Revealing the Intercalation Mechanisms of Lithium,Sodium, and Potassium in Hard Carbon

Hard carbon is the most promising anode material for sodium‐ion batteries and potassium‐ion batteries owing to its high stability, widespread availability, low‐cost, and excellent performance. Understanding the carrier‐ion storage mechanism is a prerequisite for developing high‐performance electrode materials; however, the underlying ion storage mechanism in hard carbon has been a topic of debate because of its complex structure. Herein, it is demonstrated that the Li⁺‐, Na⁺‐, and K⁺‐ion storage mechanisms in hard carbon are based on the adsorption of ions on the surface of active sites (e.g., defects, edges, and residual heteroatoms) in the sloping voltage region, followed by intercalation into the graphitic layers in the low‐voltage plateau region. At a low current density of 3 mA g^–1, the graphitic layers of hard carbon are unlocked to permit Li⁺‐ion intercalation, resulting in a plateau region in the lithium‐ion batteries. To gain insights into the ion storage mechanism, experimental observations including various ex situ techniques, a constant‐current constant‐voltage method, and diffusivity measurements are correlated with the theoretical estimation of changes in carbon structures and insertion voltages during ion insertion obtained using the density functional theory.     

Low‐Cost Hollow Mesoporous Polymer Spheres and All‐Solid‐State Lithium,Sodium Batteries

A practical, low‐cost synthesis of hollow mesoporous organic polymer (HMOP) spheres is reported. The electrochemical properties of Li⁺/Na⁺‐electrolyte membranes with these spheres substituting for oxide filler particles in poly(ethylene oxide) (PEO)‐filler composite are explored. The electrolyte membranes are mechanically robust, thermally stable to over 250 °C, and block dendrites from a metallic‐lithium/sodium anode. The Li⁺/Na⁺ transfer impedance across the lithium/sodium–electrolyte interface is initially acceptable at 65 °C and scavenging of impurities by the porous‐spheres filler lowers this impedance relative to that with Al₂O₃. All‐solid‐state Li/LiFePO₄ and Na/NaTi₂(PO4)₃ cells give stable discharge capacity of ≈130 and 80 mAh g^?1, respectively, at 0.5 C and 65 °C for 100 cycles.     

Designing Safe Electrolyte Systems for a High‐Stability Lithium–Sulfur Battery

Safety, nontoxicity, and durability directly determine the applicability of the essential characteristics of the lithium (Li)‐ion battery. Particularly, for the lithium–sulfur battery, due to the low ignition temperature of sulfur, metal lithium as the anode material, and the use of flammable organic electrolytes, addressing security problems is of increased difficulty. In the past few years, two basic electrolyte systems are studied extensively to solve the notorious safety issues. One system is the conventional organic liquid electrolyte, and the other is the inorganic solid‐state or quasi‐solid‐state composite electrolyte. Here, the recent development of engineered liquid electrolytes and design considerations for solid electrolytes in tackling these safety issues are reviewed to ensure the safety of electrolyte systems between sulfur cathode materials and the lithium‐metal anode. Specifically, strategies for designing and modifying liquid electrolytes including introducing gas evolution, flame, aqueous, and dendrite‐free electrolytes are proposed. Moreover, the considerations involving a high‐performance Li⁺ conductor, air‐stable Li⁺ conductors, and stable interface performance between the sulfur cathode and the lithium anode for developing all‐solid‐state electrolytes are discussed. In the end, an outlook for future directions to offer reliable electrolyte systems is presented for the development of commercially viable lithium–sulfur batteries.     

Lithium ion uptake associated with the stimulation of action potential ionophores of cultured human neuroblastoma cells

Cultured human neuroblastoma cell lines were tested for the action potential sodium ionophore utilizing the Li⁺ ion rather than the ²²Na⁺ ion. The cell lines studied included CHP-134, CHP-100, CHP-126, CHP-212 and LA-N-1. Veratridine-dependent uptake of Li⁺ and ²²Na⁺ and its inhibition by tetrodotoxin implies the presence of the action-potential sodium ionophore. CHP-165, and undifferentiated tumor and RAJI a lymphoblast had no veratridine-dependent Li⁺ uptake. Thus, veratridine-dependent Li⁺ uptake provides a convenient means of assaying human neural cells for the action-potential sodium ionophore without the use of the radioactive Na⁺ ion.     

