Sema Ermez scite author profile

Self-seeded growth of semiconducting nanowires offers significant advantages over foreign metal-seeded growth by eliminating seed-associated impurities. However, density and diameter control of self-seeded nanowires has proven challenging although it is required for integration of nanowires into optoelectronic devices. We report the selfseeded growth of GaAs nanowire arrays on GaAs (111)B, (110), and (111)A substrates by metal−organic chemical vapor deposition. Our approach involves two steps: the in situ deposition of Ga seed particles and subsequent GaAs nanowire growth. Control of nanowire diameter and array density is achieved via Ga seed deposition temperature and substrate orientation; increased seed deposition temperatures or changing substrate orientation from (111)A to ( 110) and ( 111)B yields reduced areal density and larger nanowire diameters. The density and diameter control approaches could be extended to other self-seeded III−V nanowire material systems.

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Mapping of Strain Fields in GaAs/GaAsP Core–Shell Nanowires with Nanometer Resolution

Jones

Ermez

Gradečak

2015

Nano Lett.

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We report the nanoscale quantification of strain in GaAs/GaAsP core-shell nanowires. By tracking the shifting of higher-order Laue zone (HOLZ) lines in convergent beam electron diffraction patterns, we observe unique variations in HOLZ line separation along different facets of the core-shell structure, demonstrating the nonuniform strain fields created by the heterointerface. Furthermore, through the use of continuum mechanical modeling and Bloch wave analysis we calculate expected HOLZ line shift behavior, which are directly matched to experimental results. This comparison demonstrates both the power of electron microscopy as a platform for nanoscale strain characterization and the reliability of continuum models to accurately calculate complex strain fields in nanoscale systems.

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Impact of nucleation conditions on diameter modulation of GaAs nanowires

Crawford¹,

Ermez²,

Haberfehlner³

et al. 2015

Nanotechnology

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Diameter-modulated nanowires can be used to impart unique properties to nanowire-based devices. Here, diameter modulation along Au-seeded GaAs nanowires was achieved by varying the flux of the III and V precursors during growth. Furthermore, three different types of [111]B-oriented nanowires were observed to display distinct differences in diameter modulation, growth rate, and cross-sectional shape. These differences are attributed to the presence of multiple distinct Au-Ga seed particle phases at the growth temperature of 420 °C. We show that the diameter modulation behavior can be modified by the growth conditions during nanowire nucleation, including temperature, V/III ratio, substrate orientation, and seed particle size. These results demonstrate the general viability of flow-controlled diameter modulation for compound semiconductors and highlight both opportunities and challenges that can arise from using compound-forming alloys to seed nanowire growth.

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Room Temperature Sensing Achieved by GaAs Nanowires and oCVD Polymer Coating

Wang

Ermez

Göktaş

et al. 2017

Macromol. Rapid Commun.

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Novel structures comprised of GaAs nanowire arrays conformally coated with conducting polymers (poly(3,4-ethylenedioxythiophene) (PEDOT) or poly(3,4-ethylenedioxythiophene-co-3-thiophene acetic acid) display both sensitivity and selectivity to a variety of volatile organic chemicals. A key feature is room temperature operation, so that neither a heater nor the power it would consume, is required. It is a distinct difference from traditional metal oxide sensors, which typically require elevated operational temperature. The GaAs nanowires are prepared directly via self-seeded metal-organic chemical deposition, and conducting polymers are deposited on GaAs nanowires using oxidative chemical vapor deposition (oCVD). The range of thickness for the oCVD layer is between 100 and 200 nm, which is controlled by changing the deposition time. X-ray diffraction analysis indicates an edge-on alignment of the crystalline structure of the PEDOT coating layer on GaAs nanowires. In addition, the positive correlation between the improvement of sensitivity and the increasing nanowire density is demonstrated. Furthermore, the effect of different oCVD coating materials is studied. The sensing mechanism is also discussed with studies considering both nanowire density and polymer types. Overall, the novel structure exhibits good sensitivity and selectivity in gas sensing, and provides a promising platform for future sensor design.

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Functional Pathways in Proteins Are Uncovered By Strong Disorder

Atılgan

Ermez

Keskin

et al. 2010

Biophysical Journal

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Sema Ermez

Self-Seeded Growth of GaAs Nanowires by Metal–Organic Chemical Vapor Deposition

Mapping of Strain Fields in GaAs/GaAsP Core–Shell Nanowires with Nanometer Resolution

Impact of nucleation conditions on diameter modulation of GaAs nanowires

Room Temperature Sensing Achieved by GaAs Nanowires and oCVD Polymer Coating

Functional Pathways in Proteins Are Uncovered By Strong Disorder

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