value of d 33 to that obtained by applying a one-step poling strategy.
Junio, 2025 · DOI: 10.1021/acsapm.5c00620
Materiales Ópticos Multifuncionales
Room-temperature cavity exciton-polariton condensation in perovskite quantum dots
Georgakilas, I.; Tiede, D; Urbonas, D; Mirek, R; Bujalance, C; Caliò, L; Oddi, V; Tao, R; Dirin, DN; Rainò, G; Boehme, SC; Galisteo-López, JF; Mahrt, RF; Kovalenko, MV; Míguez, H; Stöferle, TNature Commications, 16 (2025) 5228 DOI: 10.1038/s41467-025-60553-3
Abstract
The exploitation of the strong light-matter coupling regime and exciton-polariton condensates has emerged as a compelling approach to introduce strong interactions and nonlinearities into numerous photonic applications. The use of colloidal semiconductor quantum dots with strong three-dimensional confinement as the active material in optical microcavities would be highly advantageous due to their versatile structural and compositional tunability and wet-chemical processability, as well as potentially enhanced, confinement-induced polaritonic interactions. Yet, to date, exciton-polariton condensation in a microcavity has neither been achieved with epitaxial nor with colloidal quantum dots. Here, we demonstrate room-temperature polariton condensation in a thin film of monodisperse, colloidal CsPbBr3 quantum dots, placed in a tunable optical resonator with a Gaussian-shaped deformation serving as wavelength-scale potential well for polaritons. The onset of polariton condensation under pulsed optical excitation is manifested in emission by its characteristic superlinear intensity dependence, reduced linewidth, blueshift, and extended temporal coherence.
Junio, 2025 · DOI: 10.1038/s41467-025-60553-3
Nanotecnología en Superficies y Plasma
In situ growing of ZIF-8 crystals into TiO2 micro columnar films
Romero-Guerrero, JJ; Moscoso, FG; Hamad, S; Moreno, GP; Rico, V; Quero, AB; Lopes-Costa, T; Pedrosa, JMNext Materials, 6 (2025) 100406 DOI: 10.1016/j.nxmate.2024.100406
Abstract
This study proposes a fast and simple method for the in situ growth of metal-organic frameworks (MOFs) on metal oxide substrates as an alternative to the traditional approaches of using gold substrates and self-assembled monolayers (SAMs). As a case study, zeolitic imidazolate framework 8 (ZIF-8) crystals were grown in micro columnar TiO2 films through simple alternate and successive immersions of the TiO2 films into solutions containing the MOFs precursors. The growth process of the MOF crystals in the interstitial spaces between the TiO2 columns was investigated by varying the metal-to-ligand ratio (1:2, 1:4, and 1:8) and by employing modulating agents such as triethylamine. It was found that the optimal deposition of ZIF-8 occurred when using a higher excess of ligand and the addition of triethylamine after a controlled number of immersion cycles. These results were obtained by using glancing angle X-ray diffraction (GAXRD) and scanning electron microscopy-energy-dispersive X-ray spectroscopy (SEM-EDS) as characterization techniques. Additionally, a density functional theory (DFT) study as well as Fourier-transform infrared spectroscopy (FTIR) and GAXRD experiments were conducted to elucidate the nucleation process. It was concluded that the starting point is the formation of a covalent bond between the Zn cations and the TiO2 on the metal oxide surface after immersion of the film into a Zinc (II) nitrate solution, allowing for the formation of MOF nuclei once the film is subsequently immersed in the 2-methylimidazole solution. The results demonstrate the feasibility of in situ growth of MOF crystals onto metal oxide structures by a layer-by-layer strategy, offering a promising alternative to conventional methods.
Junio, 2025 · DOI: 10.1016/j.nxmate.2024.100406
Reactividad de Sólidos
Production of Barium Sulfide from Low-Grade Barite Ores
Santander, M; Guzmán, D; Navea, M; Valderrama, L; Pérez-Maqueda, L; Cárdenas, EMinerals, 15 (2025) 6 DOI: 10.3390/min15060646
Abstract
The manufacture of barium sulfide or barium salts (BaS, BaCl2, Ba (OH)(2), among others) requires high-purity barite ores (>90%). In this study, a new method to produce barium sulfide from low-grade barite ores (60% purity) is proposed. The method involves gravitational concentration of barite ore on a shaking table followed by mechanical activation of the barite concentrate with metallurgical coke in a ball mill. The mechanically activated mixture undergoes carbothermic reduction with an argon flow, resulting in the conversion of barite concentrate into barium sulfide. Gravitational concentration studies conducted using a shaking table demonstrated that, upon optimizing key operational parameters-namely, the wash-water flow rate, length, stroke frequency, the splitter positions of the concentrate, middlings, and tailings-a barite concentrate with a purity exceeding 95% BaSO4 was successfully achieved. Mechanical activation of the barite/coal mixture lowered the initial temperature of the carbothermic reduction from 1100 K to 990 K, enabling complete conversion of barite to BaS, as confirmed by thermogravimetric curves and XRD analysis. Furthermore, the activation energy during the carbothermic reduction ranged from 300 to 500 kJ/mol, suggesting a complex reduction process of barite with metallurgical coke that is difficult to represent by a single reaction.
