posted on 2016-02-18, 17:04authored byChunlei Pang, Hao Cui, Guowei Yang, Chengxin Wang
If the flexible transparent and free-standing
paper-like materials
that would be expected to meet emerging technological demands, such
as components of transparent electrical batteries, flexible solar
cells, bendable electronics, paper displays, wearable computers, and
so on, could be achieved in silicon, it is no doubt that the traditional
semiconductor materials would be rejuvenated. Bulk silicon cannot
provide a solution because it usually exhibits brittleness at below
their melting point temperature due to high Peierls stress. Fortunately,
when the silicon’s size goes down to nanoscale, it possesses
the ultralarge straining ability, which results in the possibility
to design flexible transparent and self-standing silicon nanowires
paper (FTS-SiNWsP). However, realization of the FTS-SiNWsP is still
a challenging task due largely to the subtlety in the preparation
of a unique interlocking alignment with free-catalyst controllable
growth. Herein, we present a simple synthetic strategy by gas flow
directed assembly of a unique interlocking alignment of the Si nanowires
(SiNWs) to produce, for the first time, the FTS-SiNWsP, which consisted
of interconnected SiNWs with the diameter of ∼10 nm via simply
free-catalyst thermal evaporation in a vertical high-frequency induction
furnace. This approach opens up the possibility for creating various
flexible transparent functional devices based on the FTS-SiNWsP.