Operando Exploring and Modulating Phase Evolution Chemistry from MAX to MXenes in Molten Salt Synthesis

Wei, Shiqiang; Zhang, Pengjun; Xu, Wenjie; Xia, Yujian; Cao, Yong; Zhu, Kehua; Cui, Qilong; Wen, Wen; Wu, Chuanqiang; Wang, Changda; Li, Song

doi:10.1021/jacs.3c01083

Cited by 21 publications

(6 citation statements)

References 34 publications

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“…For the synthesis of Ti 2 GaC, the same method was employed, with the only difference being the holding time at 1100 °C. It is worth noting that the preparation process for other Ga-MAX phases (V 2 GaC, 66 Cr 2 GaC, 67 Nb 2 GaC, 68 Mo 2 GaC, 69 and Mo 2 Ga 2 C 70 ) followed a similar procedure to that previously reported.…”

Section: Methodsmentioning

confidence: 99%

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Li,

Wei,

Chen

et al. 2024

ACS Nano

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MAX phases are highly promising materials for electromagnetic (EM) wave absorption because of their specific combination of metal and ceramic properties, making them particularly suitable for harsh environments. However, their higher matching thickness and impedance mismatching can limit their ability to attenuate EM waves. To address this issue, researchers have focused on regulating the electronic structure of MAX phases through structural engineering. In this study, we successfully synthesized a ternary MAX phase known as Sc2GaC MAX with the rare earth element Sc incorporated into the M-site sublayer, resulting in exceptional conductivity and impressive stability at high temperatures. The Sc2GaC demonstrates a strong reflection loss (RL) of −47.7 dB (1.3 mm) and an effective absorption bandwidth (E AB) of 5.28 GHz. It also achieves effective absorption of EM wave energy across a wide frequency range, encompassing the X and Ku bands. This exceptional performance is observed within a thickness range of 1.3 to 2.1 mm, making it significantly superior to other Ga-MAX phases. Furthermore, Sc2GaC exhibited excellent absorption performance even at elevated temperatures. After undergoing oxidation at 800 °C, it achieves a minimum RL of −28.3 dB. Conversely, when treated at 1400 °C under an argon atmosphere, Sc2GaC demonstrates even higher performance, with a minimum RL of −46.1 dB. This study highlights the potential of structural engineering to modify the EM wave absorption performance of the MAX phase by controlling its intrinsic electronic structure.

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Section: Methodsmentioning

confidence: 99%

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Li,

Wei,

Chen

et al. 2024

ACS Nano

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“…Another frequently used procedure to modify the surface terminal groups is APS oxidation. While prolonged treatments with APS for hours can damage MXene structure, producing amorphization and appearance of metal oxides, reaction of APS with MXenes for less than 1 h has been reported to introduce surface −O− groups without altering crystallinity and structure of the MXene [48,49] . Considering that V−O−H and V−O−V would behave differently as active sites, it was of interest to determine the influence of 30 min treatment of V 2 C with APS.…”

Section: Modification Of the Surface Termination Groups And Nature Of...mentioning

confidence: 99%

“…While prolonged treatments with APS for hours can damage MXene structure, producing amorphization and appearance of metal oxides, reaction of APS with MXenes for less than 1 h has been reported to introduce surface À OÀ groups without altering crystallinity and structure of the MXene. [48,49] Considering that VÀ OÀ H and VÀ OÀ V would behave differently as active sites, it was of interest to determine the influence of 30 min treatment of V 2 C with APS. Besides surface À OÀ functional groups being favored, it can also be envisioned that the V III/IV/V oxidation state distribution can also be modified towards higher valent V. The results of APS treatment of V 2 C are also included in Table 1 (entry 11) and, again, diminishes the catalytic activity of the original V 2 C sample for the aerobic oxidation of indane at 120 °C.…”

Section: Modification Of the Surface Termination Groups And Nature Of...mentioning

confidence: 99%

Opportunities of MXenes in Heterogeneous Catalysis: V₂C as Aerobic Oxidation Catalyst