Junio, 2025 · DOI: 10.3390/min15060646
Materiales de Diseño para la Energía y Medioambiente
Characterization of Coffee Waste-Based Biopolymer Composite Blends for Packaging Development
Hernández-López, G; Barrera-Necha, LL (Barrera-Necha, Laura Leticia) [1] ; Bautista-Baños, S; Hernández-López, M; Pérez-Camacho, O; Benítez-Jiménez, JJ; Acosta-Rodríguez, JL; Correa-Pacheco, ZNFoods, 14 (2025) 11 DOI: 10.3390/foods14111991
Abstract
In recent years, coffee waste by-products have been incorporated into polymer blends to reduce environmental pollution. In this study, coffee parchment (CP) was incorporated into biodegradable polylactic acid (PLA) and poly (butylene adipate-co-terephthalate) (PBAT) polymer blends to prepare ribbons through the extrusion process. Extracted green coffee bean oil (CO) was used as a plasticizer, and CP was used as a filler with and without functionalization. A solution of chitosan nanoparticles (ChNp) as a coating was applied to the ribbons. For the raw material, proximal analysis of the CP showed cellulose and lignin contents of 53.09 +/- 3.42% and 23.60 +/- 1.74%, respectively. The morphology of the blends was observed via scanning electron microscopy (SEM). Thermogravimetric analysis (TGA) showed an increase in the ribbons' thermal stability with the functionalization. The results of differential scanning calorimetry (DSC) revealed better miscibility for the functionalized samples. The mechanical properties showed that with CP incorporation into the blends and with the ChNp coating, the Young's modulus and the tensile strength decreased with no significant changes in the elongation at break. This work highlights the potential of reusing different by-products from the coffee industry, such as coffee oil from green beans and coffee parchment as a filler, and incorporating them into PLA PBAT biodegradable polymer blend ribbons with a nanostructured antimicrobial coating based on chitosan for future applications in food packaging.
Junio, 2025 · DOI: 10.3390/foods14111991
Materiales Semiconductores para la Sostenibilidad
Interfacial Chemistry Limits the Stability of Deep Blue Perovskite LEDs Revealed by Operando Characterization
Mirabelli, AJ; Kammlander, B; Lu, Y; Varma, RM; Gu, QC; Radetzky, K; Selby, TA; Liu, TJ; Riva, S; Wei, ZM; Lee, TL; Rawle, J; Rensmo, H; Anaya, M; Cappel, UB; Stranks, SDACS Energy Letters, 10 (2025) 3533-3543 DOI: 10.1021/acsenergylett.5c00989
Abstract
To commercialize lead halide perovskites as light-emitting diodes (LEDs), the operational device lifetime needs to be drastically improved. For this to be achieved, an understanding of degradation behavior under bias is crucial. Herein, we perform operando measurements of the structural, chemical, and electronic changes using synchrotron-based grazing-incidence wide-angle X-ray scattering and hard X-ray photoelectron spectroscopy on full-stack deep blue mixed bromide/chloride lead halide perovskite LEDs. While a clear drop in optoelectronic performance is recorded under electrical bias, the accompanying X-ray scattering data reveals only minor changes in structural properties. However, photoelectron spectroscopy reveals substantial chemical changes at the electron-injecting interface after bias is applied, including the formation of unwanted metallic lead and a new chlorine species that is not in the perovskite structure. These operando approaches give important structural and interfacial perspectives to reveal the degradation mechanisms in these LEDs and highlight the need to address the top electron-injecting interface to realize step-changes in operational stability.
Junio, 2025 · DOI: 10.1021/acsenergylett.5c00989
Materiales Coloidales
A hypervalent metal MOF catalyst as an avenue to go beyond heterogeneous Fenton-like processes for organic contaminant removal in water
Santos Juanes, L; Rodriguez-Sanchez, N; Balestra, SRG; Núñez, NO; Arques, A; Ruiz-Salvador, AR; Ballesteros, MMaterials Advances, 6 (2025) 3612-3621 DOI: 10.1039/d4ma01217h
Abstract
Metal-organic frameworks (MOFs) have recently been proposed as a plausible solution to the pressing issue of water scarcity and as a means of remediating contaminated water bodies. In light-assisted water treatment, they have so far only been exploited via the hydroxyl radical route, through Fenton-like processes. A new avenue is introduced here by the biomimetic conceptual design of MOF bearing hypervalent metal atoms for photocatalytic water treatment. We report a zeolitic imidazole framework (ZIF) material doped with iron (Fe-ZIF-7-III; UPO-4) synthesized via a novel mild treatment to stabilize photoactive hypervalent ferryl ions for the first time in a MOF for water treatment. The successful synthesis of the 2D material and the adequate incorporation of iron into the structure were demonstrated using X-ray diffraction (XRD), Fourier-transform infrared (FTIR) spectroscopy, and scanning electron microscopy (SEM). A simulation study analyzed the structure and stability of the Fe-ZIF-7-III material as well as the involvement of ferryl ions in the photo-Fenton-type process. Furthermore, the calculated band gap of this material shows its viability for use in photocatalysis using sunlight. This was confirmed by evaluating the photodegradation of caffeine, a model pollutant in water, without the assistance of hydroxyl radicals as indicated by a scavenger test. The recyclability test revealed that Fe-ZIF-7-III could be used continuously with effective catalytic activity, thus opening the door to the field of studying hypervalent metal MOFs not yet explored in water treatment.
Junio, 2025 · DOI: 10.1039/d4ma01217h
Materiales de Diseño para la Energía y Medioambiente
Elucidating the modes of incorporation of the ferulic acid amides feruloyltyramine and feruloyloctopamine into the lignin-suberin fraction of potato periderms
Del Rio, JC; Ralph, J; Benítez, JJ; Guzman-Puyol, S; Heredia-Guerrero, JA; Rencoret, JInternational Journal of Biological Macromolecules, 319 (2025) 145570 DOI: 10.1016/j.ijbiomac.2025.145570
Abstract
Ferulic acid amides are naturally present in the cell walls of potato (Solanum tuberosum) periderms. In this study, we investigated their modes of incorporation into the periderm cell wall polymers. A lignin/suberin-enriched fraction was isolated and analyzed by GPC, DFRC, and 2D-NMR. The analyses revealed that the lignin domain of this fraction was predominantly composed of G-lignin units, with an H:G:S ratio of 2:70:28 (S/G ratio of 0.40). More importantly, the data also indicated the presence of two ferulic acid amides, feruloyltyramine and feruloyloctopamine, that are incorporated into the lignin/suberin structure of potato periderms through a variety of linkages, including 8-O-4' and 4-O-beta' ether linkages, as well as 8-5' linkages forming a phenylcoumaran structure involving the ferulate moiety. Although the phenolic groups of the tyramine and octopamine moieties could theoretically undergo oxidation, potentially creating additional sites for radical coupling, our research indicates that these groups remain predominantly as free phenolic entities that do not participate in radical coupling. On the other hand, all the phenolic groups of the ferulate moieties are bound through ether linkages reinforcing the conclusion that the feruloyltyramine and feruloyloctopamine moieties are linked to lignin/suberin within the cell wall via radical coupling reactions.
