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1. Superconductivity and Pronounced Electron‐Phonon Coupling in Rock‐Salt Al _1−x O _1−x and Ti _1−x O _1−x

   https://doi.org/10.1002/aelm.202400141  

   Žguns, Pjotrs; Gedik, Nuh; Yildiz, Bilge; Li, Ju (May 2024, Advanced Electronic Materials)

   Abstract The highest ambient‐pressure Tc among binary compounds is 40 K (MgB2). Higher Tc is achieved in high‐pressure hydrides or multielement cuprates. Alternatively, are explored superconducting properties of binary, metastable sub‐oxides, that may emerge under extremely low oxygen partial pressure. The emphasis is on the rock‐salt structure, which is known to promote superconductivity, and exploring AlO, ScO, TiO, and NbO. Dynamic lattice stability is achieved by introducing metal and oxygen vacancies in the fashion of Nb_1−xO_1−x‐type structure (x = ¼). The electron‐phonon (e‐ph) coupling is remarkably large in Al_1−xO_1−xand Ti_1−xO_1−x(λ ≈ 2 at x = ¼), with Tc ≈ 35 K according to the Allen–Dynes equation. Significantly, the coupling strength is comparable to that in high‐pressure hydrides, yet, in contrast to hydrides and MgB2, the coupling is largely driven by low frequency phonons. Sc_1−xO_1−xand Nb_1−xO_1−xshow significantly smaller λ and Tc. Further, hydrogen intercalation to boost λ and Tc is investigated. Only Ti_1−x(O_1−xHx) and Nb_1−x(O_1−xHx) are dynamically stable upon intercalation, where H, respectively, decreases and increases Tc. The effect of H doping on electronic structure and Tc is discussed. Altogether, the study suggests that metal sub‐oxides are promising compounds to achieve strong e‐ph coupling at ambient pressure. 

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2. Carbon vacancy ordering in zirconium carbide powder

   https://doi.org/10.1111/jace.16964  

   Zhou, Yue; Heitmann, Thomas_W; Bohannan, Eric; Schaeperkoetter, Joseph_C; Fahrenholtz, William_G; Hilmas, Gregory_E (December 2019, Journal of the American Ceramic Society)

   Abstract Ordered carbon vacancies were detected in zirconium carbide (ZrC_x) powders that were synthesized by direct reaction. Zirconium hydride (ZrH₂) and carbon black were used as starting powders with the molar ratio of ZrH₂:C = 1:0.6. Powders were reacted at 1300°C or 2000°C. The major phase detected by x‐ray diffraction (XRD) was ZrC_x. No excess carbon was observed by transmission electron microscopy (TEM) in powders synthesized at either temperature. Ordering of the carbon vacancies was identified by neutron powder diffraction (NPD) and further supported by selected area electron diffraction (SAED). The vacancies in carbon‐deficient ZrC_xexhibited diamond cubic symmetry with a supercell that consisted of eight (2 × 2 × 2) ZrC_xunit cells with the rock‐salt structure. Rietveld refinement of the neutron diffraction patterns revealed that the synthesis temperature did not have a significant effect on the degree of vacancy ordering in ZrC_xpowders. Direct synthesis of ZrC_0.6resulted in the partial ordering of carbon vacancies without the need for extended isothermal annealing as reported in previous experimental studies. 

