Evaluation of 2D Tantalum Carbide MXene for Room to Mid‐ temperature Thermoelectric Applications

IF 2.6 4区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY

ChemNanoMat Pub Date : 2024-08-29 DOI:10.1002/cnma.202400391

Ravuri Syamsai, Vaiyapuri Vijay, Senthil Kumar Easwaran, Navaneethan M

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Abstract

Tantalum carbide MXene (Ta4C3Tx) were synthesized via HF etching of the Al intermediate layer from the parental tantalum aluminium carbide MAX phase (Ta4AlC3). The structural and vibrational studies confirm the formation of MXene from the MAX phase without disturbing the hexagonal crystal structure. The synthesized samples were analysed using XRD to understand the phase structure. In and out of plane vibrational properties were examined by Raman spectrometer. XPS confirms the successful HF etching of Al in MXene phase and all other elemental configurations. HR‐SEM and HR‐TEM revile the exfoliated layered structure of the MXene and hexagon diffraction pattern of the tantalum carbide MXene sample with increased d‐spacing. The TGA analysis demonstrated the thermal stability of the as‐synthesized post measured compounds. The synthesized tantalum carbide MXene shows stable thermoelectric properties over six thermal cycles. The temperature dependent transport properties were measured from 303 K to 803 K. Ta4C3Tx MXene shows a maximum Seebeck coefficient of 13.8 µV/K and a power factor of 1.88 µW/mK2 with the low lattice thermal conductivity of 5.42 W/mK at 803 K. In this present investigation, Tantalum carbide MXene demonstrated a decent thermoelectric property with high thermal cycling stability.

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评估用于室温至中温热电应用的二维碳化钽 MXene

通过高频蚀刻母体钽铝碳化物 MAX 相（Ta4AlC3）中的铝中间层，合成了碳化钽 MXene（Ta4C3Tx）。结构和振动研究证实，MXene 是在不破坏六方晶体结构的情况下从 MAX 相中形成的。利用 XRD 对合成样品进行了分析，以了解相结构。拉曼光谱仪检测了平面内外的振动特性。XPS 证实高频成功蚀刻了 MXene 相中的铝和所有其他元素构型。HR-SEM 和 HR-TEM 揭示了 MXene 的剥离层状结构，以及碳化钽 MXene 样品的六边形衍射图样，其 d 间距有所增加。TGA 分析表明了合成后测量化合物的热稳定性。合成的碳化钽 MXene 在六个热循环中显示出稳定的热电特性。Ta4C3Tx MXene 的最大塞贝克系数为 13.8 µV/K，功率因数为 1.88 µW/mK2，在 803 K 时的低晶格热导率为 5.42 W/mK。

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来源期刊

ChemNanoMat Energy-Energy Engineering and Power Technology

CiteScore

6.10

自引率

2.60%

发文量

236

期刊介绍： ChemNanoMat is a new journal published in close cooperation with the teams of Angewandte Chemie and Advanced Materials, and is the new sister journal to Chemistry—An Asian Journal.