Electrochemistry of Hollandite α-MnO<sub>2</sub>: Li-Ion and Na-Ion Insertion and Li<sub>2</sub>O Incorporation

Tompsett, David A.; Islam, M. Saïful

doi:10.1021/cm400864n

Cited by 178 publications

(225 citation statements)

References 72 publications

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“…[43] Sodium intercalation is predicted to be thermodynamically favorable with negative formation energy in three sodium insertion steps with voltages of 3.34 V, 2.84 V, and 2.19 V vs Na + /Na. [44] A low migration barrier of 0.48 eV is also favorable for fast sodium diffusion, indicating fast charging/discharging processes. Recently, Su et al reported b-MnO 2 nanorods with exposed {111} crystal planes with a high density of (1 × 1) tunnels for effective Na-ion insertion and extraction, exhibiting a good electrochemical performance with a high initial Na-ion storage capacity of 350 mA h g −1 and a satisfactory high-rate capability for cathode of SIBs.…”

Section: Metal Oxides Mo Xmentioning

confidence: 99%

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

et al. 2017

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lithium with cheaper alternatives might make future batteries less susceptible to price fluctuations when the market expands. [5] This concern has in turn spawned a flurry of research activity to look beyond LIB technology. In view of the various rechargeable batteries, sodiumion batteries (SIBs) that consist of a main element of seawater made their presence felt in the battery industry due to their chemical similarity (e.g., only 0.3 V more positive than lithium) but higher abundance compared to lithium, [6] as illustrated in Table 1. SIBs work in the same way as LIBs in that they involve the reversible migration of cations/anions across a separator toward the electrodes to realize voltage-driven electrochemical reactions. [7] The upward trend for sodium-ion battery research is driven by the concern over the scarcity and price rise of lithium. Hence, these major merits, as well as the suitable redox potential (E = 0.3 V vs Li) make the SIB an appropriate choice as a rechargeable battery system.In fact, SIBs started almost in parallel with LIBs in the 1980s but the development of LIBs eventually eclipsed SIBs due to the electrochemical performances of SIBs. [8,9] A major obstacle is that it is difficult to get a sodium host material with comparable operating voltage and capacity as the LIB analogs. Firstly, the larger Na + radius (0.98 Å) than that of Li + (0.69 Å) leads to the kinetically sluggish Na + insertion/extraction and transport cross the host-material framework, which will always make the specific capacity and rate capacity largely degraded. [10] Secondly, the larger volume expansion caused by Na + insertion will also bring a change in the phase and lattice of the host materials, making it difficult to achieve a favorable electrochemical stability compared with the LIB counterparts. [11] In addition, they also suffer from a lower specific energy than LIBs, due to the lower potential and larger atomic weight of sodium. It is still a challenge to build an affordable Na-host materials endowed with a high specific energy (e.g., 500 W h kg −1 in LIBs). [12] Recently, the topic of SIBs was revisited in the hope of exploring possible ways to overcome the concerns about the low energy density and poor cycling life of SIBs.In spite of the above distinct drawbacks, SIBs can actually behave slightly differently in some chemical aspects. For instance, sodium does not react with aluminum, which is contrary to the alloying tendency of lithium. In the commercial market, manufacturers could appreciate this "inertness" to reduce the production cost of batteries by substituting the Among the various energy solutions, lithium-ion batteries (LIBs) play an important role in the process of the transition from fossil fuels to renewables. However, the necessity to replace lithium with cheaper alternatives due to its scarcity has recently attracted great interest to developing sodium-ion batteries (SIBs). Hence, the discovery and development of suitable cathode materials that exhibit high specific capacity, good cycling stabil...

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Section: Metal Oxides Mo Xmentioning

confidence: 99%

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

et al. 2017

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“…Cryptomelane α-MnO2 polymorph is an attractive electrode material for lithium batteries due to its low cost, environmental friendliness and natural abundance but suffers from low electronic conductivity [31,32]. Nanotechnology has recently been employed as another route to enhance the electrochemical properties of MnO2 cathode materials for rechargeable batteries [33][34][35], so that capacities of ca.…”

Section: Manganese Dioxidementioning

confidence: 99%

Nanotechnology of Positive Electrodes for Li-Ion Batteries

et al. 2017

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Abstract:This work presents the recent progress in nanostructured materials used as positive electrodes in Li-ion batteries (LIBs). Three classes of host lattices for lithium insertion are considered: transition-metal oxides V 2 O 5 , α-NaV 2 O 5 , α-MnO 2 , olivine-like LiFePO 4 , and layered compounds LiNi 0.55 Co 0.45 O 2 , LiNi 1/3 Mn 1/3 Co 1/3 O 2 and Li 2 MnO 3 . First, a brief description of the preparation methods shows the advantage of a green process, i.e., environmentally friendliness wet chemistry, in which the synthesis route using single and mixed chelators is used. The impact of nanostructure and nano-morphology of cathode material on their electrochemical performance is investigated to determine the synthesis conditions to obtain the best electrochemical performance of LIBs.

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“…b) Author to whom correspondence should be addressed. Electronic mail: gceder@berkeley.edu community and specifically in battery research, NEB has been applied successfully to address Li [17][18][19][20][21][22] and multivalent ion [23][24][25][26]66,67 diffusion in a multitude of cathode materials and ionic conductors. 27,28 In a NEB calculation, a group of images (replicas) of the system is interpolated between the initial and final states.…”

Section: Introductionmentioning

confidence: 99%

An efficient algorithm for finding the minimum energy path for cation migration in ionic materials

Rong

Kitchaev

Canepa

et al. 2016

The Journal of Chemical Physics

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A climbing image nudged elastic band method for finding saddle points and minimum energy paths The Journal of Chemical Physics 113, 9901 (2000) In this work, we propose a new scheme to accelerate NEB calculations through an improved path initialization and associated energy estimation workflow. We demonstrate that for cation migration in an ionic framework, initializing the diffusion path as the minimum energy path through a static potential built upon the DFT charge density reproduces the true NEB path within a 0.2 Å deviation and yields up to a 25% improvement in typical NEB runtimes. Furthermore, we find that the locally relaxed energy barrier derived from this initialization yields a good approximation of the NEB barrier, with errors within 20 meV of the true NEB value, while reducing computational expense by up to a factor of 5. Finally, and of critical importance for the automation of migration path calculations in high-throughput studies, we find that the new approach significantly enhances the stability of the calculation by avoiding unphysical image initialization. Our algorithm promises to enable efficient calculations of diffusion pathways, resolving a long-standing obstacle to the computational screening of intercalation compounds for Li-ion and multivalent batteries. C 2016 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license

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Electrochemistry of Hollandite α-MnO₂: Li-Ion and Na-Ion Insertion and Li₂O Incorporation

Cited by 178 publications

References 72 publications

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

Nanotechnology of Positive Electrodes for Li-Ion Batteries

An efficient algorithm for finding the minimum energy path for cation migration in ionic materials

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Electrochemistry of Hollandite α-MnO2: Li-Ion and Na-Ion Insertion and Li2O Incorporation

Cited by 178 publications

References 72 publications

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

Advanced Cathode Materials for Sodium‐Ion Batteries: What Determines Our Choices?

Nanotechnology of Positive Electrodes for Li-Ion Batteries

An efficient algorithm for finding the minimum energy path for cation migration in ionic materials

Contact Info

Product

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Electrochemistry of Hollandite α-MnO₂: Li-Ion and Na-Ion Insertion and Li₂O Incorporation