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3. Unlocking the Origin of High‐Temperature Superconductivity in Molecular Hydrides at Moderate Pressures

   https://doi.org/10.1002/adfm.202415910  

   Zhao, Wendi; Ellis, Austin; Duan, Defang; Wang, Hongwei; Jiang, Qiwen; Du, Mingyang; Cui, Tian; Miao, Maosheng (November 2024, Advanced Functional Materials)

   Abstract The current pressing challenge in the field of superconducting hydride research is to lower the stable pressure of such materials for practical applications. Molecular hydrides are usually stable under moderate pressure, but the underlying metallization mechanism remains elusive. Here, the important role of chemical interactions in governing the structures and properties of molecular hydrides is demonstrated. A new mechanism is proposed for obtaining high‐temperature and even room‐temperature superconductivity in molecular hydrides and report that the ternary hydride NaKH₁₂hostsT_cvalues up to 245 K at moderate pressure of 60 GPa. Both the excellent stability and superconductivity of NaKH₁₂originate from the fact that the localized electrons in the interstitial region of the metal lattice occupying the crystal orbitals well matched with the hydrogen lattice and forming chemical templates to assist the assembly of H₂units. These localized electrons weaken the H─H covalent bonds and improve the charge connectivity between the H₂units, ensuring the strong coupling between electrons and hydrogen‐dominated optical phonons. The theory provides a key perspective for understanding the superconductivity of molecular hydrides with various structural motifs, opening the door to obtaining high‐temperature superconductors from molecular hydrides at moderate pressures. 

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4. Factors Determining the Resistive Switching Behavior of Transparent InGaZnO‐Based Memristors

   https://doi.org/10.1002/pssr.202200075  

   Qin, Fei; Zhang, Yuxuan; Park, Honghwi; Kim, Chung Soo; Lee, Dong Hun; Jiang, Zhong-Tao; Park, Jeongmin; No, Kwangsoo; Park, Hongsik; Song, Han Wook; et al (June 2022, physica status solidi (RRL) – Rapid Research Letters)

   The overarching goal herein is to identify the factors dominating the performance of a‐IGZO‐based memristors. Despite the highest on/off ratio, greater than 10⁴with a preferred minimal set/reset bias achieved from a‐IGZO‐based memristors, it is observed that the switching performance and stability/reliability of the devices is significantly dominated by theV_O^··density and metallization material, depending on their reactivity with IGZO. As the first governing factor, ensuring optimalV_O^··concentration in the switching layer IGZO (V_O^··/O_O^xratio 24.3% in this study) is crucial to obtain the tractable formation and rupture of conduction filament. Neither higher nor lowerV_O^··density than the optimized results in detrimental reliability issues, which may be ascribed to an uncontrollable filament in an abundant vacancy environment or a weak conducting path, respectively. As the second governing mechanism determining the memristor performance and reliability, it is suggested that metallization materials need to be carefully selected based on the thermodynamic redox potential and interfacial stability of the metallization material with IGZO. Metallization materials with larger reduction potential and interfacial stability are found to yield higher switching on/off ratio and greater device performance reliability. 

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5. Processing and room temperature mechanical properties of a zirconium carbide ceramic

   https://doi.org/10.1111/jace.17442  

   Korklan, Nicole; Hilmas, Gregory_E; Fahrenholtz, William_G (September 2020, Journal of the American Ceramic Society)

   Abstract Zirconium carbide (ZrC) powder, batched to a ratio of 0.98 C/Zr, was prepared by carbothermal reduction of ZrO₂with carbon black. Nominally phase‐pure ZrC powder had a mean particle size of 2.4 μm. The synthesized powder was hot‐pressed at 2150°C to a relative density of > 95%. The mean grain size was 2.7 ± 1.4 μm with a maximum observed grain size of 17.5 μm. The final hot‐pressed billets had a C/Zr ratio of 0.92, and oxygen content of 0.5 wt%, as determined by gas fusion analysis. The mechanical properties of ZrC_0.92O_0.03were measured at room temperature. Vickers’ hardness decreased from 19.5 GPa at a load of 0.5 kgf to 17.0 GPa at a load of 1 kgf. Flexural strength was 362.3 ± 46 MPa, Young's modulus was 397 ± 13 MPa, and fracture toughness was 2.9 ± 0.1 MPa•m^1/2. Analysis of mechanical behavior revealed that the largest ZrC grains were the strength‐limiting flaw in these ceramics. 

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