The synthesis of
large, defect-free two-dimensional materials (2DMs)
such as graphene is a major challenge toward industrial applications.
Chemical vapor deposition (CVD) on liquid metal catalysts (LMCats)
is a recently developed process for the fast synthesis of high-quality
single crystals of 2DMs. However, up to now, the lack of
in
situ
techniques enabling direct feedback on the growth has
limited our understanding of the process dynamics and primarily led
to empirical growth recipes. Thus, an
in situ
multiscale
monitoring of the 2DMs structure, coupled with a real-time control
of the growth parameters, is necessary for efficient synthesis. Here
we report real-time monitoring of graphene growth on liquid copper
(at 1370 K under atmospheric pressure CVD conditions)
via
four complementary
in situ
methods: synchrotron
X-ray diffraction and reflectivity, Raman spectroscopy, and radiation-mode
optical microscopy. This has allowed us to control graphene growth
parameters such as shape, dispersion, and the hexagonal supra-organization
with very high accuracy. Furthermore, the switch from continuous polycrystalline
film to the growth of millimeter-sized defect-free single crystals
could also be accomplished. The presented results have far-reaching
consequences for studying and tailoring 2D material formation processes
on LMCats under CVD growth conditions. Finally, the experimental observations
are supported by multiscale modeling that has thrown light into the
underlying mechanisms of graphene growth.
A new scanning tunneling microscope reactor used for high-pressure and high-temperature catalysis studies Review of Scientific Instruments 79, 084101 (2008) To enable atomic-scale observations of model catalysts under conditions approaching those used by the chemical industry, we have developed a second generation, high-pressure, high-temperature scanning tunneling microscope (STM): the ReactorSTM. It consists of a compact STM scanner, of which the tip extends into a 0.5 ml reactor flow-cell, that is housed in a ultra-high vacuum (UHV) system. The STM can be operated from UHV to 6 bars and from room temperature up to 600 K. A gas mixing and analysis system optimized for fast response times allows us to directly correlate the surface structure observed by STM with reactivity measurements from a mass spectrometer. The in situ STM experiments can be combined with ex situ UHV sample preparation and analysis techniques, including ion bombardment, thin film deposition, low-energy electron diffraction and x-ray photoelectron spectroscopy.
Scanning probe microscopy is at the verge of revolutionizing microscopy once again. Video-rate scanning tunneling microscope (STM) and video-rate atomic force microscope (AFM) technology will enable the direct observation of many dynamic processes that are impossible to observe today, such as atom or molecule diffusion, real time film growth, or catalytic reactions. In this paper we discuss the critical aspects that have to be taken into account when working on increasing the imaging speed of scanning probe microscopes. We highlight the state-of-the-art developments in the control of the piezoelectric scanning elements and describe the latest innovations regarding the design and construction of the whole mechanical loop including new scanner geometries. We identify critical aspects for which no obvious solution exists and aspects where advanced control engineering can help, like piezo non-linearities, the acceleration limit and the challenging technical requirements for the preamplifiers that are needed for measuring a tunneling current. Finally, we provide an overview of a number of new directions that are being pursued to solve the problems currently encountered in scanning probe technology.
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Pulse tube refrigerators are becoming more common, because they are cost efficient and demand less handling than conventional (wet) refrigerators. However, a downside of a pulse tube system is the vibration level at the cold-head, which is in most designs several micrometers. We implemented vibration isolation techniques which significantly reduced vibration levels at the experiment. These optimizations were necessary for the vibration sensitive magnetic resonance force microscopy experiments at milli-kelvin temperatures for which the cryostat is intended. With these modifications we show atomic resolution scanning tunneling microscopy on graphite. This is promising for scanning probe microscopy applications at very low temperatures.
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