Junio, 2025 · DOI: 10.1016/j.ijbiomac.2025.145570
Materiales Semiconductores para la Sostenibilidad
Compositional Gradient of Mixed Halide 2D Perovskite Interface Boosts Outdoor Stability of Highly Efficient Perovskite Solar Cells
Degani, M; Pallotta, R; Pica, G; Karimipour, M; Mirabelli, A; Frohna, K; Anaya, M; Xu, TY; Ma, CQ; Stranks, SD; Camtù, ML; Grancini, GAdvanced Energy Materials, 15 (2025) 17 DOI: 10.1002/aenm.202404469
Abstract
Interface engineering using self-assembled 2D perovskite interfaces is a consolidated route to efficient and durable perovskite solar cells. Whether the 2D perovskite forms a homogeneous conformal layer or is heterogeneously distributed on the surface, interface defects are passivated, leading to a general improvement in the device's open circuit voltage (VOC) and stability. Here, an innovative strategy is developed for manipulating the composition of the 2D/3D perovskite interface that results in the formation of a gradient halide distribution, which extends from the surface to the bulk. The use of a bromide-based 2D perovskite triggers a progressive Br/I exchange, affecting not only the surface but also the perovskite underneath. As a result, not only the device VOC improve, as expected, but also the photogenerated current is boosted, leading to a device efficiency of up to 24.4%. Such mixed halide gradient effectively passivates surface and bulk defects making the perovskite active layer more efficient and robust, as demonstrated by the superior device stability showing zero losses in performances upon 36 days (more than 800 h) test in outdoor conditions, those ones relevant for a marketable product.
Mayo, 2025 · DOI: 10.1002/aenm.202404469
Química de Superficies y Catálisis
Bio-aromatics: Revolutionizing the integrated biomass and plastic waste valorization for high-value aromatic hydrocarbons via bifunctional catalytic pathways of bio-syngas conversion
Saif, M; Blay-Roger, R; Nawaz, MA; Bobadilla, LF; Ramírez-Reina, T; Odriozola, JABiomass & Bioenergy, 196 (2025) 107736 DOI: 10.1016/j.biombioe.2025.107736
Abstract
Aromatic hydrocarbons play a pivotal role in various industrial applications, serving as essential building blocks to produce polymers, resins, and specialty chemicals. Traditionally, their synthesis has been reliant on fossil fuels, raising concerns about environmental sustainability and resource depletion. However, recent advancements in the field have paved the way for a paradigm shift, with a focus on biomass-derived synthesis gas as a renewable and environmentally friendly feedstock. This review explores innovative shortcuts in the synthesis of aromatic hydrocarbons, a key area of research that holds promise for a more sustainable and efficient future. As we delve into the intricacies of biomass-derived synthesis gas conversion, we will examine breakthroughs in catalyst development, process optimization, and integrated approaches. By scrutinizing these advancements, we aim to provide a comprehensive overview of the current state of the art, highlighting both challenges and opportunities for further exploration. The urgency of addressing environmental concerns and the growing demand for renewable alternatives underscore the importance of reevaluating the methodologies. The unique characteristics of biomass-derived synthesis gas coupled with co-gasification processes present an intriguing avenue for redefining the landscape of aromatic hydrocarbon synthesis. Through this exploration, we seek to unravel the complexities of these innovative shortcuts, offering insights that may contribute to a more sustainable and greener future for the chemical industry.
Mayo, 2025 · DOI: 10.1016/j.biombioe.2025.107736
Reactividad de Sólidos
Phase dependence of the thermal memory effect in polycrystalline ribbon and bulk Ni55Fe19Ga26 Heusler alloys
Vidal-Crespo, A; Manchón-Gordón, AF; Martín-Olalla, JM; Romero, FJ; Ipus, JJ; Gallardo, MC; Blázquez, JS; Conde, CFIntermetallics, 180 (2025) 108695. DOI: 10.1016/j.intermet.2025.108695
Abstract
The thermal memory effect, TME, has been studied in Ni55Fe19Ga26 shape memory alloys, fabricated as ribbons via melt-spinning and as pellets via arc-melting, to evaluate its dependence on the martensitic structure and the macrostructure of the samples. When the reverse martensitic transformation is interrupted, a kinetic delay in the subsequent complete transformation is only evident in the ribbon samples, where the 14M modulated structure is the dominant phase. In contrast, degradation of the modulated structure or the presence of the γ phase significantly reduces the observed TME. In such cases, the magnitude of the TME approaches the detection limits of commercial calorimeters, and only high-resolution calorimeter at very low heating rate (40 mK h−1) can show the effect. Following the kinetic arrest and subsequent cooling, the reverse martensitic transformation was completed at several heating rates to confirm the athermal nature of the phenomenon.
Mayo, 2025 · DOI: 10.1016/j.intermet.2025.108695
Materiales y Procesos Catalíticos de Interés Ambiental y Energético
Unveiling the Potential of a Cobalt-Based Metal-Organic Framework in Carbodiimide Synthesis
Verdoorn, DS; Zuliani, A; Ranjan, P; Holgado, JP; Khiar, N; Saya, JM; Carrillo-Carrión, C; Maes, BUW; Orru, RVAAdvanced Synthesis & Catalysis, 367 (2025) 9 DOI: 10.1002/adsc.202401540
Abstract
The synthesis of carbodiimides via nitrene transfer to isocyanides has garnered significant attention in recent years. However, this reaction predominantly relies on homogeneous catalytic systems with high catalyst loadings. In this study, we employed ZIF-67 MOF as a heterogeneous catalyst for carbodiimide synthesis and conducted an in-depth analysis of its stability. Our findings reveal the non-innocent role of catalyst leaching, demonstrating that even as little as 0.04 mol% of leached cobalt species is sufficient to catalyze this reaction. This result is in contrast with previous reports, where 5-10 mol% of homogeneous cobalt-loading is required. Furthermore, this study highlights that lower catalyst loadings are more efficient, particularly in cases where isocyanides exhibit limited stability.
