Project description:PurposeBiodiesel is a non-toxic, renewable, and environmentally friendly fuel used in compression ignition engines. This work aimed to develop Fe3O4/SiO2 as a cheap, magnetic, and easy separable catalyst for biodiesel production from waste oil by sono-catalytic transesterification.MethodsFe₃O₄-SiO₂ was prepared using a modified Stober method and used as a heterogeneous catalyst in an ultrasound-assisted transesterification reaction to produce biodiesel. The tests were designed by the Response surface methodology by considering the molar ratio of methanol to oil (M/O), catalyst weight percentage, and sonication time as independent factors. The produced biodiesel in diesel generator engines and the emission of pollutants were evaluated.ResultsThe optimal production conditions were determined using the response surface methodology, which included a molar ratio of 8.30, a catalyst weight percentage of 5.30, and a sonication time of 30.02 min. The Pareto analysis indicated that the sonication time is the most important factor in the sono-catalytic transesterification of waste oil. The evaluation of the produced fuel showed that with an increase in the percentage of biodiesel in the engine's fuel input, CO emissions decreased by 0.027 % and smoke levels by 24 %, while NOx levels increased by 495 ppm. Additionally, the increase in biodiesel percentage led to a rise in brake-specific power by 44.6 kW and brake-specific fuel consumption by 89 g/kWh though brake torque decreased by 87 Nm.ConclusionThe study introduces significant advancements in biodiesel production technology through combining heterogeneous catalysis and ultrasound processing, optimizing production parameters for efficiency and sustainability while demonstrating improved environmental performance in diesel engines.

Project description:Inspired by the reported crystal structure of compound 1, we aimed to synthesize and determine the structure of compound 2, where two imidazolium (H2im+) ions serve as diamagnetic countercations. Here, we report the thermal stabilities, FT-IR, visible, and RSE spectra, as well as the magnetic properties of both compounds. In these structures, µ-EDTA acts as a pentadentate chelator for both terminal Cu centers within the centrosymmetric linear trinuclear anion. The Cu(µ-EDTA) chelates bind to the central Cu(Him)4 unit in subtly different ways: in compound 1, µ-EDTA has a free acetate arm and binds the central Cu(II) center through a syn,anti-carboxylate group. In contrast, in compound 2, the non-chelating acetate arm serves as a monodentate O-donor to the central Cu(II) atom, increasing the Cu(terminal)···Cu(central) distance from 6.08 Å in 1 to 6.80 Å in 2. Additionally, pairs of H2im+ ions in compound 2 display antiparallel π-stacking interactions. We conclude that the H2im+ counterions in compound 2 enable the magnetic isolation of the nearly identical trinuclear anion present in both compounds. DFT calculations further support the role of different interactions in stabilizing each crystal structure. In compound 2, dominant contributions from N-H···O hydrogen bonds and π-stacking interactions are accompanied by other, less conventional interactions, such as multiple C-H···O contacts and an O···CO(π-hole) interaction within the trinuclear anion.

Project description:The optoelectronic properties of two layered copper oxyselenide compounds, with nominal composition Sr2ZnO2Cu2Se2 and Ba2ZnO2Cu2Se2, have been investigated to determine their suitability as p-type conductors. The structure, band gaps and electrical conductivity of pristine and alkali-metal-doped samples have been determined. We find that the strontium-containing compound, Sr2ZnO2Cu2Se2, adopts the expected tetragonal Sr 2 Mn 3 SbO 2 structure with I4/mmm symmetry, and has a band gap of 2.16 eV, and a room temperature conductivity of 4.8 × 10-1 S cm-1. The conductivity of the compound could be increased to 4.2 S cm-1 when sodium doped to a nominal composition of Na0.1Sr1.9ZnO2Cu2Se2. In contrast, the barium containing material was found to have a small zinc oxide deficiency, with a sample dependent compositional range of Ba2Zn1-x O2-x Cu2Se2 where 0.01 < x < 0.06, as determined by single crystal X-ray diffraction and powder neutron diffraction. The barium-containing structure could also be modelled using the tetragonal I4/mmm structure, but significant elongation of the oxygen displacement ellipsoid along the Zn-O bonds in the average structure was observed. This indicated that the oxide ion position was better modelled as a disordered split site with a displacement to change the local zinc coordination from square planar to linear. Electron diffraction data confirmed that the oxide site in Ba2Zn1-x O2-x Cu2Se2 does not adopt a long range ordered arrangement, but also that the idealised I4/mmm structure with an unsplit oxide site was not consistent with the extra reflections observed in the electron diffractograms. The band gap and conductivity of Ba2Zn1-x O2-x Cu2Se2 were determined to be 2.22 eV and 2.0 × 10-3 S cm-1 respectively. The conductivity could be increased to 1.5 × 10-1 S cm-1 with potassium doping in K0.1Ba1.9Zn1-x O2-x Cu2Se2. Hall measurements confirmed that both materials were p-type conductors with holes as the dominant charge carriers.

Project description:We report the fabrication of a novel spinel-type Pd₀.₁Cu₀.₉Co₂O₄ nano-flake material designed for Mizoroki-Heck and Suzuki coupling-cum-transesterification reactions. The Pd₀.₁Cu₀.₉Co₂O₄ material was synthesized using a simple co-precipitation method, and its crystalline phase and morphology were characterized through powder XRD, UV-Vis, FESEM, and EDX studies. This material demonstrated excellent catalytic activity in Mizoroki-Heck and Suzuki cross-coupling reactions, performed in the presence of a mild base (K₂CO₃), ethanol as the solvent, and microwave irradiation under ligand-free conditions. Notably, the Heck coupling of acrylic esters proceeded concurrently with transesterification using various alcohols as solvents. The catalyst exhibited remarkable stability under reaction conditions and could be recycled and reused up to ten times while maintaining its catalytic integrity.

