Serdar Ozturk, Ph.D.

Full Graduate Assistanship

Turkish State Planning Organization
2002-2006

President of the Republic of Turkey Fellowship

1997-2002

Karl O. Werwath Applied Research Award, MSOE

2021

Locally triggered nanoparticle aggregation by interfacial colloidal destabilization

AlChE Annual Meeting  Minneapolis, MN

2011-10-16

Using microfluidics to probe anomalous diffusion in alumina nanofluids

ECI International Conference on Nanofluids: Fundamental and Applications II  Montreal, Canada

2010-08-15

Graphene-enhanced nanorefrigerants

Ozturk, S., Hassan, Y.A., and Ugaz, V.M.

2013
Recent reports that a host liquid's thermal properties can be augmented by dispersal of small quantities of nanoparticles have stimulated intense interest as an intriguing avenue to produce advanced heat transfer fluids. But effects are challenging to exploit in practical settings because it is difficult to prepare refrigerant-based dispersions displaying sufficient long-term stability. Moreover, the most dramatic enhancements in thermal conductivity obtained using anisotropic nanomaterials (e.g., carbon nanotubes) are achieved at the expense of a severe viscosity increase. Here we overcome these limitations by introducing a robust surfactant-mediated dispersal method that enables stable suspensions containing a range of nanomaterials to be straightforwardly prepared as additives to ordinary commercial refrigerants. We apply this approach to formulate a new class of nanorefrigerants containing graphene nanosheets that uniquely match the superior thermal conductivity enhancements attained in carbon nanotube suspensions without their accompanying viscosity penalty. These suspensions can be directly substituted for conventional refrigerants to inexpensively achieve increased efficiency in many thermal management applications.

A simple microfluidic probe nanoparticle suspension activity

Ozturk, S., Hassan, Y.A., and Ugaz, V.M.

2012

We describe a simple experimental tool that enables stability of multicomponent nanoparticle suspensions to be readily assessed by establishing a confinement-imposed chemical discontinuity at the interface between co-flowing laminar streams in a microchannel. When applied to examine Al2O3 nanoparticle suspensions, this method readily reveals compositions that are susceptible to aggregation even when conventional bulk measurements (zeta potential, dynamic light scattering, bulk viscosity) suggest only subtle differences between formulations. This microfluidic stability test enables simple and rapid assessment of quality and variability in complex multicomponent mixtures for which few, if any, comparable data exist. The paradoxical ease at which localized aggregation can be triggered in suspensions that would otherwise appear stable also serves as a caution to researchers undertaking tracer-based studies of nanomaterial suspensions.

Interfacial complexation explains anomalous diffusion in nanofluids

Ozturk, S., Hassan, Y. A., Ugaz, V. M.

2010

A recent report describing dramatic anomalous enhancement in mass transport properties of nanofluids (>1000% increase in tracer dye diffusivity) has excited intense interest, but the findings have yet to be conclusively confirmed or explained. Here we investigate these phenomena using a microfluidic approach to directly probe tracer diffusion so that interactions between the suspension’s principle components (nanoparticles, surfactant, and dye) can be clearly identified. Under conditions matching previously reported studies, we unexpectedly observe spontaneous formation of highly focused and intensely fluorescent plumes at the interface between fluid streams, suggesting strong complexation interactions between the dye and nanoparticles. These phenomena, driven by competition between the rates at which free tracer molecules are transported into the interfacial zone subsequently consumed by dye−nanoparticle complexation, have likely been incorrectly interpreted as anomalous diffusion enhancement. These interactions are important to consider when devising tracer-based studies of nanoparticle suspensions and may lay a foundation for new adsorption-based analytical methods.

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Preparation and characterization of calcium stearate powders and films prepared by precipitation and Langmuir-Blodgett techniques

Gonen, M., Ozturk, S., Balkose, D., Okur, S., Umemura, J.

2010

The preparation of calcium stearate (CaSt2) using precipitation and Langmuir−Blodgett techniques was investigated in this study. While sodium stearate and calcium chloride were used in the precipitation process, calcium stearate nanofilms were produced from stearic acid and calcium chloride in sodium borate buffer with the Langmuir−Blodgett technique. Fourier transform infrared (FTIR) spectroscopy indicated carboxylate bands at 1577 and 1543 cm−1 in equal intensity in the powder form, but the films had a higher intensity 1577 cm−1 band than the 1543 cm−1 band. This showed the calcium ions associated with the COO− ions in the monodendate and bidendate structures in powders, and it was mainly in the bidendate structure in films. While characteristic peaks of CaSt2 at 2θ values of 6.40° and 19.58° were obtained in the X-ray diffraction (XRD) pattern of the dried powdered product, no sharp peaks were present in the 13 layer CaSt2 film. From scanning electron microscopy (SEM) micrographs, it was seen that calcium stearate powder had lamellar structure and the average particle size was 600 nm. The AFM picture of the CaSt2 film indicated the surface was not smooth with a peak to valley distance of 6 nm.

Effect of humidity on electrical conductivity of zinc stearate nanofilms

Ozturk, S., Balkose, D., Okur, S., Umemura, J.

2007

In this work, stearic acid (StAc) and zinc stearate (ZnSt2) nanofilms were deposited on glass and silver substrates using Langmuir–Blodgett (LB) film technique and their structural and electrical properties were investigated. X-ray diffraction and IR techniques revealed that more crystalline and better films were obtained from ZnSt2 compare to StAc. Electrical conductivity of ZnSt2 LB films with 13 layers having 28 nm thickness were measured in the range of humidity of 20–60% and it is seen that the conductivity was very sensitive to relative humidity (RH) above 40% at 25 °C and showed no hysteresis during adsorption and desorption of water vapor. Water vapor adsorption isotherm of ZnSt2 powders was determined and conductivity increase with humidity was attributed to water vapor adsorption.

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