Mayo, 2025 · DOI: 10.1002/adsc.202401540
Materiales Nanoestructurados y Microestructura
Comparing 3He content in magnetron sputtered and implanted targets for nuclear studies
Pilotto, E; Ferrer, FJ; Akhmadaliev, S; Fernandez, A; Gadea, A; Camacho, JG; Hufschmidt, D; de Haro, MCJ; Masha, E; Munnik, F; Osswald, M; Piatti, D; Skowronski, J; Turkat, S; Valiente-Dobón, JJEuropean Physical Journal A DOI: 10.1140/epja/s10050-025-01590-w
Abstract
He-3 targets are a valuable tool in nuclear physics, particularly for studying nuclear structure and dynamics via direct reactions in inverse kinematics. However, they are often prone to degradation under intense beam irradiation and have insufficient He-3 content for use with lowintensity exotic beams. In a recent AGATA experiment at LNL, designed to study the astrophysically relevant lifetime of a O-15 excited state, two types of He-3 targets were tested. One was produced using ion implantation and the other with a novel magnetron sputtering technique, in both cases on Au substrates. Following irradiation with a stable O-16 beam, they were characterized using Nuclear Reaction Analysis (NRA) and Elastic Recoil Detection Analysis (ERDA). Results demonstrated that, under the here used fabrication conditions, sputtered targets present a higher He-3 content, while implanted ones exhibit thinner profiles. This highlights the possibilities and complementarity of these targets, suggesting their tailored use for future experimental campaigns.
Mayo, 2025 · DOI: 10.1140/epja/s10050-025-01590-w
Materiales de Diseño para la Energía y Medioambiente
Plasticized cellulose bioplastics with beeswax for the fabrication of multifunctional, biodegradable active food packaging
Florido-Moreno, P; Benítez, JJ; González-Buesa, J; Porras-Vázquez, JM; Hierrezuelo, J; Grifé-Ruiz, M; Romero, D; Athanassiou, A; Heredia-Guerrero, JA; Guzmán-Puyol, SFood Hydrocolloids, 162 (2025) 110933 DOI: 10.1016/j.foodhyd.2024.110933
Abstract
Plasticized cellulose bioplastics with antioxidant and antimicrobial properties were prepared by blending cellulose and glycerol in a mixture of trifluoroacetic acid and trifluoroacetic anhydride, adding a solution of beeswax in chloroform, and subsequent drop-casting. Optical, chemical, structural, mechanical, thermal, and hydrodynamic properties were fully characterized. In addition, the biodegradability in seawater was investigated by determination of the biological oxygen demand. The incorporation of beeswax ruled out the transparency and UV blocking, modified the main mechanical parameters, and improved the thermal stability and the antioxidant capacity, as well as the hydrodynamic and barrier properties. In general, these features were comparable to those of common petroleum-based food packaging plastics. Such changes were explained by the incorporation of beeswax into the polymer matrix, as determined by infrared spectroscopy and X-ray diffraction. These cellulosebeeswax bioplastics were evaluated as viable food packaging materials by determination of the overall migration by using Tenax (R) as a dry food simulant, oxygen permeability at different relative humidities, measurement of antimicrobial activity against Escherichia coli and Bacillus cereus, and through preservation of fresh-cut pear slices, showing results similar to those obtained by using low-density polyethylene.
Mayo, 2025 · DOI: 10.1016/j.foodhyd.2024.110933
Materiales Avanzados
Valorisation of rice husk ash as an activator in the preparation of alkali-activated cements based on electric arc furnace slag
Muñoz-Castillo, A; Sánchez-Soto, PJ; Eliche-Quesada, DArchives of Civil and Mechanical Engineering, 25 (2025) 155 DOI: 10.1007/s43452-025-01209-3
Abstract
Rice husk ash (RHA) was employed as a silica source to produce an alternative sodium silicate solution through the dissolution of varying quantities of RHA in an 8 M NaOH solution. The solution was employed in the production of alkali-activated cements based on electric arc furnace slag (EAFS). Solutions were prepared with varying activator modules (Ms, molar ratio SiO2/Na2O) of 0.60, 0.85, 1.00, and 1.15. As control samples, slags were activated with 8 M NaOH (Ms = 0.0) and with 8 M NaOH in conjunction with commercial sodium silicate (Ms = 1.0). Mechanical, physical, mineralogical (XRD, FTIR), and microstructural (SEM/EDS) tests were conducted to characterize the obtained pastes. The results of the FTIR and SEM analyses indicated that the SiO2/Na2O ratio exerts a significant influence on the reaction products formed. At Ms values higher than 0.85, the predominant reaction product was observed to be a more cross-linked hybrid gel (N,C)-A-S-H. Lower modules resulted in the predominant formation of C-A-S-H gel and a more porous structure with lower mechanical properties. Pastes activated with the alternative RHA solution and Ms = 1.0 exhibited a composition, microstructure, and strength that was similar to or superior to those prepared with conventional commercial activators.
