Nature Communications (Apr 2023)

Van der Waals nanomesh electronics on arbitrary surfaces

  • You Meng,
  • Xiaocui Li,
  • Xiaolin Kang,
  • Wanpeng Li,
  • Wei Wang,
  • Zhengxun Lai,
  • Weijun Wang,
  • Quan Quan,
  • Xiuming Bu,
  • SenPo Yip,
  • Pengshan Xie,
  • Dong Chen,
  • Dengji Li,
  • Fei Wang,
  • Chi-Fung Yeung,
  • Changyong Lan,
  • Chuntai Liu,
  • Lifan Shen,
  • Yang Lu,
  • Furong Chen,
  • Chun-Yuen Wong,
  • Johnny C. Ho

DOI
https://doi.org/10.1038/s41467-023-38090-8
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 14

Abstract

Read online

Abstract Chemical bonds, including covalent and ionic bonds, endow semiconductors with stable electronic configurations but also impose constraints on their synthesis and lattice-mismatched heteroepitaxy. Here, the unique multi-scale van der Waals (vdWs) interactions are explored in one-dimensional tellurium (Te) systems to overcome these restrictions, enabled by the vdWs bonds between Te atomic chains and the spontaneous misfit relaxation at quasi-vdWs interfaces. Wafer-scale Te vdWs nanomeshes composed of self-welding Te nanowires are laterally vapor grown on arbitrary surfaces at a low temperature of 100 °C, bringing greater integration freedoms for enhanced device functionality and broad applicability. The prepared Te vdWs nanomeshes can be patterned at the microscale and exhibit high field-effect hole mobility of 145 cm2/Vs, ultrafast photoresponse below 3 μs in paper-based infrared photodetectors, as well as controllable electronic structure in mixed-dimensional heterojunctions. All these device metrics of Te vdWs nanomesh electronics are promising to meet emerging technological demands.