Project description:This study introduces a new method for synthesizing Cu+-containing metastable phases through ion exchange. Traditionally, CuCl has been used as a Cu+ ion source for solid-state ion exchanges; however, its thermodynamic driving force is often insufficient for complete ion exchange with Li+-containing precursors. First-principles calculations have identified Cu2SO4 and Cu3PO4 as more powerful alternatives, providing a higher driving force than CuCl. It has been experimentally demonstrated that these ion sources can open up new reaction pathways through experimental ion exchanges, such as from β-LiGaO2 to β-CuGaO2, which were previously unattainable. An important perspective provided by this study is that the potential of such simple compounds to act as powerful ion sources has been overlooked and that they were identified through straightforward first-principles calculations. This work presents the initial strategic design of an ion-exchange reaction by exploring suitable ion sources, thereby expanding the potential for synthesizing metastable materials.

Project description:In this study, we explore the charge transfer mechanism between WO3 and Cu2O in heterostructured WO3/Cu2O electrodes and in a WO3||Cu2O tandem photoelectrochemical cell. The physical-chemical characterizations of the individual WO3 and Cu2O electrodes and the heterostructured WO3/Cu2O electrode by XRD, XPS, and SEM methods confirm the successful formation of the target systems. The results of photoelectrochemical studies infer that in both the heterostructured WO3/Cu2O electrode and WO3||Cu2O tandem photoelectrochemical cell, the major mechanism of charge transfer between WO3 and Cu2O is a realization of the Z-scheme.

Project description:Two-dimensional (2D) materials have been identified as promising candidates for future electronic devices. However, high dielectric constant (κ) materials, which can be integrated with 2D semiconductors, are still rare. Here, we report a hydrate-assisted thinning chemical vapor deposition (CVD) technique to grow manganese oxide (Mn3O4) single crystal nanosheets, enabled by a strategy to minimize the substrate lattice mismatch and control the growth kinetics. The material demonstrated a dielectric constant up to 135, an equivalent oxide thickness (EOT) as low as 0.8 nm, and a breakdown field strength (Ebd) exceeding 10 MV/cm. MoS2 field-effect transistors (FETs) integrated with Mn3O4 thin films through mechanical stacking method operate under low voltages (<1 V), achieving a near 108 Ion/Ioff ratio and a subthreshold swing (SS) as low as 84 mV/dec. The MoS2 FET exhibit nearly zero hysteresis (<2 mV/MV cm⁻¹) and a low drain-induced barrier lowering (~20 mV/V). This work further expands the family of 2D high-κ dielectric materials and provides a feasible exploration for the epitaxial growth of single-crystal thin films of non-layered materials.

Project description:We report the first process for iridium element recovery from organoiridium waste that is quantitative, pyrolysis-free, and generates no iridium metal. The key step is oxidative degradation of the waste by bleach to crude iridium(IV) hydroxide. Its treatment with hydrazine and then hydrogen peroxide gives synthetically important hexachloroiridic acid, which is converted to [(1,5-cyclooctadiene)IrCl]2 in 87% yield.

Project description:A Cu2 paddle wheel-based metal-organic framework, [Cu2(trz-ia)2] (trz-ia2- = 5-(4H-1,2,4-triazol-4-yl) isophthalate), is investigated for hydrogen adsorption and hydrogen isotopologue separation. Its ultramicroporous structure with pore diameters ranging from 0.35 to 0.53 nm allows for strong interactions with dihydrogen molecules, resulting in steep H2 uptake and heat of adsorption Qads = 9.7 kJ mol-1. Notably, the hydrogen density inside the pores is 43.9 g L-1 at 77 K and 100 kPa. Thermal desorption spectroscopy (TDS) after exposure to a H2/D2 mixture indicates dihydrogen isotopologue separation with a selectivity of S = 6 at 30 K and a high uptake of D2. These findings are compared with numerous other metal-organic frameworks (MOFs) and related to their pore size.

Project description:Transforming hazardous and difficult-to-process waste materials, like spent Ni-MH batteries and aluminium foil, into nanocatalysts (NCts) provides a sustainable solution for resource management and reducing environmental impact. This study demonstrates a novel approach by extracting nickel sulfate (NiSO4·xH2O) from battery waste and subsequently converting it into Ni(OH)2 hydrogel precursors using l-glutamic acid. Waste aluminium foil was processed into alumina (Al2O3), and combined with Ni(OH)2 to synthesize Ni/η-Al2O3 NCts with 4% and 8% Ni loading. Characterization through XRD/SAED, STEM/EFTEM, and EELS revealed a disordered cubic structure of η-Al2O3, with well-dispersed Ni particles, making it effective for CO2 hydrogenation. The 8-Ni/η-Al2O3 exhibited the best catalytic performance, with CH4 selectivity of 99.8% and space time yield (STY) of 80.3 mmolCH4 gcat -1 h-1 at 400 °C. The CO2 methanation mechanism over Ni/η-Al2O3 NCts was further explored using operando DRIFTS aligned with GC + MS. The operando investigation suggested a preferential associative CO2 methanation pathway, involving sequential adsorption and hydrogenation of CO2 to hydrogen carbonates on Ni/η-Al2O3, and their transformation into formate and methoxy intermediates leading to methane. Finally, to complete the upcycling/recycling loop, the spent Ni/η-Al2O3 NCts were recycled into Ni and Al precursors. These findings underscore the potential of upcycling waste materials for synthesizing sustainable, high-performance NCts, and offer insights into the CO2 methanation mechanism.