Lithium Dendrites Inhibition via Diffusion Enhancement

The dendritic structure is a disastrous problem of lithium metal batteries as well as other metal rechargeable batteries. The dendritic structures are usually caused by diffusion limitation. Here, a novel strategy is reported to inhibit lithium dendrites based on the understanding of their formation mechanism. An alternating current field perpendicular to the anode is set up, which promotes Li⁺ movement along the anode surface and prevents ions' deposition on the tips from forming dendrites. Furthermore, an external direct current field parallel to the current is employed, which accelerates the transport of Li⁺ in electrolytes to mitigate the concentration gradient nearby the anode and thus inhibits the formation of dendritic structures. A simultaneous employment of these two fields gains five times increase of the lifespan of batteries at the high charging current density of 2 mA cm^?2, confirming the effectiveness of this strategy in protecting the metal anode and inhibiting lithium dendrites. This strategy may have a wide feasibility since it does not change the materials and structures of batteries.     

Mechanism of Na+ Insertion in Alkali Vanadates and Its Influence on Battery Performance

Sodium‐ion batteries may become an alternative to the widespread lithium‐ion technology due to cost and kinetic advantages provided that cyclability is improved. For this purpose, the interplay between electrochemical and structural processes is key and is demonstrated in this work for Na_2.46V₆O₁₆ (NVO) and Li_2.55V₆O₁₆ employing operando synchrotron X‐ray diffraction. When NVO is cycled between 4.0 and 1.6 V, Na‐ions reversibly occupy two crystallographic sites, which results in remarkable cyclability. Upon discharge to 1.0 V, however, Na‐ions occupy also interstitial sites, inducing irreversible structural change with some loss of crystallinity concomitant with a decrease in capacity. Capacity fading increases with the ionic radius of the alkali ions (K⁺ > Na⁺ > Li⁺), suggesting that smaller ions stabilize the structure. This correlation of structural variation and electrochemical performance suggests a route toward improving cycling stability of a sodium‐ion battery. Its essence is a minor Li⁺‐retention in the A_2+xV₆O₁₆ structure. Even though the majority of Li‐ions are replaced by the abundant Na⁺, the residual Li‐ions (≈10%) are sufficient to stabilize the layered structure, diminishing the irreversible structural damage. These results pave the way for further exploitation of the role of small ions in lattice stabilization that increases cycling performance.     

Insights into the Storage Mechanism of Layered VS2 Cathode in Alkali Metal‐Ion Batteries

VS₂ is one of the attractive layered cathodes for alkali metal‐ion batteries. However, the understanding of the detailed reaction processes and energy storage mechanism is still inadequate. Herein, the Li⁺/Na⁺/K⁺ insertion/extraction mechanisms of VS₂ cathode are elucidated on the basis of experimental analyses and theoretical simulations. It is found that the insertion/extraction behavior of Li⁺ is partially irreversible, while the insertion/extraction behavior of Na⁺/K⁺ is completely reversible. The detailed intermediates and final products (Li_0.33VS₂, LiVS₂, Na_0.5VS₂, NaVS₂, K_0.6VS₂, K_zVS₂, z > 0.6) during the discharging/charging processes are identified, indicating that VS₂ undergoes different phase transitions and solid–solution reactions in different battery systems, which have a great influence on the battery performance. Moreover, the diffusion of Na⁺ in VS₂ cathode is demonstrated to be much slower than that of Li⁺ and K⁺. Such mechanistic research provides a reference for in‐depth understanding of energy storage in layered transition metal sulfides/selenides.     

