A physical catalyst for the electrolysis of nitrogen to ammonia | Aluminium Sulphate

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Since the nature of the interphase layers between the Li metal and the SSEs drastically changed the behavior of the Li metal plating and stripping, the interphase morphology and composition were analyzed using scanning electron microscopy (SEM), time-of-flight secondary ion mass spectrometry (ToF-SIMS), and x-ray photoelectron spectroscopy (XPS). Figure 4 (A and B) shows the surface morphology of the cycled LPS recovered from Li|LPS|SS and Li|LiFSI@LPS|SS. The untreated LPS shows substantial cracking after prolonged cycling due to the side reactions (Li3PS4 + 8Li → Li3P + 4Li2S) between the Li metal and the solid-state LPS electrolyte, as evidenced by the low CE and poor cycling stability (Fig. 3D). Figure 4D shows the ternary phase diagram of the Li-P-S obtained from Materials Project (MP) (30). The reaction between the LPS and the Li metal will ultimately form the fully lithiated species of Li2S and Li3P, with LiP7, Li3P7, and LiP as the possible intermediates. However, these reduction products cannot act as effective SEI layers due to the high electronic conductivity of LixP (figs. S4 and S5). The formation of the lithiated layer will increase the Li content on the LPS surface. ToF-SIMS analysis was used to map the Li content in the cross section. As shown in fig. S4, the Li content in the cracked layer of the cycled LPS SSE was higher than that in the bulk LPS SSE, confirming the side reactions of LPS with Li. XPS was also performed to obtain the detailed composition information on the interface layer (Fig. 4, C, E, and F, and fig. S6). For the cycled LPS recovered from the untreated Li|LPS|SS battery, significantly high doublet peaks of Li3P (2p3/2: 126 eV) were observed, in addition to P doublet peaks of 2p3/2 and 2p1/2 (~132.5 eV) from LPS (31). A few tiny peaks at 130.3 eV in XPS could be attributed to other reduced P compounds (LixP, 0 ≤ x < 3) (31). The XPS surface composition analysis confirms the serious parasitic reactions between the LPS SSE and the Li metal during the Li plating/stripping process, which is in line with the previous reports (31, 32) and the reaction mechanism based on the ternary phase diagram in Fig. 4D. All the analyses from the SEM, XPS, and ToF-SIMS proved that significant reactions take place between the LPS SSE and the Li metal anode, leading to the formation of the lithiated by-products and cracks. Hayashi and colleagues (31) reported that LPS coated by Au is also reduced by Li.

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The PSS polymer was interwoven in the HKUST-1 scaffold by a two-step process: firstly it was firmly assembled with the HKUST-1 precursor, then the composite was converted into the final PSS@HKUST-1 membrane. The produced composite solid membrane thus combined the molecular sieving characteristics with chemical selection functionality.

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The report mainly studies the size, recent trends and development status of the Adsorbent market, as well as investment opportunities, government policy, market dynamics (drivers, restraints, opportunities), supply chain and competitive landscape. Technological innovation and advancement will further optimize the performance of the product, making it more widely used in downstream applications. Moreover, Porter’s Five Forces Analysis (potential entrants, suppliers, substitutes, buyers, industry competitors) provides crucial information for knowing the Adsorbent market.

Completed Task List Activities: Completed Thursday (GMT 150) Adlink SD card move Fundoscope troubleshooting ISS Experience message review ISS Photo Inspections from Cupola, JEM Rodent Research 12 Lab audit

Synthetic zeolites such as those produced by Neometals’ process at bench‐scale, are typically used in more demanding industrial applications such as molecular sieves for natural gas dehydration, air and hydrocarbon purification.

Al-doped LLZTO is one of the most promising solid-state electrolytes due to its high ionic conductivity, excellent chemical stability, super mechanical strength, and desirable electrical insulation (29). LLZTO powders are well dispersed by sonication in tetrahydrofuran (THF) solvent and coated on one side of the commercial PP separator (Celgard 2400) by vacuum filtration. The adopted LLZTO powders exhibit a cubic garnet phase (PDF 80-0457) (fig. S1), whose ionic conductivities are much higher than those of its tetragonal counterparts (30). The dark-field transmission electron microscope (TEM) image indicates that the crystal size of the ceramic particles is around 20 nm (fig. S2). X-ray diffraction (XRD) patterns of the composite electrolytes reveal that the LLZTO layer is integrated to a PP matrix without losing its garnet crystalline structure.