Since their successful commercialization in 1990s, lithium-ion batteries (LIBs) have been widely applied in portable digital products. The energy density and power density of LIBs are inadequate, however, to satisfy the continuous growth in demand. Considering the cost distribution in battery system, it is essential to explore cathode/anode materials with excellent rate capability and long cycle life. Nanometer-sized electrode materials could quickly take up and store numerous Li+ ions, afforded by short diffusion channels and large surface area. Unfortunately, low thermodynamic stability of nanoparticles results in electrochemical agglomeration and raises the risk of side reactions on electrolyte. Thus, micro/nano and hetero/hierarchical structures, characterized by ordered assembly of different sizes, phases, and/or pores, have been developed, which enable us to effectively improve the utilization, reaction kinetics, and structural stability of electrode materials. This review summarizes the recent efforts on electrode materials with hierarchical structures, and discusses the effects of hierarchical structures on electrochemical performance in detail. Multidimensional self-assembled structures can achieve integration of the advantages of materials with different sizes. Core/yolk-shell structures provide synergistic effects between the shell and the core/yolk. Porous structures with macro-, meso-, and micropores can accommodate volume expansion and facilitate electrolyte infiltration.

Recent Developments on and Prospects for Electrode Materials with Hierarchical Structures for Lithium-Ion Batteries

https://dr.ntu.edu.sg/bitstream/10356/104510/1/POWER-D-14-00007R1%28edited%29.pdf

Li3V2(PO4)3 cathode materials for lithium-ion batteries: A review

A database of battery materials is presented which comprises a total of 292,313 data records, with 214,617 unique chemical-property data relations between 17,354 unique chemicals and up to five material properties: capacity, voltage, conductivity, Coulombic efficiency and energy. 117,403 data are multivariate on a property where it is the dependent variable in part of a data series. The database was auto-generated by mining text from 229,061 academic papers using the chemistry-aware natural language processing toolkit, ChemDataExtractor version 1.5, which was modified for the specific domain of batteries. The collected data can be used as a representative overview of battery material information that is contained within text of scientific papers. Public availability of these data will also enable battery materials design and prediction via data-science methods. To the best of our knowledge, this is the first auto-generated database of battery materials extracted from a relatively large number of scientific papers. We also provide a Graphical User Interface (GUI) to aid the use of this database. Machine-accessible metadata file describing the reported data: https://doi.org/10.6084/m9.figshare.12646277

/pdf/a-database-of-battery-materials-auto-generated-using-2kb2cqavg5.pdf

A database of battery materials auto-generated using ChemDataExtractor.

Advances in graphene oxide membranes for water treatment

Hydrothermal synthesis of plate-like carbon-coated Li3V2(PO4)3 and its low temperature performance for high power lithium ion batteries

Selective reduction of epoxy groups in graphene oxide membrane for ultrahigh water permeation

Freeze-drying synthesis of Li3V2(PO4)3/C cathode material for lithium-ion batteries

"On-off-on" fluorescence switch of graphene quantum dots: A cationic control strategy

Microstructure, hydrogenation and optical behavior of Mg–Ni multilayer films deposited by magnetron sputtering

Abnormal salt crystals with unconventional stoichiometries, such as Na2 Cl, Na3 Cl, K2 Cl, and CaCl crystals that have been explored in reduced graphene oxide membranes (rGOMs) or diamond anvil cell, hold great promise in applications due to their unique electronic, magnetic, and optical properties predicted in theory. However, the low content of these crystals, only less than 1% in rGOM, limits their research interest and utility in applications. Here, w e report a high-yield synthesis of 2D abnormal crystals with unconventional stoichiometries achieved by applying negative potential on rGOM. W e obtained a more than ten-fold increase in the abnormal Na2 Cl crystals using potential of -0.6 V, resulting in an atomic content of 13.4 ± 4.7% for Na on rGOM. Direct observations by transmission electron microscopy and piezoresponse force microscopy demonstrated a unique piezoelectric behavior arise from 2D Na2 Cl crystals with square structure. The output voltage increased from 0 to ∼180 mV in broad 0°-150° bending angle regime, which meets the voltage requirement of most nanodevices in realistic applications. Density functional theory calculations reveal that the applied negative potential of the graphene surface can strengthen the effect of the Na+ -π interaction and reduce the electrostatic repulsion between cations, making more Na2 Cl crystals formed. This article is protected by copyright. All rights reserved.

High-yield Synthesis of Sodium Chlorides of Unconventional Stoichiometries.

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