3. Conclusions and outlookThe BBF a

3. Conclusions and outlook
The BBF approach for assembling nanomaterials has been
reviewed, and key features such as generality, alignment and
density control, large area, and conformal transfer to various
substrates have been outlined. Nanomaterial-BBFs with distinct
nanomaterial properties, including metallic conduction, semiconductor
properties, and optical emission, can serve as a powerful
platform for manufacturing electrically and/or optically
active films enabling many applications. Nanomaterial-BBFs
prepared using other types of polymers that enable direct processing
by photolithography and/or electron-beam lithography,
such as PMMA, can facilitate device fabrication steps compared
to the original epoxy polymer system. While there are scientific
and engineering issues that should be tackled in the future,
including (i) optimization of density, (ii) extension to other polymer
systems, and (iii) a fundamental understanding of forces and
dynamics during bubble expansion, we remain very optimistic
about the potential of this approach for opening up applications
and new scientific directions. For example, nanostructure-BBFs
could be fabricated as reinforced nanocomposite films/coatings
which have visible/infrared absorption and fluorescence,47 NW/
NT-BBFs could yield flexible nanoelectronic systems integrating
high-performance FETs and chemical/biological sensors for
environmental and medical applications,39,48 and NW/NT-BBFs
might lead to ultra-large area high-density, flat panel displays.49
Moreover, by layering multiple nanostructure-BBFs or folding/
scrolling nanomaterials-BBFs, more complex three-dimensional
structures such as crossbars and hierarchically arranged nanoscale
building blocks21,50 might be fabricated to enable completely new
types of electronic/photonic systems in the future.