Zhaojin Li scite author profile

We present a comparative study on the static and dynamical properties of bare Ti3C2 and T-terminated Ti3C2T2 (T = O, F, OH) monosheets using density functional theory calculations. First, the crystal structures are optimized to be of trigonal configurations (P3[combining macron]m1), which are thermodynamically and dynamically stable. It is demonstrated that the terminations modulate the crystal structures through valence electron density redistribution of the atoms, particularly surface Ti (Ti2) in the monosheets. Second, lattice dynamical properties including phonon dispersion and partial density of states (PDOS) are investigated. Phonon PDOS analysis shows a clear collaborative feature in the vibrations, reflecting the covalent nature of corresponding bonds in the monosheets. In the bare Ti3C2 monosheet, there is a phonon band gap between 400 and 500 cm(-1), while it disappears in Ti3C2O2 and Ti3C2(OH)2 as the vibrations associated with the terminal atoms (O and OH) bridge the gap. Third, both Raman (Eg and A1g) and infrared-active (Eu and A2u) vibrational modes are predicted and conclusively assigned. A comparative study indicates that the terminal atoms remarkably influence the vibrational frequencies. Generally, the terminal atoms weaken the vibrations in which surface Ti atoms are involved while strengthening the out-of-plane vibration of C atoms. Temperature-dependent micro Raman measurements agree with the theoretical prediction if the complexity in the experimentally obtained lamellae for the Raman study is taken into account.

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High-Capacitance Mechanism for Ti₃C₂T_x MXene by in Situ Electrochemical Raman Spectroscopy Investigation

et al. 2016

ACS Nano

489

346

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MXenes represent an emerging family of conductive two-dimensional materials. Their representative, TiCT, has been recognized as an outstanding member in the field of electrochemical energy storage. However, an in-depth understanding of fundamental processes responsible for the superior capacitance of TiCT MXene in acidic electrolytes is lacking. Here, to understand the mechanism of capacitance in TiCT MXene, we studied electrochemically the charge/discharge processes of TiCT electrodes in sulfate ion-containing aqueous electrolytes with three different cations, coupled with in situ Raman spectroscopy. It is demonstrated that hydronium in the HSO electrolyte bonds with the terminal O in the negative electrode upon discharging while debonding occurs upon charging. Correspondingly, the reversible bonding/debonding changes the valence state of Ti element in the MXene, giving rise to the pseudocapacitance in the acidic electrolyte. In stark contrast, only electric double layer capacitance is recognized in the other electrolytes of (NH)SO or MgSO. The charge storage ways also differ: ion exchange dominates in HSO, while counterion adsorption in the rest. Hydronium that is characterized by smaller hydration radius and less charge is the most mobile among the three cations, facilitating it more kinetically accommodated on the deep adsorption sites between the MXene layers. The two key factors, i.e., surface functional group-involved bonding/debonding-induced pseudocapacitance, and ion exchange-featured charge storage, simultaneously contribute to the superior capacitance of TiCT MXene in acidic electrolytes.

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Surface Functional Groups and Interlayer Water Determine the Electrochemical Capacitance of Ti₃C₂T_x MXene

et al. 2018

ACS Nano

385

182

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MXenes, an emerging class of conductive two-dimensional materials, have been regarded as promising candidates in the field of electrochemical energy storage. The electrochemical performance of their representative TiC T , where T represents the surface termination group of F, O, or OH, strongly relies on termination-mediated surface functionalization, but an in-depth understanding of the relationship between them remains unresolved. Here, we studied comprehensively the structural feature and electrochemical performance of two kinds of TiC T MXenes obtained by etching the TiAlC precursor in aqueous HF solution at low concentration (6 mol/L) and high concentration of (15 mol/L). A significantly higher capacitance was recognized in a low-concentration HF-etched MXene (TiC T -6M) electrode. In situ Raman spectroscopy and X-ray photoelectron spectroscopy demonstrate that TiC T -6M has more components of the -O functional group. In combination with X-ray diffraction analysis, low-fieldH nuclear magnetic resonance spectroscopy in terms of relaxation time unambiguously underlines that TiC T -6M is capable of accommodating more high-mobility HO molecules between the TiC T interlayers, enabling more hydrogen ions to be more readily accessible to the active sites of TiC T -6M. The two main key factors ( i.e., high content of -O functional groups that are involved bonding/debonding-induced pseudocapacitance and more high-mobility water intercalated between the MXene interlayers) simultaneously account for the superior capacitance of the TiC T -6M electrode. This study provides a guideline for the rational design and construction of high-capacitance MXene and MXene-based hybrid electrodes in aqueous electrolytes.

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Chemical Origin of Termination-Functionalized MXenes: Ti₃C₂T₂ as a Case Study

et al. 2017

J. Phys. Chem. C

237

157

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MXenes represent a burgeoning family of two-dimensional (2D) functional materials with a variety of applications that highly rely on terminationmediated surface functionalization, but the understanding of termination is limited. Here, we take Ti 3 C 2 T 2 (T = O, F, OH, and H) as an example of MXenes, to demonstrate how termination stabilizes the Ti 3 C 2 monolayer matrix by saturating the nonbonding valence electrons of the surface Ti atom by the low-energy orbitals of the termination. This is achieved by orbitally resolved density of states analysis by simply yet efficiently manipulating the internal coordination of the octahedral crystal field to match exactly the Cartesian coordination. Highly degenerate 3d orbitals of surface Ti split in such a way that it exhibits pseudogaps whose widths predict a stability order Ti 3 C 2 O 2 > Ti 3 C 2 F 2 > Ti 3 C 2 (OH) 2 > Ti 3 C 2 H 2 > Ti 3 C 2 , consistent with Bader charge analysis, thermodynamic calculations, and experimental results. This new criterion could have implications in the general context of ubiquitous termination phenomena of MXenes and other relevant termination-functionalized 2D materials.

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Zhaojin Li

Vibrational properties of Ti₃C₂and Ti₃C₂T₂(T = O, F, OH) monosheets by first-principles calculations: a comparative study

High-Capacitance Mechanism for Ti₃C₂T_x MXene by in Situ Electrochemical Raman Spectroscopy Investigation

Surface Functional Groups and Interlayer Water Determine the Electrochemical Capacitance of Ti₃C₂T_x MXene

Chemical Origin of Termination-Functionalized MXenes: Ti₃C₂T₂ as a Case Study

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Zhaojin Li

Vibrational properties of Ti3C2and Ti3C2T2(T = O, F, OH) monosheets by first-principles calculations: a comparative study

High-Capacitance Mechanism for Ti3C2Tx MXene by in Situ Electrochemical Raman Spectroscopy Investigation

Surface Functional Groups and Interlayer Water Determine the Electrochemical Capacitance of Ti3C2Tx MXene

Chemical Origin of Termination-Functionalized MXenes: Ti3C2T2 as a Case Study

Contact Info

Product

Resources

About

Vibrational properties of Ti₃C₂and Ti₃C₂T₂(T = O, F, OH) monosheets by first-principles calculations: a comparative study

High-Capacitance Mechanism for Ti₃C₂T_x MXene by in Situ Electrochemical Raman Spectroscopy Investigation

Surface Functional Groups and Interlayer Water Determine the Electrochemical Capacitance of Ti₃C₂T_x MXene

Chemical Origin of Termination-Functionalized MXenes: Ti₃C₂T₂ as a Case Study