Mayo, 2025 · DOI: 10.1007/s43452-025-01209-3
Nanotecnología en Superficies y Plasma
Atomic-Scale Modeling of Water and Ice Behavior on Vibrating Surfaces: Toward the Design of Surface Acoustic Wave Anti-icing and Deicing Systems
Wejrzanowski, T; Jacob, S; Winkler, A; Delmoral, J; Borrás, A; González-Elipe, ARLangmuir, 41 (2025) 11293-11306 DOI: 10.1021/acs.langmuir.4c04330
Abstract
Within these studies, atomic-scale molecular dynamics simulations have been performed to analyze the behavior of water droplets and ice clusters on hydrophilic and hydrophobic surfaces subjected to high-frequency vibrations. The methodology applied herewith aimed at understanding the phenomena governing the anti-icing and deicing process enabled by surface acoustic waves (SAWs). The complex wave propagation was simplified by in-plane and out-of-plane substrate vibrations, which are relevant to the individual longitudinal and transverse components of SAWs. Since the efficiency of such an active system depends on the energy transfer from the vibrating substrate to water or ice, the agents influencing such transfer as well as the accompanying phenomena were studied in detail. Apart from the polarization of the substrate vibrations (in-plane/out-of-plane), the amplitude and frequency of these vibrations were analyzed through atomic-scale modeling. Further, the surface wettability effect was introduced as a critical factor within the simulation of water or ice sitting on the vibrating substrate. The results of these studies allow identification of the different phenomena responsible for water and ice removal from vibrating surfaces depending on the wave amplitude and frequency. The importance of substrate wetting for anti-icing and deicing has also been analyzed and discussed concerning the future design and optimization of SAW-based systems.
Mayo, 2025 · DOI: 10.1021/acs.langmuir.4c04330
Fotocatálisis Heterogénea: Aplicaciones
Towards the effective removal of environmental strains of bacteria from real wastewater by heterostructured photocatalysts
Larumbe, N; Moles, S; Hidalgo, MC; Rubio, E; Goñi, P; Mosteo, RCatalysis Today, 449 (2025) 115197 DOI: 10.1016/j.cattod.2025.115197
Abstract
Access to clean water is crucial for human health, yet microbial contamination poses significant challenges. This study investigates the effectiveness of novel photocatalytic catalysts: heterostructured TiO2/AgBr and faceted titanium dioxide, for microbial inactivation under ultraviolet and visible light. Both catalysts were synthesized and characterized. Performance was evaluated using real wastewater samples and saline solutions, targeting gram-positive and gram-negative bacteria. The experimental approach included testing the photocatalysts with and without the addition of peroxydisulfate to assess its impact on inactivation effectiveness. Results indicated that the TiO2/AgBr catalyst outperformed the faceted titanium dioxide one due to its superior visible light absorption and enhanced charge separation, achieving complete inactivation of environmental strains of Escherichia coli and significant inactivation for Enterococcus faecalis in real wastewater. The inclusion of peroxodisulfate with TiO2/AgBr significantly improved inactivation rates, demonstrating a synergistic effect. Regarding wastewater composition, the treatment achieves a significant COD removal while the rest of studied parameters remain stable. Both catalysts effectively prevented bacterial regrowth for up to 48 hours, underscoring its long-term efficacy. Overall, these findings highlight the potential application of TiO2/AgBr combined with peroxodisulfate as an effective strategy for microbial inactivation, contributing to the advancement in water treatment technologies across real environmental contexts.
Abril, 2025 · DOI: 10.1016/j.cattod.2025.115197
Nanotecnología en Superficies y Plasma - Materiales Ópticos Multifuncionales
Multidimensional nanoarchitectures for improved indoor light harvesting in dye-sensitized solar cells
Castillo-Seoane, J; Contreras-Bernal, L; Riquelme, AJ; Fauvel, S; Kervella, Y; Gil-Rostra, J; Lozano, G; Barranco, A; Demadrille, R; Sánchez-Valencia, JR; Borrás, AMaterials Today Energy, 49 (2025) 101851 DOI: 10.1016/j.mtener.2025.101851
Abstract
Dye Sensitized Solar Cells (DSSCs) have recently gained renewed interest for their potential in indoor light harvesting and powering wireless devices. However, to fully exploit their potential, crucial aspects require further attention, in particular, the improvement of spectral compatibility and low-light harvesting mechanisms, as well as the development of efficient photoanodes through high-yield scalable methods. In this article, we propose the use of nanocomposite photoanodes integrating mesoporous TiO2 nanoparticles, ITO nanotubes (NT), and anatase TiO2 shells (ITO@TiO2 NT) prepared by step-by-step method relying on mild temperature conditions and avoiding toxic precursors. These photoanodes outperform previous attempts to implement low-dimensional ITO and ITO@TiO2 nanowires and nanotubes for outdoor light conversion, demonstrating a power conversion efficiency under low artificial light intensity of 24 % for at 0.014 mW cm-2, a 166 % increase compared to the conventional architectures. Advanced microstructural, optical, and electrochemical characterizations have revealed that the strong scattering effect of the light in the visible range coupled with enhanced charge collection at low-intensity illumination are the essential mechanisms responsible for such enhanced energy conversion. Remarkably, our devices retain up to 90 % of the normal incidence efficiency even under glancing illumination, while conventional reference devices retain only 30 %.
Abril, 2025 · DOI: 10.1016/j.mtener.2025.101851
Materiales de Diseño para la Energía y Medioambiente
Triphenyl Acetic Glyceroate as a sustainable multifunctional additive for developing transparent, biodegradable, and flexible polylactide green alternative to polyethylene-based films for food packaging
Ferri, M; Lenzi, L; Degli Esposti, M; Martellosio, L; Benítez, JJ; Hierrezuelo, J; Grifé-Ruiz, M; Romero, D; Guzmán-Puyol, S; Heredia-Guerrero, JAChemical Engineering Journal, 508 (2025) 160887 DOI: 10.1016/j.cej.2025.160887
Abstract
Polylactide-based materials represent a promising bio-based alternative to traditional food packaging polymers. However, their widespread use is still limited due to significant drawbacks, such as brittleness, high gas permeability, and biodegradability only under specific conditions. This work introduces fully bio-based Triphenyl Acetic Glyceroate (TPAG), synthesized through a solvent-free and mild conditions valorization of glycerol and phenylacetic acid, as a polylactide (PLA) plasticizer and multiple property-enhancer for extending foodstuff shelf-life. After optimizing TPAG synthesis and confirming its structure through FT-IR and NMR, PLA-based films are prepared at different TPAG contents (0, 5, 10, and 20 phr). Detailed investigations of the films' thermal, mechanical, optical, hydrodynamic, barrier, antioxidant, antibacterial, migration, and biodegradation characteristics are carried out. TPAG shows a significant plasticizing effect while maintaining high transparency and improving PLA's antioxidant, antibacterial and UV-blocking activities. Moreover, a notable lowering in oxygen and water vapor transmission rate is detected, revealing water vapor barrier properties closer to LDPE. Migration tests verify the material's compliance with European regulations up to 10 phr, and BOD assessments in seawater indicate improved biodegradability. Fresh food preservation is evaluated on pear slices, showing limited variation of color, acidity, antioxidant power, and weight loss comparable to LDPE-based commercial packaging.
