We developed a bifunctional electrode of Pr 0.8 Sr 1.2 (Fe,Ni) 0.8 Nb 0.2 O 4−δ (R.P.PSFNNb) fashioned with in situ exsolved Ni-Fe alloy nanoparticles (NPs) for electrochemical oxidations of H 2 , CO, and syngas as well as CO 2 electrolysis. The NiFe-R.P.PSFNNb was prepared by in situ phase transition of Pr 0.4 Sr 0.6 Fe 0.8 Ni 0.1 Nb 0.1 O 3−δ (PSFNNb) along with exsolution of Ni-Fe alloys in a reducing atmosphere, as confirmed by X-ray diffraction and X-ray photoelectron spectroscopy (XPS) characterization. XPS and H 2 -temperature-programmed reduction analyses were also conducted to examine the behavior of the exsolution process. Transmission electron microscopy and electron energy loss spectroscopy element mapping concluded that the Ni-Fe alloy NPs were successfully exsolved and anchored on the parent oxide material. The NiFe-R.P.PSFNNb exhibited superior electrochemical performance for fuel electrode reactions of reversible solid oxide cells (RSOCs). A maximum peak power density of 829, 522, and 749 mW•cm −2 was obtained for the electrochemical oxidations of H 2 , CO, and syngas, respectively, and a high current density of −1.89 A•cm −2 was produced in the electrochemical reduction of CO 2 to CO at a temperature of 850 °C. More interestingly, no significant degradation of the electrochemical performance was observed in both operating modes, indicating that the NiFe-R.P.PSFNNb proposed in this work could be a promising candidate as a bifunctional electrode for the practical implementation of RSOCs.
Patterned electrodes were developed for use in solid-state lithium-ion batteries, with the ultimate goal to promote fast-charging attributes through improving electrochemically activated surfaces within electrodes. By a conventional photolithography, patterned arrays of SnO 2 nanowires were fabricated directly on the current collector, and empty channel structures formed between the resulting arrays were customized through modifying the size and interval of the SnO 2 patterns. The composite electrolyte comprising Li 7 La 3 Zr 2 O 12 and poly(ethylene oxide) was exploited to secure intimate interfacial contact at the electrode/ electrolyte junction while preserving ionic conductivity in the bulk electrolyte. The potential and limitation of the electrode patterning approach were then explored experimentally. For example, the electrochemical behaviors of patterned electrodes were investigated as a function of variations in microchannel structures, and compared with those of conventional film-type electrodes. The findings show promise to improve electrode dynamics when electrochemical reaction kinetics could be hindered by poor interfacial characteristics on electrodes.
Mixed transition metal oxides are promising anodes to meet high‐performance energy storage materials; however, their widespread uses are restrained owing to limited theoretical capacity, restricted synthesis methods and templates, low conductivity, and extreme volume expansion. Here, Mn3‐xFexO4 nanosheets with interconnected conductive networks are synthesized via a novel self‐hybridization approach of a facile, galvanic replacement‐derived, tetraethyl orthosilicate‐assisted hydrothermal process. An exceptionally high reversible capacity of 1492.9 mAh g−1 at 0.1 A g−1 is achieved by producing Li‐rich phase through combined synergistic effects of amorphous phases with interface modification design for fully utilizing highly spin‐polarized surface capacitance. Furthermore, it is demonstrated that large surface area can effectively facilitate Li‐ion kinetics, and the formation of interconnected conductive networks improves the electrical conductivity and structural stability by alleviating volume expansion. This leads to a high rate capability of 412.3 mAh g−1 even at an extremely high current density of 10 A g−1 and stable cyclic stability with a capacity up to 921.9 mAh g−1 at 2 A g−1 after 500 cycles. This study can help to overcome theoretically limited electrochemical properties of conventional metal oxide materials, providing a new insight into the rational design with surface alteration to boost Li‐ion storage capacity.
F-doped carbon layer coating is an effective surface
modification
method to enhance the intrinsic conductivity of active materials and
facilitate the accommodation of solvated Li+ ions near
the carbon surface. Furthermore, it induces the formation of an effective
LiF-rich solid electrolyte interface with high electrochemical stability
and facile surface diffusion of Li+ ion owing to its low
energy barrier. Therefore, by employing a cost-effective coating material
poly(vinylidene fluoride) (PVDF), high electrochemical performance
in rate capability, cyclability, and energy/power density can be easily
achieved without using expensive materials. A uniform and thin coating
of an F-doped amorphous carbon layer was fabricated on the natural
graphite (NG) surface using 1 wt % of PVDF (NG-F1), followed by a
carbonization step. This process resulted in a high energy density
of 59.8 Wh kg–1 at a current density of 5.0 A g–1 (100C) in a full cell configuration for lithium-ion
capacitors (LICs). In comparison, the pristine NG demonstrated an
energy density of 47.3 Wh kg–1. Furthermore, this
LIC full cell with NG-F1 showed a lower charge-transfer resistance
and a higher capacity retention of 99.4% than pristine NG, even after
500 charge–discharge cycles at 3C.
Nowadays, thickness optimization
of an electrode is considered
an effective approach to achieve a high energy density or high areal
capacity of Li-ion batteries. In this paper, we report a simple electrospinning
technique to develop free-standing sheet bundles of lithium titanium
oxide (LTO) nanowires with a readily controlled thickness of electrodes.
The LTO nanowire sheet bundles (LNSBs) can show a very high areal
capacity as an anode due to its microscale layer-by-layer configuration
in which the nanoscale LTO nanowires are networked in each microscale
layer. Such unique structures with interspaces formed between the
multiple stacked sheet layers should promote electrolytes to efficiently
penetrate through the thick electrode layer. Nanoscale wire assemblies
can also increase the transfer rates of ions and electrons during
the lithiation/delithiation processes. Consequently, the fabricated
LNSB electrode delivers an ultrahigh areal capacity of up to ca. 14.2
mA h cm–2 for the first cycle and ca. 6.5 mA h cm–2 for the 500th cycle at 0.2C rate current density,
which is a much larger areal capacity than the commercial graphite
anode (ca. 3.5 mA h cm–2). Such a high areal discharge
capacity on a novel free-standing electrode design could provide an
idea for advanced energy storage applications.
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