Photo-induced lattice contraction in layered materials. Academic Article uri icon

abstract

  • Structural and electronic changes induced by optical excitation is a promising technique for functionalization of 2D crystals. Characterizing the effect of excited electronic states on the in-plane covalent bonding network as well as the relatively weaker out-of-plane dispersion interactions is necessary to tune photo-response in these highly anisotropic crystal structures. In-plane atom dynamics was measured using pump-probe experiments and characterized using ab initio simulations, but the effect of electronic excitation on weak out-of-plane van der Waals bonds is less well-studied. We use non-adiabatic quantum molecular dynamics to investigate atomic motion in photoexcited MoS2 bilayers. We observe a strong athermal reduction in the lattice parameter along the out-of-plane direction within 100 fs after electronic excitation, resulting from redistribution of electrons to excited states that have lesser anti-bonding character between layers. This non-trivial behavior of weakly bonded interactions during photoexcitation could have potential applications for modulating properties in materials systems containing non-covalent interactions like layered materials and polymers.

published proceedings

  • J Phys Condens Matter

altmetric score

  • 1.5

author list (cited authors)

  • Kumazoe, H., Krishnamoorthy, A., Bassman, L., Kalia, R. K., Nakano, A., Shimojo, F., & Vashishta, P.

citation count

  • 5

complete list of authors

  • Kumazoe, Hiroyuki||Krishnamoorthy, Aravind||Bassman, Lindsay||Kalia, Rajiv K||Nakano, Aiichiro||Shimojo, Fuyuki||Vashishta, Priya

publication date

  • August 2018