Marzo, 2025 · DOI: 10.1016/j.cej.2025.160887
Materiales Nanoestructurados y Microestructura
First Measurement of a Weak r-Process Reaction on a Radioactive Nucleus
Williams, M; Angus, C; Laird, AM; Davids, B; Diget CAa; Fernández, A; Williams, EJ; Andreyev, AN; Asch, H et al.Physical Review Letters, 134 (2025) 112701 DOI: 10.1103/PhysRevLett.134.112701
Abstract
This Letter reports on the first cross-section measurements for the 94Sr(alpha, n)97Zr and 86Kr(alpha, n)89Sr reactions. In particular, our measurement of 94Sr(alpha, n)97Zr is the first weak r-process reaction cross section obtained using a radioactive ion beam. This experiment was enabled by the use of novel solid helium targets, comprised of silicon thin films with high helium incorporation obtained via a sputtering technique. Yield measurements were performed at center-of-mass energies of 10.4 and 9.0 MeV for the 86Kr(alpha, n)89Sr reaction, and 9.9 MeV for 94Sr(alpha, n)97Zr, extending into the respective Gamow energy windows for a temperature of 5 GK. Reactions were uniquely identified by prompt gamma rays detected in coincidence with heavy ions selected by a recoil mass spectrometer. The obtained cross sections are smaller than predicted for both reactions. In the case of 94Sr(alpha, n)97Zr, the reaction rate found here is lowered by an order of magnitude at temperatures below 5 GK, which is expected to impact the predicted abundance of ruthenium, a signature weak r-process element.
Marzo, 2025 · DOI: 10.1103/PhysRevLett.134.112701
Materiales de Diseño para la Energía y Medioambiente
Poly(Ionic) Liquid-Enhanced Ion Dynamics in Cellulose-Derived Gel Polymer Electrolytes
Paiva, TG; Klem, M; Silvestre, SL; Coelho, J; Alves, N; Fortunato, E; Cabrita, EJ; Corvo, MCChemSusChem, 18 (2025) e202401710 DOI: 10.1002/cssc.202401710
Abstract
Gel polymer electrolytes (GPEs) are regarded as a promising alternative to conventional electrolytes, combining the advantages of solid and liquid electrolytes. Leveraging the abundance and eco-friendliness of cellulose-based materials, GPEs were produced using methyl cellulose and incorporating various doping agents, either an ionic liquid (1-Butyl-1-methylpyrrolidinium bis(trifluoromethylsulfonyl)imide [Pyr14][TFSI]), its polymeric ionic liquid analogue (Poly(diallyldimethylammonium bis(trifluoromethylsulfonyl)imide) [PDADMA][TFSI]), or an anionically charged backbone polymeric ionic liquid (lithium poly[(4-styrenesulfonyl)(trifluoromethyl(S-trifluoromethylsulfonylimino) sulfonyl) imide] LiP[STFSI]). The ion dynamics and molecular interactions within the GPEs were thoroughly analyzed using Attenuated Total Reflectance Fourier-Transform Infrared Spectroscopy (ATR-FTIR), Heteronuclear Overhauser Enhancement Spectroscopy (HOESY), and Pulsed-Field Gradient Nuclear Magnetic Resonance Diffusion (PFG-NMR). Li+ transference numbers (tLi+) were successfully calculated. Our study found that by combining slow-diffusing polymeric ionic liquids (PILs) with fast-diffusing lithium salt, we were able to achieve transference numbers comparable to those of liquid electrolytes, especially with the anionic PIL, LiP[STFSI]. This research highlights the influence of the polymer ' s nature on lithium-ion transport within GPEs. Additionally, micro supercapacitor (MSC) devices assembled with these GPEs exhibited capacitive behavior. These findings suggest that further optimization of GPE composition could significantly improve their performance, thereby positioning them for application in sustainable and efficient energy storage systems.
Marzo, 2025 · DOI: 10.1002/cssc.202401710
Reactividad de Sólidos
A practical analysis to predict sample overheating in flash experiments using the current ramp methodology
Manchón-Gordón, AF; Molina-Molina, S; Perejón, A; Sánchez-Jiménez, P; Pérez-Maqueda, LAJournal of the American Ceramic Society, DOI: 10.1111/jace.20248
Abstract
This work presents a straightforward strategy for achieving specific overheating during flash experiments by adjusting the initial electrical parameters. To do that, an extensive experimental analysis was performed to evaluate the temperature evolution of dense ZnO specimens during controlled-current ramping at different furnace temperatures, which in turn modified the initial electrical resistance of the sample. A detailed electrical explanation of controlled-current ramp flash processes is provided and, for the first time, a practical equivalence between current-ramp and temperature-ramp flash methodologies is established. By parameterizing the experiments in terms of an effective power density, a consistent heating pattern following the blackbody radiation trend was identified, despite the different electrical characteristics of each experiment. Finally, a “flash heating map” is introduced, which can be used to determine the starting electrical parameters necessary to achieve a specific temperature increase, whether employing current or temperature ramps.
