Direct Observation of Alternating Octahedral and Prismatic Sodium Layers in O3‐Type Transition Metal Oxides

Kim, Jae Chul; Kwon, Deok‐Hwang; Yang, Julia H.; Kim, Hyunchul; Bo, Shou‐Hang; Seo, Dong‐Hwa; Shi, Tan; Wang, Jingyang; Zhu, Yimei; Ceder, Gerbrand

doi:10.1002/aenm.202001151

Cited by 47 publications

(40 citation statements)

References 50 publications

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“…Broad diffraction lines observed for the O1 phase suggest the presence of stacking faults along the c-axis direction. For other O3 phases, e.g., Na y Ni 1/3-Fe 1/3 Mn 1/3 O 2[46] and Na y Ti 0.25 Fe 0.25 Co 0.25 Ni 0.25 O 2[47], the formation of an OP2 phase (a sequence of ABCA), which contains alternating octahedral and prismatic sites for sodium ion layers, is evidenced. This phase is regarded as the intergrown layered material of P3-and O1-type structures.…”

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confidence: 97%

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

et al. 2021

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The development of an energy storage system with abundant elements is a key challenge for a sustainable society, and the interest of Na intercalation chemistry is extending throughout the research community. Herein, the impact of Ti integration into NaMnO2 in a binary system of x NaMnO2–(1–x) TiO2 (0.5≤x≤1) is systematically examined for rechargeable Na battery applications. Stoichiometric NaMnO2, which is classified as an in-plane distorted O′3-type layered structure, delivers a large initial discharge capacity of approximately 200 mAh g-1, but insufficient capacity retention is observed, most probably associated with dissolution of Mn ions on electrochemical cycles. Ti-substituted samples show highly improved electrode performance as electrode materials. However, the appearance of a sodium-deficient phase, Na4Mn4Ti5O18 with a tunnel-type structure, is observed for Ti-rich phases. Among the samples in this binary system, Na0.8Mn0.8Ti0.2O2 (x=0.8), which is a mixture of a partially Ti-substituted O′3-type layered oxide (Na0.88Mn0.88Ti0.12O2) and tunnel-type Na4Mn4Ti5O18 as a minor phase elucidated by Rietveld analysis on both neutron and X-ray diffraction patterns, shows good electrode performance on the basis of energy density and cyclability. Both phases are electrochemically active as evidenced by in situ X-ray diffraction study, and the improvement of reversibility originates from the suppression of Mn dissolution on electrochemical cycles. From these results, the feasibility of Mn-based electrode materials for high-energy rechargeable Na batteries made from only abundant elements is discussed in detail.

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confidence: 97%

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

et al. 2021

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“…The reasons for the phase transition can be summarized as follows: 1) the slip of the TM layer, [ 35 ] 2) the transformation of Na + vacancy ordering, [ 36 ] and 3) the Jahn–Teller effect. [ 23 ] Compared with the NaClO 4 ‐based cell, the plateau in the NaPF 6 ‐based cell is shorter and the polarization is smaller. It indicates an alleviated effect of phase transition for NaPF 6 ‐based cells.…”

Section: Resultsmentioning

confidence: 99%

“…[22] Owing to the strong corrosiveness of NaTFSI to the current collector, most literatures have used NaPF 6 and NaClO 4 as sodium salt in electrolytes to study various properties of cathode materials. [23][24][25][26][27][28][29] For example, researchers have used NaPF 6 -and NaClO 4 -based electrolytes to study the degradation mechanism of layered cathode materials, respectively. [19,31] However, there are few comparative studies about specific mechanism of these two commonly used electrolytes on cathode surface.…”

Section: Introductionmentioning

confidence: 99%

Selection of Sodium Salt Electrolyte Compatible with Na_0.67Ni_0.15Fe_0.2Mn_0.65O₂ Cathode for Sodium‐Ion Batteries

Wang

Fan

et al. 2021

Energy Tech

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The construction of an optimized electrolyte system compatible with layered transition metal (TM) oxides is of great importance to advanced sodium‐ion batteries (SIBs). Herein, a low‐cost iron‐containing manganese‐based layered cathode material of Na0.67Ni0.15Fe0.2Mn0.65O2 (N‐NFM) is prepared through an improved coprecipitation method. Then, the chemical properties of interfaces between the N‐NFM cathode and organic liquid electrolytes based on NaClO4 and NaPF6 are investigated, respectively. Results show that the cathode electrolyte interphase (CEI) film formed in the NaPF6‐based electrolyte is dense and uniform, which inhibits the dissolution of TM ions effectively and provides a low energy barrier for the transport of Na+. Apart from that the CEI film formed in the NaClO4‐based electrolyte contains more organic but less inorganic compounds, resulting in an increase in impedance. In addition, it is believed that the stability of the CEI film is susceptible to the perchlorate with strong oxidizing property. In this role, a small part of the CEI film falls from the cathode surface, accelerating the dissolution of TM ions and leading to the reactivation of electrolyte decomposition.

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“…Density functional theory (DFT) calculations have been adopted to provide an atomistic explanation of the enhancement of electrochemical kinetics. [91][92][93][94][95] As shown in the band diagram in Figure 2a-c, the conduction and valence band energy levels of materials can be calculated; their difference triggers electron flow in one direction, resulting in built-in electric field at the interface (Figure 2d), which facilitates electron transport. [96] A study by Wang et al theoretically calculated the adsorption energy between alkali-ions and host materials (Co 0.85 Se and S-doped Co 0.85 Se).…”

Section: Atomistic Explanation Of the Heterointerface Effectmentioning

confidence: 99%

Recent Advances in Heterostructured Anode Materials with Multiple Anions for Advanced Alkali‐Ion Batteries

Park

Kim

et al. 2021

Advanced Energy Materials

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in 2019. He is currently doing his postdoctoral research in Prof. Yun Chan Kang's group at Korea University. His research interest focuses on the design, synthesis, and characterization of the nanostructured materials for energy storage, catalyst, and biomaterials.Jin-Sung Park is a Ph.D. candidate at Korea University under the supervision of Prof. Yun Chan Kang. He received his bachelor's degree from the Department of Materials Science and Engineering, Korea University in 2015. His current research focuses on the design and synthesis of nanostructured materials for energy storage applications.

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Direct Observation of Alternating Octahedral and Prismatic Sodium Layers in O3‐Type Transition Metal Oxides

Cited by 47 publications

References 50 publications

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

Selection of Sodium Salt Electrolyte Compatible with Na_0.67Ni_0.15Fe_0.2Mn_0.65O₂ Cathode for Sodium‐Ion Batteries

Recent Advances in Heterostructured Anode Materials with Multiple Anions for Advanced Alkali‐Ion Batteries

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Direct Observation of Alternating Octahedral and Prismatic Sodium Layers in O3‐Type Transition Metal Oxides

Cited by 47 publications

References 50 publications

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO 2

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO 2

Selection of Sodium Salt Electrolyte Compatible with Na0.67Ni0.15Fe0.2Mn0.65O2 Cathode for Sodium‐Ion Batteries

Recent Advances in Heterostructured Anode Materials with Multiple Anions for Advanced Alkali‐Ion Batteries

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Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

Efficient Stabilization of Na Storage Reversibility by Ti Integration into O′3-Type NaMnO ₂

Selection of Sodium Salt Electrolyte Compatible with Na_0.67Ni_0.15Fe_0.2Mn_0.65O₂ Cathode for Sodium‐Ion Batteries