Ecofriendly Chemical Activation of Overlithiated Layered Oxides by DNA‐Wrapped Carbon Nanotubes

Despite their exceptionally high capacity, overlithiated layered oxides (OLO) have not yet been practically used in lithium‐ion battery cathodes due to necessary toxic/complex chemical activation processes and unsatisfactory electrochemical reliability. Here, a new class of ecofriendly chemical activation strategy based on amphiphilic deoxyribose nucleic acid (DNA)‐wrapped multiwalled carbon nanotubes (MWCNT) is demonstrated. Hydrophobic aromatic bases of DNA have a good affinity for MWCNT via noncovalent π–π stacking interactions, resulting in core (MWCNT)‐shell (DNA) hybrids (i.e., DNA@MWCNT) featuring the predominant presence of hydrophilic phosphate groups (coupled with Na⁺) in their outmost layers. Such spatially rearranged Na⁺–phosphate complexes of the DNA@MWCNT efficiently extract Li⁺ from monoclinic Li₂MnO₃ of the OLO through cation exchange reaction of Na⁺–Li⁺, thereby forming Li₄Mn₅O₁₂‐type spinel nanolayers on the OLO surface. The newly formed spinel nanolayers play a crucial role in improving the structural stability of the OLO and suppressing interfacial side reactions with liquid electrolytes, eventually providing significant improvements in the charge/discharge kinetics, cyclability, and thermal stability. This beneficial effect of the DNA@MWCNT‐mediated chemical activation is comprehensively elucidated by an in‐depth structural/electrochemical characterization.     

Vertically Oriented MoS2 with Spatially Controlled Geometry on Nitrogenous Graphene Sheets for High‐Performance Sodium‐Ion Batteries

Inspired by the great success of graphite in lithium‐ion batteries, anode materials that undergo an intercalation mechanism are considered to provide stable and reversible electrochemical sodium‐ion storage for sodium‐ion battery (SIB) applications. Though MoS₂ is a promising 2D material for SIBs, it suffers from deformation of its layered structure during repeated intercalation of Na⁺, resulting in undesirable electrochemical behaviors. In this study, vertically oriented MoS₂ on nitrogenous reduced graphene oxide sheets (VO‐MoS₂/N‐RGO) is presented with designed spatial geometries, including sheet density and height, which can deliver a remarkably high reversible capacity of 255 mA h g^?1 at a current density of 0.2 A g^?1 and 245 mA h g^?1 at a current density of 1 A g^?1, with a total fluctuation of 5.35% over 1300 cycles. These results are superior to those obtained with well‐developed hard carbon structures. Furthermore, a SIB full cell composed of the optimized VO‐MoS₂/N‐RGO anode and a Na₂V₃(PO₄)₃ cathode reaches a specific capacity of 262 mA h g^?1 (based on the anode mass) during 50 cycles, with an operated voltage range of 2.4 V, demonstrating the potentially rewarding SIB performance, which is useful for further battery development.     

Hybrid and Aqueous Lithium‐Air Batteries

Lithium‐air (Li‐air) batteries have become attractive because of their extremely high theoretical energy density. However, conventional Li‐air cells operating with non‐aqueous electrolytes suffer from poor cycle life and low practical energy density due to the clogging of the porous air cathode by insoluble discharge products, contamination of the organic electrolyte and lithium metal anode by moist air, and decomposition of the electrolyte during cycling. These difficulties may be overcome by adopting a cell configuration that consists of a lithium‐metal anode protected from air by a Li⁺‐ion solid electrolyte and an air electrode in an aqueous catholyte. In this type of configuration, a Li⁺‐ion conducting “buffer” layer between the lithium‐metal anode and the solid electrolyte is often necessary due to the instability of many solid electrolytes in contact with lithium metal. Based on the type of buffer layer, two different battery configurations are possible: “hybrid” Li‐air batteries and “aqueous” Li‐air batteries. The hybrid and aqueous Li‐air batteries utilize the same battery chemistry and face similar challenges that limit the cell performance. Here, an overview of recent developments in hybrid and aqueous Li‐air batteries is provided and the factors that influence their performance and impede their practical applications, followed by future directions are discussed.     