Dhakshinamoorthy,

Ramírez‐Grau,

Garcia

et al. 2024

Chemistry A European J

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MXenes are 2D nanomaterials having alternating sheets of one atom‐thick early transition metal layer and one atom‐thick C or N layer. The external surface contains termination groups, whose nature depends on the etching agent used in the preparation procedure from the MAX phase. The present concept proposes that, due to their composition, the metal‐surface termination groups make MXenes particularly suited as heterogeneous catalysts for some reactions. T After presenting the concept, we have selected V2C Mxene as example to illustrate its catalytic activity showing how the catalytic performance varies when the surface groups are modified. As test reaction we selected the aerobic oxidation of indane to the corresponding indanol/indanone mixture using molecular oxygen as terminal oxidizing reagent. Two previously reported procedures to modify the surface groups, namely surface dehydroxylation by thermal treatment under diluted hydrogen flow and surface oxidation with ammonium monoperoxy sulfate to convert some surface groups into oxo groups were used, observing in both cases a decrease in the catalytic activity of V2C. Based on this, VIII/IV‐OH are proposed as catalytic centers in this aerobic oxidation. Overall, the present concept shows the merits of MXenes in heterogeneous catalysis, based on their chemical composition and the surface functionality.

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“…This approach avoids the production of harmful compounds, eliminates the need for a protective atmosphere, and has recently gained widespread attention. [ 31,32 ]…”

Section: Introductionmentioning

confidence: 99%

“…This approach avoids the production of harmful compounds, eliminates the need for a protective atmosphere, and has recently gained widespread attention. [31,32] Here, we propose the utilization of 2D layered Ti 2 CT x MXene as the cathode host material for Zn-Br 2 battery. The Ti 2 CT x MXene, synthesized via the molten salt method, possesses a distinctive open layered structure, and is enriched with polar surface functional groups (Figure S2, Supporting Information).…”

Section: Introductionmentioning

confidence: 99%

Ti₂CT_x MXene Cathode Host for Enhanced Zinc‐Bromine Battery Performance

Guo,

Ma,

Liu

et al. 2024

Advanced Energy Materials

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Aqueous zinc‐bromine batteries represent a promising large‐scale energy storage system, yet generally suffer from the dissolution of polybromides in the cathode. Currently, various nonpolar carbon materials are employed as hosts for the bromine cathode. Still, they typically exhibit weak adsorption capabilities toward polybromides. Here, a highly conductive Ti2CTx MXene synthesized through an eco‐friendly molten salt method is reported, serving as an ideal bromine cathode host material for the first time. Ti2CTx MXene shows strong chemisorptive capability to soluble polybromide species and can effectively immobilize them for enhanced coulombic efficiency and prolong cycling life of zinc‐bromine batteries. Additionally, Ti2CTx MXene enhances the reaction kinetics of the bromine cathode. Benefiting from the synergistic polybromide adsorption and catalysis effects of Ti2CTx, the dual‐plating zinc‐bromine batteries exhibit good cycle stability, with a capacity retention of 87% after 3000 cycles, outperforming traditional carbon host which fail after 2300 cycles. Meanwhile, Ti2CTx achieves a much lower polarization voltage of only 84 mV, significantly less than 240 mV observed with carbon hosts. This research highlights the potential of developing host materials with polybromide chemisorptive properties to advance the performance of zinc‐bromine batteries.

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Operando Exploring and Modulating Phase Evolution Chemistry from MAX to MXenes in Molten Salt Synthesis

Cited by 21 publications

References 34 publications

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Opportunities of MXenes in Heterogeneous Catalysis: V₂C as Aerobic Oxidation Catalyst

Ti₂CT_x MXene Cathode Host for Enhanced Zinc‐Bromine Battery Performance

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Operando Exploring and Modulating Phase Evolution Chemistry from MAX to MXenes in Molten Salt Synthesis

Cited by 21 publications

References 34 publications

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Regulating the Electronic Structure of MAX Phases Based on Rare Earth Element Sc to Enhance Electromagnetic Wave Absorption

Opportunities of MXenes in Heterogeneous Catalysis: V2C as Aerobic Oxidation Catalyst

Ti2CTx MXene Cathode Host for Enhanced Zinc‐Bromine Battery Performance

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Product

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Opportunities of MXenes in Heterogeneous Catalysis: V₂C as Aerobic Oxidation Catalyst

Ti₂CT_x MXene Cathode Host for Enhanced Zinc‐Bromine Battery Performance