| 1 |
Effects of Electric Field and Polymer Structure on the Formation of Helical Nanofibers via Coelectrospinning
Wu HH, Bian FG, Gong RH, Zeng YC
Industrial & Engineering Chemistry Research, 54(39), 9585, 2015 |
| 2 |
Electric Field Design for Multijet Electropsinning with Uniform Electric Field
Zheng YS, Zhuang CM, Gong RH, Zeng YC
Industrial & Engineering Chemistry Research, 53(38), 14876, 2014 |
| 3 |
Needle and Needleless Electrospinning for Nanofibers
Zhou FL, Gong RH, Porat I
Journal of Applied Polymer Science, 115(5), 2591, 2010 |
| 4 |
Three-jet electrospinning using a flat spinneret
Zhou FL, Gong RH, Porat I
Journal of Materials Science, 44(20), 5501, 2009 |
| 5 |
Hydro-Entangled Bi-Component Microfiber Nonwovens
Gong RH, Nikoukhesal A
Polymer Engineering and Science, 49(9), 1703, 2009 |
| 6 |
Polymeric Nanofibers via Flat Spinneret Electrospinning
Zhou FL, Gong RH, Porat I
Polymer Engineering and Science, 49(12), 2475, 2009 |
| 7 |
Thermal oxidative degradation of bicomponent PP/PET fiber during thermal bonding process
Wang XY, Gong RH
Journal of Applied Polymer Science, 104(1), 391, 2007 |
| 8 |
Thermally bonded nonwoven filters composed of bicomponent polypropylene/polyester fiber. I. Statistical approach for minimizing the pore size
Wang XY, Gong RH
Journal of Applied Polymer Science, 101(4), 2689, 2006 |
| 9 |
Thermally bonded nonwoven filters composed of bi-component polypropylene/polyester fiber. II. Relationships between fabric area density, air permeability, and pore size distribution
Wang XY, Gong RH
Journal of Applied Polymer Science, 102(3), 2264, 2006 |
| 10 |
Frictional properties of thermally bonded 3D nonwoven fabrics prepared from polypropylene/polyester bi-component staple fiber
Wang XY, Gong RH, Dong Z, Porat I
Polymer Engineering and Science, 46(7), 853, 2006 |
