High-entropy
oxides based on transition metals, such as Mg0.2Co0.2Ni0.2Cu0.2Zn0.2O (TM-HEO),
have recently drawn special attention as potential anodes in lithium-ion
batteries due to high specific capacity and cycling reversibility.
However, the lithiation/delithiation mechanism of such systems is
still controversial and not clearly addressed. Here, we report on
an operando XAS investigation into TM-HEO-based anodes for lithium-ion
cells during the first lithiation/delithiation cycle. This material
showed a high specific capacity exceeding 600 mAh g–1 at 0.1 C and Coulombic efficiency very close to unity. The combination
of functional and advanced spectroscopic studies revealed complex
charging mechanisms, developing through the reduction of transition-metal
(TM) cations, which triggers the conversion reaction below 1.0 V.
The conversion is irreversible and incomplete, leading to the final
collapse of the HEO rock-salt structure. Other redox processes are
therefore discussed and called to account for the observed cycling
behavior of the TM-HEO-based anode. Despite the irreversible phenomena,
the HEO cubic structure remains intact for ∼60% of lithiation
capacity, so proving the beneficial role of the configuration entropy
in enhancing the stability of the HEO rock-salt structure during the
redox phenomena.
The
mechanisms of CO oxidation on the Mg
0.2
Co
0.2
Ni
0.2
Cu
0.2
Zn
0.2
O high-entropy oxide
were studied by means of operando soft X-ray absorption spectroscopy.
We found that Cu is the active metal and that Cu(II) can be rapidly
reduced to Cu(I) by CO when the temperature is higher than 130 °C.
Co and Ni do not have any role in this respect. The Cu(II) oxidation
state can be easily but slowly recovered by treatment of the sample
with O
2
at ca. 250 °C. However, it should be noted
that CuO is readily and irreversibly reduced to Cu(I) when it is treated
with CO at
T
> 100 °C. Thus, the main conclusion
of this work is that the high configurational entropy of Mg
0.2
Co
0.2
Ni
0.2
Cu
0.2
Zn
0.2
O
stabilizes the rock-salt structure and permits the oxidation/reduction
of Cu to be reversible, thus permitting the catalytic cycle to take
place.
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