Marzo, 2025 · DOI: 10.1111/jace.20248
Materiales Avanzados
Influence of features and firing temperature on the ceramic properties and phase evolution of raw kaolins
Sánchez-Soto, PJ; García-Garzón, V; Martínez-Martínez, S; Pérez-Villarejo, L; Sánchez-Garrido, JA; Garzón, EConstruction and Building, 466 (2025) 140215 DOI: 10.1016/j.conbuildmat.2025.140215
Abstract
The influence of the characteristic features and firing temperature on the ceramic properties of raw kaolin samples were examined studying a wide range of firing temperatures (1000–1500 ºC). The techniques of investigation have been particle size analysis, Transmission Electron Microscopy (TEM), X-ray powder Diffraction (XRD), X-ray Fluorescence analysis (XRF), and Thermal Analysis using Termodilatometry (TD), Thermalgravimetric analysis (TGA) and Differential Thermal Analysis (DTA). Uniaxial pressed cylindric bodies were obtained and fired from 1000 to 1500 °C/2 h. TEM allowed investigate morphological differences and identification of kaolinite and halloysite. The mineralogical analysis indicated that the kaolinite content is high (80–90 wt%). The contents of oxide impurities are relatively low although in a sample is 7.6 wt% on a calcined basis. The characteristic sharp DTA exothermic effect of kaolinite was observed in the range 900–1000 °C. The ceramic properties of the group of kaolin samples has been determined: linear firing shrinkage, water absorption capacity, apparent density and open porosity. Sintering diagrams allowed investigate the progressive decrease of water absorption and the increase of firing shrinkage. In some kaolin samples the water absorption reached zero at 1450–1500 ᵒC. High sintering temperatures have been observed when kaolinite is present in high contents and the fluxes content is low. The maximum values of apparent density were determined, with a sample with the highest value (2.75 ± 0.10 g/cm3). The open porosity changes from ∼ 34–38 % at 1000 ᵒC up to zero or minimum values (< 3 %) at 1500 ᵒC. This behaviour is associated to the progressive sintering of the particles and filling of pores by glassy phase originated by the presence of fluxes and the influence of a low particle size. The formation of mullite and cristobalite by firing have been studied by XRD. Mullite has been detected from 1000 to 1100 ᵒC and the crystals developed as increasing firing temperatures. Cristobalite (α-cristobalite) has been identified at 1200–1300 ºC. The presence of an alkaline melt could impede the crystallization of cristobalite. This study presents a comparative research because all these commercial kaolin samples have been examined under the same experimental conditions. Consequently, the results have allowed to provide new data about raw kaolin powders with high kaolinite content in the range 80–90 wt%.
Marzo, 2025 · DOI: 10.1016/j.conbuildmat.2025.140215
Materiales Ópticos Multifuncionales
Tunable White Light Emission from Transparent Nanophosphor Films Embedding Perovskite Lead Halide Nanostructures
Viaña, JM; Romero-Pérez, C; Calvo, ME; Lozano, G; Míguez, HACS Applied Materials & Interfaces, 17 (2025) 19900-19905 DOI: 10.1021/acsami.4c22044
Abstract
Exploring synergistic interactions between nanomaterials that can enhance their collective properties in ways that individual components cannot achieve represents an avenue for advancing beyond the current state of the art. This approach is particularly relevant in the context of ABX(3) nanocrystals, where pursuing cooperation could help to overcome current challenges associated with light generation. Transparent photoluminescent coatings are developed by combining perovskite nanomaterials and porous scaffolds of high optical quality phosphor nanoparticles. Fine tuning of the spectral content of the emission is achieved with the photoexcitation wavelength, allowing the demonstration of white light emission with tunable hues.
Marzo, 2025 · DOI: 10.1021/acsami.4c22044
Reactividad de Sólidos
Revisiting Stability Criteria in Ball-Milled High-Entropy Alloys: Do Hume-Rothery and Thermodynamic Rules Equally Apply?
Blázquez, JS; Manchón-Gordón, AF; Vidal-Crespo, A; Caballero-Flores, R; Ipus, JJ; Conde, CFAdvanced Engineering Materials, 27 (2025) 2401148 DOI: 10.1002/adem.202401148
Abstract
Stability descriptors for the formation of solid solutions can be divided into two categories: inspired by Hume–Rothery rules (HRR) and derived from thermodynamic approaches. Herein, HRRs are extended from binary to high-entropy alloys (HEAs) focusing on compositions prepared by ball milling. Parameters describing stability criteria are interrelated and implicitly account for the microstrains’ storage energy, more determinant than entropy increase in stabilization of HEAs and more effective in bcc structures than close-packed ones (fcc and hcp). An effective temperature, Teff, is defined as the ratio between increase in metallic bonding energy of solid solutions with respect to segregated pure constituents and configurational entropy. This versatile parameter is used as a threshold for stabilization of HEAs at equilibrium and out of equilibrium. When Teff is below room temperature, HEA would be stable at equilibrium. When Teff is below melting temperature, HEA would be obtained by rapid quenching. Limitations related to electronegativity differences remain valid in mechanically alloyed solid solutions. However, ball milling broadens the allowed differences in atomic size to form HEA. Moreover, thermodynamic criteria can be surpassed in these systems, allowing the formation of single-phase solid solutions beyond the compositional range predicted by those criteria.
