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Strain-engineered growth of two-dimensional materials

Author

Listed:
  • Geun Ho Ahn

    (University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • Matin Amani

    (University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • Haider Rasool

    (Lawrence Berkeley National Laboratory
    University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • Der-Hsien Lien

    (University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • James P. Mastandrea

    (Lawrence Berkeley National Laboratory
    University of California at Berkeley)

  • Joel W. Ager III

    (Lawrence Berkeley National Laboratory
    University of California at Berkeley)

  • Madan Dubey

    (US Army Research Laboratory)

  • Daryl C. Chrzan

    (Lawrence Berkeley National Laboratory
    University of California at Berkeley)

  • Andrew M. Minor

    (Lawrence Berkeley National Laboratory
    University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • Ali Javey

    (University of California at Berkeley
    Lawrence Berkeley National Laboratory)

Abstract

The application of strain to semiconductors allows for controlled modification of their band structure. This principle is employed for the manufacturing of devices ranging from high-performance transistors to solid-state lasers. Traditionally, strain is typically achieved via growth on lattice-mismatched substrates. For two-dimensional (2D) semiconductors, this is not feasible as they typically do not interact epitaxially with the substrate. Here, we demonstrate controlled strain engineering of 2D semiconductors during synthesis by utilizing the thermal coefficient of expansion mismatch between the substrate and semiconductor. Using WSe2 as a model system, we demonstrate stable built-in strains ranging from 1% tensile to 0.2% compressive on substrates with different thermal coefficient of expansion. Consequently, we observe a dramatic modulation of the band structure, manifested by a strain-driven indirect-to-direct bandgap transition and brightening of the dark exciton in bilayer and monolayer WSe2, respectively. The growth method developed here should enable flexibility in design of more sophisticated devices based on 2D materials.

Suggested Citation

  • Geun Ho Ahn & Matin Amani & Haider Rasool & Der-Hsien Lien & James P. Mastandrea & Joel W. Ager III & Madan Dubey & Daryl C. Chrzan & Andrew M. Minor & Ali Javey, 2017. "Strain-engineered growth of two-dimensional materials," Nature Communications, Nature, vol. 8(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_s41467-017-00516-5
    DOI: 10.1038/s41467-017-00516-5
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