Quantum confinement in black phosphorus through strain-engineered rippling

Jorge Quereda, Vincenzo Parente, Pablo San-José, Nicolás Agraït, Gabino Rubio-Bollinger, Francisco Guinea, Rafael Roldán, Andres Castellanos-Gomez

Published 2015-09-03Version 1

The recent isolation of black phosphorus has unleashed the interest of the community working on 2D materials because of its interesting electronic and optical properties: narrow intrinsic gap, ambipolar field effect and high carrier mobility. Black phosphorus is composed of phosphorus atoms held together by strong bonds forming layers that interact through weak van der Waals forces holding the layers stacked on top of each other. This structure, without surface dangling bonds, allows black phosphorus susceptible to withstand very large localized deformations without breaking (similarly to graphene and MoS2). Its outstanding mechanical resilience makes black phosphorus a prospective candidate for strain engineering, modification of a material's optical/electrical properties by means of mechanical stress, in contrast to conventional 3D semiconductors that tend to break for moderate deformations. Very recent theoretical works explore the effect of strain on the band structure and optical properties of black phosphorus, predicting an even stronger response than in other 2D semiconductors such as transition metal dichalcogenides. Most of the reported works, however, are limited to theoretical studies dealing exclusively with uniform strain, while the role of non-uniform strain remains poorly-understood. Here we explore the effect of periodic strain profiles to modulate the electronic and optical properties of black phosphorus by combining hyperspectral imaging spectroscopy experiments and tight-binding calculations.