Abstract
With the growing interest in low dimensional materials, MXenes have also attracted considerable attention recently. In this work, the thermal and electrical properties of oxygen-functionalized M2CO2 (M = Ti, Zr, Hf) MXenes are investigated using first-principles calculations. Hf2CO2 is determined to exhibit a thermal conductivity better than MoS2 and phosphorene. The room-temperature thermal conductivity along the armchair direction is determined to be 86.25~131.2 Wm−1 K−1 with a flake length of 5~100 μm. The room temperature thermal expansion coefficient of Hf2CO2 is 6.094 × 10−6 K−1, which is lower than that of most metals. Moreover, Hf2CO2 is determined to be a semiconductor with a band gap of 1.657 eV and to have high and anisotropic carrier mobility. At room temperature, the Hf2CO2 hole mobility in the armchair direction (in the zigzag direction) is determined to be as high as 13.5 × 103 cm2V−1s−1 (17.6 × 103 cm2V−1s−1). Thus, broader utilization of Hf2CO2, such as the material for nanoelectronics, is likely. The corresponding thermal and electrical properties of Ti2CO2 and Zr2CO2 are also provided. Notably, Ti2CO2 presents relatively lower thermal conductivity but much higher carrier mobility than Hf2CO2. According to the present results, the design and application of MXene based devices are expected to be promising.
Highlights
Based on the results presented Hf2CO2 is unexpectedly determined to possess a moderate band gap, a thermal conductivity better than MoS2 and phosphorene, and a high carrier mobility comparable to phosphorene, which indicates that this material may have extensive potential applications in nanoelectronics
Because of the limited data currently available, further research should be conducted on the synthesis of M2CO2 (M =Zr, Hf) monolayers, and their intrinsic thermal and electrical properties should be experimentally measured
Considering the successful fabrication of Ti2CT2 (T =-O, -F, -OH) and the existence of MAX phases M2AC (M =Zr, Hf; A =In, Tl, Sn, Pb, S)[48], there is a great anticipation on the synthesis of M2CO2 (M =Zr, Hf) using the reported preparation methods such as etching of their parental MAX phase and heat treatment on hydroxyl functionalized MXenes
Summary
The electronic band gap, thermal properties and carrier mobility of three oxygen-functionalized MXenes, Ti2CO2, Zr2CO2 and Hf2CO2, are predicted via theoretical calculations. Based on the results presented Hf2CO2 is unexpectedly determined to possess a moderate band gap, a thermal conductivity better than MoS2 and phosphorene, and a high carrier mobility comparable to phosphorene, which indicates that this material may have extensive potential applications in nanoelectronics. For this reason, the major part of this work focuses on the thermal conductivity and electrical properties of Hf2CO2. The results for Ti2CO2 and Zr2CO2 are mainly supplied in the Supplementary Information
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