Corrosion is a ubiquitous and costly problem for a variety of industries. Understanding and reducing the cost of corrosion remain primary interests for corrosion professionals and relevant asset owners. The present study summarises the findings that arose from the landmark “Study of Corrosion Status and Control Strategies in China”, a key consulting project of the Chinese Academy of Engineering in 2015, which sought to determine the national cost of corrosion and costs associated with representative industries in China. The study estimated that the cost of corrosion in China was approximately 2127.8 billion RMB (~ 310 billion USD), representing about 3.34% of the gross domestic product. The transportation and electronics industries were the two that generated the highest costs among all those surveyed. Based on the survey results, corrosion is a major and significant issue, with several key general strategies to reduce the cost of corrosion also outlined.
A simple and clean method of transferring two-dimensional (2D) materials plays a critical role in the fabrication of 2D electronics, particularly the heterostructure devices based on the artificial vertical stacking of various 2D crystals. Currently, clean transfer techniques rely on sacrificial layers or bulky crystal flakes (e.g., hexagonal boron nitride) to pick up the 2D materials. Here, we develop a capillary-force-assisted clean-stamp technique that uses a thin layer of evaporative liquid (e.g., water) as an instant glue to increase the adhesion energy between 2D crystals and polydimethylsiloxane (PDMS) for the pick-up step. After the liquid evaporates, the adhesion energy decreases, and the 2D crystal can be released. The thin liquid layer is condensed to the PDMS surface from its vapor phase, which ensures the low contamination level on the 2D materials and largely remains their chemical and electrical properties. Using this method, we prepared graphene-based transistors with low charge-neutral concentration (3 × 10 cm) and high carrier mobility (up to 48 820 cm V s at room temperature) and heterostructure optoelectronics with high operation speed. Finally, a capillary-force model is developed to explain the experiment.
The
tip-enhanced Raman spectroscopy (TERS) imaging technique is
designed to provide correlated morphological and chemical information
with a nanoscale spatial resolution by utilizing the plasmonic resonance
supported by metallic nanostructures at the tip apex of a scanning
probe. However, limited by the scattering cross sections of these
nanostructures, only a small fraction of the incident light can be
coupled to the plasmonic resonance to generate Raman signals. The
uncoupled light then directly excites background spectra with a diffraction-limited
resolution, which becomes the background noise that often blurs the
TERS image. Here, we demonstrate how this problem can be solved by
physically separating the light excitation region from the Raman signal
generation region on the scanning probe. The remote-excitation TERS
(RE-TERS) probe, which can be fabricated with a facile, robust and
reproducible method, utilizes silver nanoparticles as nanoantennas
to mediate the coupling of free-space excitation light to propagating
surface plasmon polaritons (SPPs) in a sharp-tip silver nanowire
to excite Raman signals remotely. With this RE-TERS probe, a 10 nm
spatial resolution was demonstrated on a single-walled carbon nanotube
sample, and the strain distribution in a monolayer molybdenum disulfide
(MoS2) was mapped.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.