High-entropy oxides (HEOs), which
contain five or more
metal cations
that are generally thought to be randomly mixed in a crystalline oxide
lattice, can exhibit unique and enhanced properties, including improved
catalytic performance, due to synergistic effects. Here, we show that
band gap narrowing emerges in a high-entropy aluminate spinel oxide,
(Fe0.2Co0.2Ni0.2Cu0.2Zn0.2)Al2O4 (A
5Al2O4). The 0.9 eV band gap of A
5Al2O4 is narrower than the band
gaps of all parent spinel oxides. First-principles calculations for
multicomponent AAl2O4 spinels
indicate that the band gap narrowing arises from the broadening of
the energy distribution of the 3d states due to variations in the
electronegativities and crystal field splitting across the 3d transition-metal
series. As a catalyst for the oxygen evolution reaction in an alkaline
electrolyte, A
5Al2O4 reaches a current density of 10 mA/cm2 at an overpotential
of 400 mV, outperforming all of the single-metal end members at an
applied potential of 1.7 V vs RHE. Catalyst deactivation occurs after
5 h at 10 mA/cm2 and is attributed, based on elemental
analysis and grazing-incidence X-ray diffraction, to the formation
of a passivating layer that blocks the high-entropy oxide surface.
This result helps to validate that the HEO is the active catalyst.
The observation of band gap narrowing in A
5Al2O4 expands the scope of synergistic properties
exhibited by high-entropy materials and offers insight into the question
of how the electronic structure of multicomponent oxide materials
can be engineered via a high-entropy approach to achieve enhanced
catalytic properties.
Ion exchange reactions of colloidal nanoparticles post-synthetically modify the composition while maintaining the morphology and crystal structure and therefore are important for tuning properties and producing otherwise inaccessible and/or metastable materials. Reactions involving anion exchange of metal chalcogenides are particularly interesting, as they involve the replacement of the sublattice that defines the structure while also requiring high temperatures that can be disruptive. Here, we show that the tellurium anion exchange of weissite Cu 2−x Se nanoparticles using a trioctylphosphine−tellurium complex (TOP�Te) yields weissite Cu 2−x Se 1−y Te y solid solutions, rather than complete exchange to weissite Cu 2−x Te, with compositions that are tunable based on the amount of TOP�Te used. Upon storage at room temperature in either solvent or air, tellurium-rich Cu 2−x Se 1−y Te y solid solution nanoparticles transform, over the span of several days, to a seleniumrich Cu 2−x Se 1−y Te y composition. The tellurium that is expelled from the solid solution during this process migrates to the surface and forms a tellurium oxide shell, which correlates with the onset of particle agglomeration due to the change in surface chemistry. Collectively, this study demonstrates tunable composition during tellurium anion exchange of copper selenide nanoparticles along with unusual post-exchange reactivity that transforms the composition, surface chemistry, and colloidal dispersibility due to the apparent metastable nature of the solid solution product.
The high temperatures typically required to synthesize refractory compounds preclude the formation of highenergy morphological features, including nanoscopic pores that are beneficial for applications, such as catalysis, that require higher surface areas. Here, we demonstrate a low-temperature multistep pathway to engineer mesoporosity into a catalytic refractory material. Mesoporous molybdenum boride, α-MoB, forms through the controlled thermal decomposition of nanolaminate-containing sheets of the metastable MAB (metal−aluminum−boron) phase Mo 2 AlB 2 and amorphous alumina. Upon heating, the Mo 2 AlB 2 layers of the Mo 2 AlB 2 −AlO x nanolaminate, which is derived from MoAlB, begin to bridge and decompose, forming inclusions of alumina in a framework of α-MoB. The alumina can be dissolved in aqueous sodium hydroxide in an autoclave, forming α-MoB with empty and accessible pores. Statistical analysis of the morphologies and dimensions of the pores reveals a correlation with grain size, which relates to the pathway by which the alumina inclusions form. The transformation of Mo 2 AlB 2 to α-MoB is topotactic due to crystal structure relationships, resulting in a high density of stacking faults that can be modeled to account for the observed experimental diffraction data. Porosity was validated by comparing surface areas and demonstrating catalytic viability for the hydrogen evolution reaction.
Herein, we report an effective strategy to maximize the antimicrobial activity of CuWO4/CuS hybrid composites, prepared by simply mixing CuWO4 and CuS nanopowders with varying weight ratios in phosphate buffered...
Oxides of p-block metals (e.g., indium oxide) and semimetals (e.g., antimony oxide) are of broad practical interest as transparent conductors and light absorbers for solar photoconversion due to the tunability of their electronic conductivity and optical absorption. Comparatively, these oxides have found limited applications in solar-to-hydrogen photocatalysis primarily due to their high electronegativity, which impedes electron transfer for converting protons into molecular hydrogen. We have shown recently that inserting s-block metal cations into p-block oxides is effective at lowering electronegativities while affording further control of band gaps. Here, we explain the origins of this dual tunability by demonstrating the mediator role of s-block metal cations in modulating orbital hybridization while not contributing to frontier electronic states. From this result, we carry out a comprehensive computational study of 109 ternary oxides of s-and p-block metal elements as candidate photocatalysts for solar hydrogen generation. We downselect the most desirable materials using band gaps and band edges obtained from Hubbard-corrected density-functional theory with Hubbard parameters computed entirely from first principles, evaluate the stability of these oxides in aqueous conditions, and characterize experimentally four of the remaining materials, synthesized with high phase uniformity, to assess the accuracy of computational predictions. We thus propose seven oxide semiconductors, including CsIn3O5, Sr2In2O5, and KSbO2 which, to the extent of our literature review, have not been previously considered as water-splitting photocatalysts.
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