An Anion‐Tuned Solid Electrolyte Interphase with Fast Ion Transfer Kinetics for Stable Lithium Anodes

The spatial distribution and transport characteristics of lithium ions (Li⁺) in the electrochemical interface region of a lithium anode in a lithium ion battery directly determine Li⁺ deposition behavior. The regulation of the Li⁺ solvation sheath on the solid electrolyte interphase (SEI) by electrolyte chemistry is key but challenging. Here, 1 m lithium trifluoroacetate (LiTFA) is induced to the electrolyte to regulate the Li⁺ solvation sheath, which significantly suppresses Li dendrite formation and enables a high Coulombic efficiency of 98.8% over 500 cycles. With its strong coordination between the carbonyl groups (C?O) and Li⁺, TFA^? modulates the environment of the Li⁺ solvation sheath and facilitates fast desolvation kinetics. In addition, due to relatively smaller lowest unoccupied molecular orbital energy than solvents, TFA^? has a preferential reduction to produce a stable SEI with uniform distribution of LiF and Li₂O. Such stable SEI effectively reduces the energy barrier for Li⁺ diffusion, contributing to low nucleation overpotential, fast ion transfer kinetics, and uniform Li⁺ deposition with high cycling stability. This work provides an alternative insight into the design of interface chemistry in terms of regulating anions in the Li⁺ solvation sheath. It is anticipated that this anion‐tuned strategy will pave the way to construct stable SEIs for other battery systems.     

SnO2 as Advanced Anode of Alkali‐Ion Batteries: Inhibiting Sn Coarsening by Crafting Robust Physical Barriers,Void Boundaries,and Heterophase Interfaces for Superior Electrochemical Reaction Reversibility

Superior reaction reversibility of electrode materials is urgently pursued for improving the energy density and lifespan of batteries. Tin dioxide (SnO₂) is a promising anode material for alkali‐ion batteries, having a high theoretical lithium storage capacity of 1494 mAh g^? based on the reactions of SnO₂ + 4Li⁺ + 4e^? ? Sn + 2Li₂O and Sn + 4.4Li⁺ + 4.4e^? ? Li_4.4Sn. The coarsening of Sn nanoparticles into large particles induced reaction reversibility degradation has been demonstrated as the essential failure mechanism of SnO₂ electrodes. Here, three key strategies for inhibiting Sn coarsening to enhance the reaction reversibility of SnO₂ are presented. First, encapsulating SnO₂ nanoparticles in physical barriers of carbonaceous materials, conductive polymers or inorganic materials can robustly prevent Sn coarsening among the wrapped SnO₂ nanoparticles. Second, constructing hierarchical, porous or hollow structured SnO₂ particles with stable void boundaries can hinder Sn coarsening between the void‐divided SnO₂ subunits. Third, fabricating SnO₂‐based heterogeneous composites consisting of metals, metal oxides or metal sulfides can introduce abundant heterophase interfaces in cycled electrodes that impede Sn coarsening among the isolated SnO₂ crystalline domains. Finally, a perspective on the future prospect of the structural/compositional designs of SnO₂ as anode of alkali‐ion batteries is highlighted.     

Study of Na+ and Water Transport in the Pigeon and Chicken Kidney by Lithium Clearance Method under Conditions of Water and Salt Load: Regimes of Renal Net Reabsorption and Net Secretion of Li+

The water (intestinally) and salt (intravenously) loads of a sufficient intensity (about 120 ml water or 9 mmol NaCl per kg body mass) caused a reversible conversion (of duration of 30–40 min) in the renal Li transport, i.e., transition from net reabsorption of this ion (FE_Li = C_Li/GFR < 1) to its net secretion (FE_Li > 1), where C_Li—lithium clearance, GFR—glomerular filtration rate, ⁶⁵ZnDTPA clearance. Maximal values of the fractional lithium excretion (FE_Li) amounted to about 1.5 and 2.0 after the water and salt loads, respectively. A repeated salt load (4–5 NaCl injections by 9 mmol/kg at 20–40 min intervals) induced a long (2–3 h) net secretion of lithium in the chicken kidney. This regime of renal functioning was characterized by abundant urination (20–30 ml/kg/h) and a substantial increase of the Na⁺ concentration in blood plasma (from 138 ± 9 to 172 ± 10 mM, the mean ( standard deviation) and in urine (to 157 ± 19 mM). The data obtained were considered in terms of a hypothesis suggesting that the renal lithium secretion indicates the appearance of net water and Na⁺ secretion in the proximal tubule of the avian kidney in response to water and salt load. The fractional reabsorption of Na⁺ and water in the chicken kidney were calculated by means of lithium clearance during both the net reabsorption and the secretion of lithium in the kidney. In the former regime of renal functioning (FE_Li < 1), regardless of changes in lithium reabsorption (up to its complete cessation at FE_Li = 1), the kidney as a whole reabsorbs about 99% of filtered Na⁺, while distal reabsorption of this ion accounts for about 98%. The corresponding values for water reabsorption are about 96 and 92%, respectively. At FE_Li > 1, the fractional reabsorption of Na⁺ and water decrease significantly: the minimal values amount to about 60%, while the mean values, about 80%.     

