Education
Ph.D., Chemical Engineering, Princeton University, 1981
M.A., Undesignated, Princeton University, 1978
M.S., Chemical Engineering, Case Western Reserve University, 1977
B.S., Chemical Engineering, Case Western Reserve University, 1976
Awards and Recognitions
2015,
AIChE Fellow,
American Institute of Chemical Engineers
Research Interests
Research interests include particle science and processing, colloidal phenomena, dispersive mixing, and acoustic separation and materials processing methods.
Our research focuses on the physical behavior and processing characteristics of multiphase (particle-liquid or fluid-liquid) dispersions, including suspensions of biological cells. These include fundamental studies of dispersive mixing phenomena for polymer composites and morphology development in emulsions that can be used as templates for advanced materials. We have also developed several methods that use resonant ultrasonic fields to perform sharp separations with applications in chemical and biochemical processing. This has been extended to the development of biochemical reactor configurations in which processing efficiency is enhanced through the application of ultrasonic fields. Additional studies are dedicated to the development of morphology in dispersions using acoustic processing techniques.
Teaching Interests
Transport Phenomena. Mathematical methods.
Publications
Gong, X., Zhao, B., Manas-Zloczower, I., & Feke, D. L.
(2021).
Effect of curing bath conditions on the morphology and structure of poly(high internal phase emulsion) fibers.
Journal of Applied Polymer Science,
138
(11),
50019.
Gong, X., Zhao, B., Manas-Zloczower, I., & Feke, D. L.
(2021).
Effect of curing bath conditions on the morphology and structure of poly(high internal phase emulsion) fibers.
Journal of Applied Polymer Science,
138
(11).
Gong, X., Sang, Z., Guo, H., Ke, K., Manas-Zloczower, I., & Feke, D. L.
(2021).
Piezoresistive Strain Sensors Based on Psyllium-Carbon Nanostructure Skeletons.
Composites B,
209
(),
108610.
Zhao, B., Rohm, K., Wang, Y., Gong, X., Manas-Zloczower, I., & Feke, D. L.
(2020).
A Compact Volume-Expandable Sorbent (CVES) for Oil and Solvent Capture.
ACS Applied Poly-mer Materials,
3
(1),
494-503.
DOI: 10.1021/acsapm.0c01324
Foudazi, R., Zhao, B., Gokun, P., Manas-Zloczower, I., Rowan, S., & Feke, D. L.
(2020).
The Effect of Shear on the Evolution of Morphology in High Internal Phase Emulsions Used as Templates for Structural and Functional Polymer Foams.
ACS Applied Polymer Materials,
2
(4),
1579-1586.
Zhao, B., Gedler, G., Manas-Zloczower, I., Rowan, S. J., & Feke, D. L.
(2020).
Fluid transport in open-cell polymeric foams: effect of morphology and surface wettability.
SN Applied Sciences,
2
(2).
DOI: 10.1007/s42452-020-1983-1
Kravchenko, O., Gedler, G., Kravchenko, S., Feke, D. L., & Manas-Zloczower, I.
(2018).
Modeling Compressive Behavior of Open-Cell Polymerized High Internal Phase Emulsions: Effects of Density and Morphology.
Soft Matter,
14
(),
1637-1646.
Kravchenko, O., Gedler, G., Kravchenko, S., Feke, D. L., & Manas-Zloczower, I.
(2018).
Modeling compressive behavior of open-cell polymerized high internal phase emulsions: effects of density and morphology.
Soft Matter,
14
(9),
1637-1646.
Li, R., & Feke, D. L.
(2015).
Rheological and kinetic study of the ultrasonic degradation of locust bean gum in aqueous saline and salt-free solutions.
Ultrasonics Sonochemistry,
27
(),
334-338.
Li, R., & Feke, D. L.
(2015).
Rheological and kinetic study of the ultrasonic degradation of xanthan gum in aqueous solution: Effects of pyruvate group.
Carbohydrate Polymers,
124
(),
216-221.
Li, R., & Feke, D. L.
(2015).
Rheological and kinetic study of the ultrasonic degradation of xanthan gum in aqueous solutions.
Food Chemistry,
172
(),
808-813.
Law, Y., Feke, D. L., & Manas-Zloczower, I.
(2014).
Modeling of the Torque Requirements for the Mixing and Dispersion of Silica into Rubber.
International Polymer Processing Journal,
29
(1),
112-118.
Loos, M., Yang, J., Feke, D. L., Manas-Zloczower, I., Unal, S., & Unes, U.
(2013).
Enhancement of Fatigue Life of Polyurethane Composites Containing Carbon Nanotubes.
Composites B,
44
(),
740-744.