@article{ojha_stevens_stano_hoffman_clarke_gorga_2008, title={Characterization of electrical and mechanical properties for coaxial nanofibers with poly(ethylene oxide) (PEO) core and multiwalled carbon nanotube/PEO sheath}, volume={41}, ISSN={["1520-5835"]}, DOI={10.1021/ma702634a}, abstractNote={The present work focuses on the electrical and mechanical characterization of nanocomposite fibers having core−sheath (or bicomponent) morphologies. Owing to their unique mechanical and electrical properties, multiwalled carbon nanotubes (MWNTs) have been utilized in the nanocomposite construction. Submicron diameter nanofibers (200–300 nm) with core−sheath morphology were fabricated from a polymer/MWNT solution and collected in random mats. By constraining the MWNTs to the sheath, significant increases in the mechanical properties were observed at lower MWNT concentrations when compared to mats made from single-layer fibers. The electrical properties of the core−sheath mats showed similar gains, having a critical weight percent more than 10 times lower than that of the single-layer mats.}, number={7}, journal={MACROMOLECULES}, author={Ojha, Satyajeet S. and Stevens, Derrick R. and Stano, Kelly and Hoffman, Torissa and Clarke, Laura I. and Gorga, Russell E.}, year={2008}, month={Apr}, pages={2509–2513} }
 @article{ojha_stevens_hoffman_stano_klossner_scott_krause_clarke_gorga_2008, title={Fabrication and characterization of electrospun chitosan nanofibers formed via templating with polyethylene oxide}, volume={9}, ISSN={["1526-4602"]}, DOI={10.1021/bm800551q}, abstractNote={Chitosan is an abundantly common, naturally occurring, polysaccharide biopolymer. Its biocompatible, biodegradable, and antimicrobial properties have led to significant research toward biological applications such as drug delivery, artificial tissue scaffolds for functional tissue engineering, and wound-healing dressings. For applications such as tissue scaffolding, formation of highly porous mats of nanometer-sized fibers, such as those fabricated via electrospinning, may be quite important. Previously, strong acidic solvents and blending with synthetic polymers have been used to achieve electrospun nanofibers containing chitosan. As an alternative approach, in this work, polyethylene oxide (PEO) has been used as a template to fabricate chitosan nanofibers by electrospinning in a core-sheath geometry, with the PEO sheath serving as a template for the chitosan core. Solutions of 3 wt % chitosan (in acetic acid) and 4 wt % PEO (in water) were found to have matching rheological properties that enabled efficient core-sheath fiber formation. After removing the PEO sheath by washing with deionized water, chitosan nanofibers were obtained. Electron microscopy confirmed nanofibers of approximately 250 nm diameter with a clear core-sheath geometry before sheath removal, and chitosan nanofibers of approximately 100 nm diameter after washing. The resultant fibers were characterized with IR spectroscopy and X-ray diffraction, and the mechanical and electrical properties were evaluated.}, number={9}, journal={BIOMACROMOLECULES}, author={Ojha, Satyajeet S. and Stevens, Derrick R. and Hoffman, Torissa J. and Stano, Kelly and Klossner, Rebecca and Scott, Mary C. and Krause, Wendy and Clarke, Laura I. and Gorga, Russell E.}, year={2008}, month={Sep}, pages={2523–2529} }
 @article{ojha_afshari_kotek_gorga_2008, title={Morphology of electrospun nylon-6 nanofibers as a function of molecular weight and processing parameters}, volume={108}, ISSN={["1097-4628"]}, DOI={10.1002/app.27655}, abstractNote={Abstract}, number={1}, journal={JOURNAL OF APPLIED POLYMER SCIENCE}, author={Ojha, Satyajeet S. and Afshari, Mehdi and Kotek, Richard and Gorga, Russell E.}, year={2008}, month={Apr}, pages={308–319} }
 @article{mccullen_stevens_roberts_ojha_clarke_gorga_2007, title={Morphological, electrical, and mechanical characterization of electrospun nanofiber mats containing multiwalled carbon nanotubes}, volume={40}, ISSN={["1520-5835"]}, DOI={10.1021/ma061735c}, abstractNote={This work focuses on the development of electrically conducting porous nanocomposite structures by the incorporation of multiwalled carbon nanotubes (MWNT) into electrospun poly(ethylene oxide) (PEO) nanofibers. Electron microscopy confirmed the presence of individual aligned MWNT encapsulated within the fibers and showed fiber morphologies with diameters of 100−200 nm. Electrical conductance measurements of the random nanofiber mats showed that by increasing the concentration of MWNT we were able to produce porous nanocomposite structures with dramatically improved electrical conductivity. Above a percolation threshold of 0.365 ± 0.09 MWNT weight percent (wt %) in PEO the conductance increased by a factor of 1012 and then became approximately constant as the concentration of MWNT was further increased. Because of this percolation threshold, for a 1 wt % loading of MWNT, the conductivity is essentially maximized. Mechanical testing confirmed that the tensile strength did not change, and there was a 3-fold...}, number={4}, journal={MACROMOLECULES}, author={McCullen, Seth D. and Stevens, Derrick R. and Roberts, Wesley A. and Ojha, Satyajeet S. and Clarke, Laura I. and Gorga, Russell E.}, year={2007}, month={Feb}, pages={997–1003} }