High-rate capable, reversible lithium metal anodes are necessary for next generation energy storage systems. In situ tomography of Li|LLZO|Li cells is carried out to track morphological transformations in Li metal electrodes. Machine learning enables tracking the lithium metal morphology during galvanostatic cycling. Nonuniform lithium electrode kinetics are observed at both electrodes during cycling. Hot spots in lithium metal are correlated with microstructural anisotropy in LLZO. Mesoscale modeling reveals that regions with lower effective properties (transport and mechanical) are nuclei for failure. Advanced visualization combined with electrochemistry represents an important pathway toward resolving non-equilibrium effects that limit rate capabilities of solid-state batteries.
Mollisols
support the most productive agroecosystems in the world.
Despite their critical links to food quality and human health, the
varying distributions of selenium (Se) species and factors governing
Se mobility in the mollisol vadose zone remain elusive. This research
reveals that, in northern mollisol agroecosystems, Se hotspots (≥0.32
mg/kg) prevail along the regional river systems draining the Lesser
Khingan Mountains, where piedmont Se-rich oil shales are the most
probable source of regional Se. While selenate and selenite dominate
Se species in the water-soluble and absorbed pools, mollisol organic
matter is the major host for Se. Poorly crystalline and crystalline
Fe oxides are subordinate in Se retention, hosting inorganic and organic
Se at levels comparable to those in the adsorbed pool. The depth-dependent
distributions of mollisol Se species for the non-cropland and cropland
sites imply a predominance of reduced forms of Se under the mildly
acidic and reducing conditions that, in turn, are variably impacted
by agricultural land use. These findings therefore highlight that
fluvial deposition and land use change together are the main drivers
of the spatial variability and speciation of mollisol Se.
Due to their high reaction rate and reliable selectivity,
bioorthogonal
click reactions have been extensively investigated in numerous research
fields, such as nanotechnology, drug delivery, molecular imaging,
and targeted therapy. Previous reviews on bioorthogonal click chemistry
for radiochemistry mainly focus on 18F-labeling protocols
employed to produce radiotracers and radiopharmaceuticals. In fact,
besides fluorine-18, other radionuclides such as gallium-68, iodine-125,
and technetium-99m are also used in the field of bioorthogonal click
chemistry. Herein, to provide a more comprehensive perspective, we
provide a summary of recent advances in radiotracers prepared using
bioorthogonal click reactions, including small molecules, peptides,
proteins, antibodies, and nucleic acids as well as nanoparticles based
on these radionuclides. The combination of pretargeting with imaging
modalities or nanoparticles, as well as the clinical translations
study, are also discussed to illustrate the effects and potential
of bioorthogonal click chemistry for radiopharmaceuticals.
In the current study, the characteristics of aerosol water-soluble ions (WSI) were investigated via high-time-resolution observations as part of the nineth Chinese National Arctic Research Expedition (CHINARE) in 2018. WSI, including Cl − , SO 4
Reversible lithium metal anodes that can achieve high rate capabilities are necessary for next generation energy storage systems. Solid electrolyte can act as a barrier for unwanted physical and chemical decomposition that lead to unstable electrodeposition (e.g. dendrite and filament growth). The formation and growth of filaments is tied to unique chemo-mechanical properties that exists at buried solid|solid interfaces. Herein,<i> in situ</i> tomography of Li|LLZO|Li cells is carried out to track morphological transformations in Li metal electrodes and buried solid|solid interfaces during stripping and plating processes. Optimized experimental parameters provide high resolution, high contrast reconstructions that enable lithium metal visualization. Machine learning and image processing tools are combined to quantify changes in lithium metal during stripping and plating. The analysis enables quantifying local current densities and pore size distribution in lithium metal during cycling experiments. Hotspots in lithium metal are correlated with microstructural anisotropy in the solid electrolyte. Modeling studies show large heterogeneity in transport and mechanical properties of electrolyte at the electrode|electrolyte interfaces. Regions with lower effective properties (transport and mechanical) are nuclei for failure. Failure is attributed to microstructural heterogeneities in the solid electrolyte that lead to high local stress and flux distributions.
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