Lithium induced changes in intracellular free magnesium concentration in isolated rat ventricular myocytes

We have examined the effect of exposing isolated rat ventricular myocytes to lithium while measuring cytosolic free magnesium ([Mg²⁺]_i) and calcium ([Ca²⁺]_i) levels with the fluorescent, ion sensitive probes mag-fura-2 and fura-2. There was a significant rise in [Mg²⁺]_i after a 5 min exposure to a solution in which 50% of the sodium had been replaced by Li⁺, but not when the sodium had been replaced by bis-dimethylammonium (BDA). However, there were significant increases in [Ca²⁺]_i when either Na⁺ substitute was used. The possibility that Li⁺, which enters the cells, interferes with the signal from mag-fura-2 was eliminated as Li⁺ concentrations up to 10 mM had no effect on the dye's fluorescence signal. A possible explanation for these findings is that Li⁺ displaces Mg²⁺ from intracellular binding sites. Having considered the binding constants for Mg²⁺ and Li⁺ to ATP, we conclude that Li⁺ can displace Mg²⁺ from Mg-ATP, thus causing a rise in [Mg²⁺]_i. This work has implications for other studies where Li⁺ is used as a Na⁺ substitute.     

Lithium/Oxygen Incorporation and Microstructural Evolution during Synthesis of Li‐Rich Layered Li[Li0.2Ni0.2Mn0.6]O2 Oxides

As promising cathode materials, the lithium‐excess 3d‐transition‐metal layered oxides can deliver much higher capacities (>250 mAh g^?1 at 0.1 C) than the current commercial layered oxide materials (≈180 mAh g^?1 at 0.1 C) used in lithium ion batteries. Unfortunately, the original formation mechanism of these layered oxides during synthesis is not completely elucidated, that is, how is lithium and oxygen inserted into the matrix structure of the precursor during lithiation reaction? Here, a promising and practical method, a coprecipitation route followed by a microwave heating process, for controllable synthesis of cobalt‐free lithium‐excess layered compounds is reported. A series of the consistent results unambiguously confirms that oxygen atoms are successively incorporated into the precursor obtained by a coprecipitation process to maintain electroneutrality and to provide the coordination sites for inserted Li ions and transition metal cations via a high‐temperature lithiation. It is found that the electrochemical performances of the cathode materials are strongly related to the phase composition and preparation procedure. The monoclinic layered Li[Li_0.2Ni_0.2Mn_0.6]O₂ cathode materials with state‐of‐the‐art electrochemical performance and comparably high discharge capacities of 171 mAh g^?1 at 10 C are obtained by microwave annealing at 750 °C for 2 h.     

A tracer method to study unidirectional fluxes of lithium: Application to frog skin

We describe a new tracer method to measure unidirectional fluxes of Li⁺, despite the lack of any utilizable radioisotope of lithium. This method uses the purified stable isotopes, ⁶Li and ⁷Li, detected with an ion-probe microanalyser. The accuracy is comparable to that obtained for other ions (e.g., Na⁺) with radiotracers.The method has been applied to frog skin with both faces bathed in a 20% lithium/80% sodium medium. Sodium and lithium unidirectional fluxes have been measured simultaneously. The results are consistent with lithium being actively pumped, the outflux of lithium being, however, much larger than that of sodium.     

