A team at the International Center for Materials Nanoarchitectonics (WPI-MANA) 
has demonstrated for the first time the fabrication of folded bilayer-bilayer 
graphene (fBBLG)/hexagonal boron nitride (hBN) superlattices. This achievement 
could pave the way for expanded applications of superlattices, such as in a 
variety of quantum devices.

(Image: 
https://kyodonewsprwire.jp/prwfile/release/M105739/202008183233/_prw_PI1fl_813CpOk8.jpg)


Graphene superlattices represent a novel class of quantum metamaterials that 
have promising prospects. They have been generating a lot of attention 
recently, ever since the discovery of superconductivity in twisted bilayer 
graphene (BLG). This was followed by studies related to twisted bilayer-bilayer 
graphene. Bernal-stacked BLG has a parabolic energy dispersion with a four-fold 
spin and valley degeneracy.

A superlattice is a periodic structure of layers of two or more materials. 
Typically, the width of layers is orders of magnitude larger than the lattice 
constant, and is limited by the growth of the structure. The WPI-MANA team's 
superlattices are made up of vertically stacked ultrathin/atomic-layer quasi 2D 
materials.

The WPI-MANA team's results point to the emergence of a unique electronic band 
structure in the fBBLG, which could provide a way for investigating correlated 
electron phenomena by performing energy-band engineering with superlattice 
structures.

The results of this study indicate the emergence of a unique electronic band 
structure in fBBLG, which could be modified by the moire superlattice 
potential. Although a systematic way to fold graphene is still lacking, it 
should be a fruitful topic of future research, leading to 2D paper-folding 
engineering like "origami." The team's results suggest a possible way to 
engineer 2D electronic systems by mechanical folding, similar to "tear and 
stack" for twisted heterostructures.

This work could lead the way to expanded applications of superlattices, 
including quantum devices such as Bloch oscillators, quantum cascade lasers and 
terahertz source generators.

This research was carried out by Takuya Iwasaki (ICYS-WPI-MANA Research Fellow, 
WPI-MANA, NIMS) and his collaborators.

Takuya Iwasaki et al., APPLIED PHYSICS EXPRESS, March 5, 2020: 
https://iopscience.iop.org/article/10.35848/1882-0786/ab790d


Source: 
International Center for Materials Nanoarchitectonics (WPI-MANA), National 
Institute for Materials Science (NIMS)