Abstract
As a derivative of graphene, graphene oxide (GO) was initially developed
by chemists to emulate some of the key properties of graphene, but it
was soon recognized as a unique material in its own right, addressing an
application space that is not accessible to chemical vapor deposition
based materials. Over the past decade, GO has emerged as a new frontier
material with tremendous advances in its material fabrication and
quality control over its properties. These in turn have led to rapid
progress in GO based photonics, electronics, and optoelectronics
concepts and devices, evoking new science and paving the way for many
technological breakthroughs with exceptional performance. Here, we
review the unique fundamental characteristics of GO, its thin film
fabrication methods, patterning techniques, and mechanisms for tuning
its material properties. This latter capability in particular has
enabled novel advanced functional photonic, electronic, and
optoelectronic devices. Understanding these insights is essential for
designing and tailoring GO properties for state-of-the-art applications
including solar energy harvesting, energy storage, medical diagnosis,
image displays, and optical communications. We conclude by discussing
the open challenges and exciting opportunities of this field, together
with future prospects for major technological advancements and
breakthroughs.