Abstract:
The upcoming Na-ion battery system still lacks in terms of a safe, electrochemically stable and high 'ratecapable' anode material. Against this backdrop, we report here the development of bi-phase Na-titanate based composite, which satisfies the above requirements and displays exceptionally high rate-capability, along with long-term cyclic stability even at very high current densities. 'Bi-phase NTO', having Na2Ti3O7 and Na(2)Ti(6)O(13 )in similar to 2:1 ratio (as formed in situ during synthesis), shows contributions from both the phases towards electrochemical Na-storage (as cross-confirmed by operand degrees synchrotron XRD), with reversible sodiation of Na2Ti6O13 component being > 1 Na-ion per-formula-unit. 'Bi-phase NTO' also has favorable Na-insertion/removal potential w.r.t. operation as anode, as well as safety aspects, and is electrochemically more stable than Na2Ti3O7. Furthermore, addition of functionalized multi-walled carbon nanotubes bestows 'bi-phase NTO' with reversible Na-storage capacity of similar to 162 mAh g(-1) at C/5, excellent stability of 'charge-averaged' discharge/charge voltages and negligible impedance build-up over multiple cycles. More importantly, even at 50C, 1st cycle reversible capacity of > 140 mAh g(-1) is obtained, with stable capacity retention (up to 2000 cycles), including negligible fade from the 300th cycle onward; indicating feasibility for long-term cycling even at very high current densities. Overall, this development will allow addressing the major concerns associated with the Na-ion battery system. (C) 2020 Elsevier Ltd. All rights reserved.