Despite the continuous progress in the research and development of Ti 3 C 2 T x (MXene) electrodes for high-power batteries and supercapacitor applications, the role of the anions in the electrochemical energy storage and their ability to intercalate between the MXene sheets upon application of positive voltage have not been clarified. A decade after the discovery of MXenes, the information about the possibility of anion insertion into the restacked MXene electrode is still being questioned. Since the positive potential stability range in diluted aqueous electrolytes is severely limited by anodic oxidation of the Ti, the possibility of anion insertion was evaluated in concentrated aqueous electrolyte solutions and aprotic electrolytes as well. To address this issue, we have conducted in situ gravimetric electrochemical quartz crystal microbalance with dissipation monitoring (EQCM-D) measurements in highly concentrated LiCl and LiBr electrolytes, which enable a significant extension of the operation range of the MXene electrodes toward positive potentials. Also, halogens are among the smallest anions and should be easier to intercalate between MXene layers, in comparison to multiatomic anions. On the basis of mass change variations in the positive voltage range and complementary density functional theory calculations, it was demonstrated that insertion of anionic species into MXene, within the range of potentials of interest for capacitive energy storage, is not likely to occur. This can be explained by the strong negative charge on Ti 3 C 2 T x sheets terminated by functional groups.
Identifying
and understanding charge storage mechanisms is important
for advancing energy storage. Well-separated peaks in cyclic voltammograms
(CVs) are considered key indicators of diffusion-controlled electrochemical
processes with distinct Faradaic charge transfer. Herein, we report
on an electrochemical system with separated CV peaks, accompanied
by surface-controlled partial charge transfer, in 2D Ti3C2T
x
MXene in water-in-salt
electrolytes. The process involves the insertion/desertion of desolvation-free
cations, leading to an abrupt change of the interlayer spacing between
MXene sheets. This unusual behavior increases charge storage at positive
potentials, thereby increasing the amount of energy stored. This also
demonstrates opportunities for the development of high-rate aqueous
energy storage devices and electrochemical actuators using safe and
inexpensive aqueous electrolytes.
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