E. Z. Kordatos scite author profile

A novel two-step approach for preparing carbon nanotube (CNT) systems, exhibiting an extraordinary combination of functional properties, is presented. It is based upon nanocomposite films consisting of metal (Me = Ni, Fe, Mo, Sn) nanoparticles embedded into diamond-like carbon (DLC). The main concept behind this approach is that DLC inhibits the growth of Me, resulting in the formation of small nanospheres instead of layers or extended grains. In the second step, DLC:Me substrates were used as catalyst templates for the growth of CNTs by the thermal chemical vapor deposition (T-CVD) process. X-ray photoelectron spectroscopy (XPS) has shown that at the T-CVD temperature of 700 °C DLC is completely graphitized and NiC is formed, making DLC:Ni a very effective catalyst for CNT growth. The catalyst layers and the CNT systems have been characterized with a wide range of analytical techniques such as Auger electron spectroscopy and X-ray photoelectron spectroscopy (AES/XPS), X-ray diffraction, reflectivity and scattering, Raman spectroscopy, scanning electron microscopy, atomic force microscopy, and optical and electrical testing. The produced CNTs are of excellent quality, without needing any further purification, durable, firmly attached to the substrate, and of varying morphology depending on the density of catalyst nanoparticles. The produced CNTs exhibit exceptional properties, such as super-hydrophobic surfaces (contact angle up to 165°) and exceptionally low optical reflection (reflectivity <10(-4)) in the entirety of the visible range. The combination of the functional properties makes these CNT systems promising candidates for solar thermal harvesting, as it is demonstrated by solar simulation experiments.

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Monitoring mechanical damage in structural materials using complimentary NDE techniques based on thermography and acoustic emission

Kordatos

Aggelis

Matikas

2012

Composites Part B: Engineering

147

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Combined use of thermography and ultrasound for the characterization of subsurface cracks in concrete

Aggelis

Kordatos

Soulioti

et al. 2010

Construction and Building Materials

109

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Rapid evaluation of the fatigue limit in composites using infrared lock-in thermography and acoustic emission

Kordatos

Dassios

Aggelis

et al. 2013

Mechanics Research Communications

102

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E. Z. Kordatos

Acoustic emission for fatigue damage characterization in metal plates

Nanocomposite Catalysts Producing Durable, Super-Black Carbon Nanotube Systems: Applications in Solar Thermal Harvesting

Monitoring mechanical damage in structural materials using complimentary NDE techniques based on thermography and acoustic emission

Combined use of thermography and ultrasound for the characterization of subsurface cracks in concrete

Rapid evaluation of the fatigue limit in composites using infrared lock-in thermography and acoustic emission

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