Li/Na exchange and Li active transport in human lymphoid cells U937 cultured in lithium media

Lithium transport across the cell membrane is interesting in the light of general cell physiology and because of its alteration during numerous human diseases. The mechanism of Li⁺ transfer has been studied mainly in erythrocytes with a slow kinetics of ion exchange and therefore under the unbalanced ion distribution. Proliferating cultured cells with a rapid ion exchange have not been used practically in study of Li⁺ transport. In the present paper, the kinetics of Li⁺ uptake and exit, as well as its balanced distribution across the plasma membrane of U937 cells, were studied at minimal external Li⁺ concentrations and after the whole replacement of external Na⁺ for Li⁺. It is found that a balanced Li⁺ distribution attained at a high rate similar to that for Na⁺ and Cl^? and that Li⁺/Na⁺ discrimination under balanced ion distribution at 1–10 mM external Li⁺ stays on 3 and drops to 1 following Na, K-ATPase pump blocking by ouabain. About 80% of the total Li⁺ flux across the plasma membrane under the balanced Li⁺ distribution at 5 mM external Li⁺ accounts for the equivalent Li⁺/Li⁺ exchange. The majority of the Li⁺ flux into the cell down the electrochemical gradient is a flux through channels and its small part may account for the NC and NKCC cotransport influxes. The downhill Li⁺ influxes are balanced by the uphill Li⁺ efflux involved in Li⁺/Na⁺ exchange. The Na⁺ flux involved in the countertransport with the Li⁺ accounts for about 0.5% of the total Na⁺ flux across the plasma membrane. The study of Li⁺ transport is an important approach to understanding the mechanism of the equivalent Li⁺/Li⁺/Na⁺/Na⁺ exchange, because no blockers of this mode of ion transfer are known and it cannot be revealed by electrophysiological methods. Cells cultured in the medium where Na⁺ is replaced for Li⁺ are recommended as an object for studying cells without the Na,K-ATPase pump and with very low intracellular Na⁺ and K⁺ concentration.     

DFT study of the interaction of cytidine and 2′-deoxycytidine with Li, Na, and K: effects of metal cationization on sugar puckering and stability of the N-glycosidic bond

Density functional theory (DFT) calculations were performed at the B3LYP level with a 6-311++G(d,p) basis set to systematically explore the geometrical multiplicity and binding strength for complexes formed by Li⁺, Na⁺, and K⁺ with cytidine and 2′-deoxycytidine. All computational studies indicate that the metal ion affinity (MIA) decreases from Li⁺ to Na⁺ and K⁺ for cytosine nucleosides. For example, for cytidine the affinity for the above metal ions are 79.5, 55.2, and 41.8 and for 2′-deoxycytidine, 82.8, 57.4, and 42.2 kcal/mol, respectively. It is also interesting to mention that linear correlations between calculated MIA values and the atomic numbers (Z) of the above metal ions were found. The influence of metal cationization on the coordination modes and the strength of the N-glycosidic bond in cytosine nucleosides have been studied. In all cases, the N1-C1′ bond distance changes upon introducing a positive charge in the nucleosides. It has been found that metal binding significantly changes the values of the phase angle of pseudorotation P in the sugar unit of these nucleosides. With respect to the sugar ring, metal binding changes the values of the glycosyl torsion angle and sugar ring conformation. The present calculations in the gas phase provide the first clues on the intrinsic chemistry of these systems and may be of value for studies of the influence of metal cations on the conformational behavior and function of nucleic acids.     

Partially Reduced Holey Graphene Oxide as High Performance Anode for Sodium‐Ion Batteries

The current Na⁺ storage performance of carbon‐based materials is still hindered by the sluggish Na⁺ ion transfer kinetics and low capacity. Graphene and its derivatives have been widely investigated as electrode materials in energy storage and conversion systems. However, as anode materials for sodium‐ion batteries (SIBs), the severe π–π restacking of graphene sheets usually results in compact structure with a small interlayer distance and a long ion transfer distance, thus leading to low capacity and poor rate capability. Herein, partially reduced holey graphene oxide is prepared by simple H₂O₂ treatment and subsequent low temperature reduction of graphene oxide, leading to large interlayer distance (0.434 nm), fast ion transport, and larger Na⁺ storage space. The partially remaining oxygenous groups can also contribute to the capacity by redox reaction. As anode material for SIBs, the optimized electrode delivers high reversible capacity, high rate capability (365 and 131 mAh g^?1 at 0.1 and 10 A g^?1, respectively), and good cycling performance (163 mAh g^?1 after 3000 cycles at a current density of 2 A g^?1), which is among the best reported performances for carbon‐based SIB anodes.