Marzo, 2025 · DOI: 10.1002/adem.202401148
Nanotecnología en Superficies y Plasma
Facile integration of single-crystalline phthalocyanine nanowires and nanotrees as photo-enhanced conductometric sensors
Filippin, AN; Campos-Lendinez, A; Delgado-Alvarez, J; Moreno-Martínez, G; Castillo-Seaone, J; Rico, VJ; Godinho, VF; Barranco, A; Sanchez-Valencia, JR; Borras, ANanoscale, 17 (2025) 7945-7956 DOI: 10.1039/d4nr04761c
Abstract
This article presents a reproducible and affordable methodology for fabricating organic nanowires (ONWs) and nanotrees (ONTs) as light-enhanced conductometric O2 sensors. This protocol is based on a solventless procedure for the formation of high-density arrays of nanowires and nanotrees on interdigitated electrodes. The synthesis combines physical vapour deposition for the self-assembled growth of free-phthalocyanine nanowires and soft plasma etching to prompt the nucleation sites on the as-grown ONWs to allow for the formation of nanotrees. Electrical conductivity in such low-dimensional electrodes was analysed in the context of density, length, and interconnection between nanowires and nanotrees. Furthermore, the electrodes were immersed in water to improve the nanowires' connectivity. The response of the nanotrees as conductometric O2 sensors was tested at different temperatures (from room temperature to 100 degrees C), demonstrating that the higher surface area exposed by the nanotrees, in comparison with that of their polycrystalline thin film counterparts, effectively enhances the doping effect of oxygen and increases the response of the ONT-based sensor. Both organic nanowires and nanotrees were used as model systems to study the augmented response of the sensors provided by illumination with white or monochromatic light to organic semiconducting systems. Interestingly, the otherwise negligible sensor response at room temperature can be activated (On/Off) under LED illumination, and no dependency on the illumination wavelength in the visible range was observed. Thus, under low-power LED illumination with white light, we show a response to O2 of 16% and 37% in resistivity for organic nanotrees at room temperature and 100 degrees C, respectively. These results open the path to developing room temperature long-lasting gas sensors based on one- and three-dimensional single-crystalline small-molecule nanowires.
Marzo, 2025 · DOI: 10.1039/d4nr04761c
Materiales y Procesos Catalíticos de Interés Ambiental y Energético
Direct biogas methanation at moderate pressure: Mechanism investigation over Ni-based catalysts
Giarnieri, I; Che, SN; Ballesteros-Plata, D; Holgado, JP; Maluta, F; Caballero, A; Ospitali, F; Fornasari, G; Beale, AM; Benito, PJournal of CO2 Utilization, 93 (2025) 103045 DOI: 10.1016/j.jcou.2025.103045
Abstract
Direct upgrading of biogas by CO2 methanation aims to produce a gas to be injected into the grid. Operating at moderate pressures favors thermodynamics, but catalyst surface and reaction mechanism under realistic conditions are not well investigated. We study the role of basic and metallic sites on performance and mechanism of clean biogas methanation (CO2/CH4=1/1 v/v) at 1, 5 and 7 bar. Ni/Mg/La/Al hydrotalcite-derived catalysts, with different Ni and La contents, are investigated combining tests and physico-chemical characterization, including quasi-in situ XPS at 7 bar, with CO2-adsorption and methanation DRIFTS at 1 and 7 bar, respectively. An optimized catalyst (6.5 wt% La, 35 wt% Ni) with 3-4 nm Ni0 and balanced basicity, achieves 96 LCH4*gcat- 1* h- 1 (300 degrees C, 7 bar). DRIFTS confirm catalysts activity experimental trend. Optimizing Ni and La results in higher consumption rates of formate intermediate and sufficient Ni0 sites for CO formation. Increasing pressure to 7 bar promotes CO and m-HCOO reactivity.
Marzo, 2025 · DOI: 10.1016/j.jcou.2025.103045
Materiales Nanoestructurados y Microestructura
On the characteristics of helium filled nano-pores in amorphous silicon thin films
Lacroix, B; Fernández, A; Pyper, NC; Thom, AJW; Whelan, CTApplied Surface Science, 683 (2025) 161772 DOI: 10.1016/j.apsusc.2024.161772
Abstract
A joint theory-experimental study is presented of irregularly shaped nano-pores in amorphous silicon. STEM- ELLS spectra were measured for each pore. The observed helium 1 s 2- 1 s 2 p( 1 P ) excitation energies were found to be shifted from that of a free atom. The relation between the helium density in the pore and these energy shifts is explored and shown to be completely consistent with earlier studies of helium in its bulk condensed phases as well as encapsulated as bubbles in solid silicon. The density, pressure and depth of the pores, all key properties for applications, were determined. An alternative and novel method for determining the depth of the pores more accurately is presented.
Febrero, 2025 · DOI: 10.1016/j.apsusc.2024.161772
Tribología y Protección de Superficies
Diffusion mechanisms and corrosion resistance of nanostructured ZrN-Cu coating obtained by hybrid HiPIMS-DCMS
Castro, JD; Sánchez-López, JC; Rojas, TC; Escobar-Galindo, R; Carvalho, SApplied Surface Science, 682 (2025) DOI: 10.1016/j.apsusc.2024.161635
Abstract
Globalisation has brought numerous benefits regarding the cost-effective transportation of goods. Still, the shipping industry faces challenges such as corrosion, biofouling, and restrictions on heavy pollutant products used in paintings. This study proposes a solution using a multifunctional coating based on zirconium nitride and copper nano-structured coating, applying high-power impulse and direct current magnetron sputtering processes (i.e., HiPIMS and DCMS, respectively). The coating's morphological, structural, and chemical features were analysed using advanced characterisation techniques (SEM, EDX, STEM, SAED and EELS). Potentiodynamic polarisation (PP) and Electrochemical Impedance Spectroscopy (EIS - up to 30 days) were employed to study the corrosion resistance in saline solution (3.5 wt. % NaCl). Besides, activated ZrN-Cu exhibited a corrosion rate decrease from similar to 354 x 10(-4) to 52 x 10(-4) mm/yr when compared to its inactivated counterpart. Besides, a similar to 3.5-fold impedance increasing was exhibited by activated ZrN-Cu after 30 days of exposure to saline solution, meaning an increase in corrosion resistance compared to the non-activated ZrN-Cu. SEM micrographs revealed that the copper diffusion in ZrN-Cu can be provoked by a strong oxidising agent (NaOCl) or by an electrical potential. Based on the chartered evidence, a diffusion mechanism is proposed for the biocidal release (Cu) in the obtained ZrN-Cu films. The present study depicts a solution that offers a controlled biocide release and corrosion resistance, opening the possibility of its application in the maritime industry.
Febrero, 2025 · DOI: 10.1016/j.apsusc.2024.161635
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