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Nanoantennas are an enabling technology for visible to terahertz components and may be used with a variety of detector materials. We have integrated subwavelength patterned metal nanoantennas with various detector materials for infrared detection: midwave infrared indium gallium arsenide antimonide detectors, longwave infrared graphene detectors, and shortwave infrared germanium detectors. Nanoantennas offer a means to make infrared detectors much thinner, thus lowering the dark current and improving performance. The nanoantenna converts incoming plane waves to more tightly bound and concentrated surface waves. The active material only needs to extend as far as these bound fields. In the case of graphene detectors, which are only one or two atomic layers thick, such field concentration is a necessity for usable device performance, as single pass absorption is insufficient. The nanoantenna is thus the enabling component of these thin devices. However nanoantenna integration and fabrication vary considerably across these platforms as do the considerations taken into account during design. Here we discuss the motivation for these devices and show examples for the three material systems. Characterization results are included for the midwave infrared detector. © 2014 SPIE.

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TYPE Conference YEAR 2014

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Planarized un-entangled carbon nanotube arrays

Siegal, Michael P.; Limmer, Steven J.; Beechem, Thomas E.

Abstract not provided.

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TYPE Conference YEAR 2013

OSTI

Evidence of ion mixing increasing the thermal boundary conductance across aluminum/silicon interfaces

Advanced Functional Materials

Hattar, Khalid M.; Beechem, Thomas E.; Ihlefeld, Jon I.; Biedermann, Laura B.; Piekos, Edward S.; Medlin, Douglas L.

Abstract not provided.

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TYPE Journal Article YEAR 2013

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Accelerating the development of transparent graphene electrodes through basic science driven chemical functionalization

Chan, Calvin C.K.; Beechem, Thomas E.; Ohta, Taisuke O.; Brumbach, Michael T.; Wheeler, David R.

Chemical functionalization is required to adapt graphenes properties to many applications. However, most covalent functionalization schemes are spontaneous or defect driven and are not suitable for applications requiring directed assembly of molecules on graphene substrates. In this work, we demonstrated electrochemically driven covalent bonding of phenyl iodoniums onto epitaxial graphene. The amount of chemisorption was demonstrated by varying the duration of the electrochemical driving potential. Chemical, electronic, and defect states of phenyl-modified graphene were studied by photoemission spectroscopy, spatially resolved Raman spectroscopy, and water contact angle measurement. Covalent attachment rehybridized some of the delocalized graphene sp2 orbitals to localized sp3 states. Control over the relative spontaneity (reaction rate) of covalent graphene functionalization is an important first step to the practical realization of directed molecular assembly on graphene. More than 10 publications, conference presentations, and program highlights were produced (some invited), and follow-on funding was obtained to continue this work.

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TYPE SAND Report YEAR 2013

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