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Title: Ordered and disordered polymorphs of Na(Ni2/3Sb1/3)O₂: Honeycomb-ordered cathodes for Na-ion batteries

Journal Article · · Chemistry of Materials
DOI:https://doi.org/10.1021/cm504339y· OSTI ID:1193224
 [1];  [2];  [1];  [3];  [4];  [2]
  1. Stony Brook Univ., Stony Brook, NY (United States)
  2. Brookhaven National Lab. (BNL), Upton, NY (United States)
  3. Brookhaven National Lab. (BNL), Upton, NY (United States); Brookhaven National Lab. (BNL), Upton, NY (United States)
  4. Stony Brook Univ., Stony Brook, NY (United States); Cambridge Univ. (United Kingdom)
+ Show Author Affiliations

Na-ion batteries are appealing alternatives to Li-ion battery systems for large-scale energy storage applications in which elemental cost and abundance are important. Although it is difficult to find Na-ion batteries which achieve substantial specific capacities at voltages above 3 V (vs Na⁺/Na), the honeycomb-layered compound Na(Ni2/3Sb1/3)O₂ can deliver up to 130 mAh/g of capacity at voltages above 3 V with this capacity concentrated in plateaus at 3.27 and 3.64 V. Comprehensive crystallographic studies have been carried out in order to understand the role of disorder in this system which can be prepared in both “disordered” and “ordered” forms, depending on the synthesis conditions. The average structure of Na(Ni2/3Sb1/3)O₂ is always found to adopt an O3-type stacking sequence, though different structures for the disordered (R3¯m, #166, a = b = 3.06253(3) Å and c = 16.05192(7) Å) and ordered variants (C2/m, #12, a = 5.30458(1) Å, b = 9.18432(1) Å, c = 5.62742(1) Å and β = 108.2797(2)°) are demonstrated through the combined Rietveld refinement of synchrotron X-ray and time-of-flight neutron powder diffraction data. However, pair distribution function studies find that the local structure of disordered Na(Ni2/3Sb1/3)O₂ is more correctly described using the honeycomb-ordered structural model, and solid state NMR studies confirm that the well-developed honeycomb ordering of Ni and Sb cations within the transition metal layers is indistinguishable from that of the ordered phase. The disorder is instead found to mainly occur perpendicular to the honeycomb layers with an observed coherence length of not much more than 1 nm seen in electron diffraction studies. When the Na environment is probed through ²³Na solid state NMR, no evidence is found for prismatic Na environments, and a bulk diffraction analysis finds no evidence of conventional stacking faults. The lack of long range coherence is instead attributed to disorder among the three possible choices for distributing Ni and Sb cations into a honeycomb lattice in each transition metal layer. It is observed that the full theoretical discharge capacity expected for a Ni³⁺/²⁺ redox couple (133 mAh/g) can be achieved for the ordered variant but not for the disordered variant (~110 mAh/g). The first 3.27 V plateau during charging is found to be associated with a two-phase O3 ↔ P3 structural transition, with the P3 stacking sequence persisting throughout all further stages of desodiation.

Research Organization:
Brookhaven National Laboratory (BNL), Upton, NY (United States)
Sponsoring Organization:
USDOE Office of Science (SC), Basic Energy Sciences (BES)
Grant/Contract Number:
SC00112704
OSTI ID:
1193224
Report Number(s):
BNL-108109-2015-JA; R&D Project: MA015MACA; KC0201010
Journal Information:
Chemistry of Materials, Vol. 27, Issue 7; ISSN 0897-4756
Publisher:
American Chemical Society (ACS)Copyright Statement
Country of Publication:
United States
Language:
English
Citation Metrics:
Cited by: 91 works
Citation information provided by
Web of Science

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Cited By (22)

Structural and Na-ion conduction characteristics of Na 3 PS x Se 4−x journal January 2016
Layered Oxide Cathodes for Sodium-Ion Batteries: Phase Transition, Air Stability, and Performance journal November 2017
Oxygen Redox Promoted by Na Excess and Covalency in Hexagonal and Monoclinic Na 2−x RuO 3 Polymorphs journal January 2019
Review—Manganese-Based P2-Type Transition Metal Oxides as Sodium-Ion Battery Cathode Materials journal January 2015
Zigzag spin structure in layered honeycomb L i 3 N i 2 Sb O 6 : A combined diffraction and antiferromagnetic resonance study journal July 2017
Commercial Prospects of Existing Cathode Materials for Sodium Ion Storage journal July 2017
Ni-based cathode materials for Na-ion batteries journal June 2019
Routes to High Energy Cathodes of Sodium-Ion Batteries journal December 2015
Stress Distortion Restraint to Boost the Sodium Ion Storage Performance of a Novel Binary Hexacyanoferrate journal December 2019
Synthesis, structure and magnetic properties of honeycomb-layered Li 3 Co 2 SbO 6 with new data on its sodium precursor, Na 3 Co 2 SbO 6 journal January 2019
Micro/Nanostructured Materials for Sodium Ion Batteries and Capacitors journal December 2017
Sodium-Ion Batteries (a Review) journal February 2018
Recent Advances and Prospects of Cathode Materials for Sodium-Ion Batteries journal August 2015
Ni- and/or Mn-based layered transition metal oxides as cathode materials for sodium ion batteries: status, challenges and countermeasures journal January 2019
An Ordered Ni 6 ‐Ring Superstructure Enables a Highly Stable Sodium Oxide Cathode journal September 2019
The top-down synthesis of sequentially controlled architectures for honeycomb-layered Na 3 Ni 2 BiO 6 towards high-voltage and superior performance cathodes for sodium-ion batteries journal January 2019
Effects of Mn‐Doping on the Structural and Electrochemical Properties of Na 3 Ni 2 SbO 6 for Sodium‐Ion Battery. journal January 2020
Advanced Cathode Materials for Sodium-Ion Batteries: What Determines Our Choices? journal April 2017
Zigzag antiferromagnetic quantum ground state in monoclinic honeycomb lattice antimonates A 3 N i 2 Sb O 6 ( A = Li , Na ) journal October 2015
Synthesis, structure and magnetic properties of honeycomb-layered Li3Co2SbO6 with new data on its sodium precursor, Na3Co2SbO6 text January 2020
Electrochemical properties and structural evolution of O3-type layered sodium mixed transition metal oxides with trivalent nickel journal January 2017
Effects of Mn‐doping on the Structural and Electrochemical Properties of Na 3 Ni 2 SbO 6 for Sodium‐Ion Battery journal April 2020

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cathode