Calcium‐metal batteries (CMBs) provide a promising option for high‐energy and cost‐effective energy‐storage technology beyond the current state‐of‐the‐art lithium‐ion batteries. Nevertheless, the development of room‐temperature CMBs is significantly impeded by the poor reversibility and short lifespan of the calcium‐metal anode. A solvation manipulation strategy is reported to improve the plating/stripping reversibility of calcium‐metal anodes by enhancing the desolvation kinetics of calcium ions in the electrolyte. The introduction of lithium salt changes the electrolyte structure considerably by reducing coordination number of calcium ions in the first solvation shell. As a result, an unprecedented Coulombic efficiency of up to 99.1 % is achieved for galvanostatic plating/stripping of the calcium‐metal anode, accompanied by a very stable long‐term cycling performance over 200 cycles at room temperature. This work may open up new opportunities for development of practical CMBs.
Mapping out the high-dimensional state space would be valuable for better understanding the multistate quantum systems. Here, we demonstrate that highdimensional spin state space can be mapped onto a tensor diagram in full dimension or self-similarly onto the reduced base state space. Based on the tensor diagram, a modular approach is proposed to construct spin eigenfunctions taking the basis of the lowerdimensional space as modules. The implementation of the approach on exciton pair states results in 16 spin eigenstates including 2 singlet states, 3 triplet states, and 1 quintet state with proper symmetry, in contrast to the ones generated using the conventional branching diagram method. The corresponding state energies obtained show the order of spin eigenstates reverses with respect to spin multiplicity. Interestingly, the state space can be decomposed into three subspaces corresponding to the singlet−singlet pair, singlet−triplet pair, and triplet−triplet pair, resulting in a modular structure that is invariant as intermolecular interactions diminish. The proposed approach offers a new perspective on the state space structure of multiple spin states, featuring a hierarchical symmetry, which could be extended to general high-dimensional quantum multistate systems.
Calcium‐metal batteries (CMBs) provide a promising option for high‐energy and cost‐effective energy‐storage technology beyond the current state‐of‐the‐art lithium‐ion batteries. Nevertheless, the development of room‐temperature CMBs is significantly impeded by the poor reversibility and short lifespan of the calcium‐metal anode. A solvation manipulation strategy is reported to improve the plating/stripping reversibility of calcium‐metal anodes by enhancing the desolvation kinetics of calcium ions in the electrolyte. The introduction of lithium salt changes the electrolyte structure considerably by reducing coordination number of calcium ions in the first solvation shell. As a result, an unprecedented Coulombic efficiency of up to 99.1 % is achieved for galvanostatic plating/stripping of the calcium‐metal anode, accompanied by a very stable long‐term cycling performance over 200 cycles at room temperature. This work may open up new opportunities for development of practical CMBs.
Fully understanding
of multistate quantum systems could become
formidable if not impossible as the system dimensionality increases.
One ideal strategy to comprehend complex systems is to transform the
system representation into a more structural one so that major characteristics,
connections, and even underlying mechanisms can stand out from the
huge unstructured information, e.g., the construction of spin eigenfunctions
for a system of multiple spins through the diagonalization of the
system Hamiltonian matrix. Here, instead of direct matrix diagonalization,
the recently developed modular tensor diagram approach is applied
to reorganize the state space structure of multispin systems, extending
previous investigations on exciton pair states to exciton trimer states.
This implementation demonstrates that the proposed approach not only
provides a systematical way to transform the high dimensional multistate
system into a well organized structure based on basic (exciton) modules
but also paves the way to further analysis on potential applications.
For example, the analysis on the state space of the exciton trimer
system suggests a possible scheme to improve the laser performance
via single fission involving multiexcitations and/or multiple fission
steps.
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