Notes:

Volume 3, Issue 2

Insights in Analytical Electrochemistry

ISSN: 2470-9867

Analytical Chemistry-Formulation 2017

August 28-30, 2017

Page 60

8

th

Annual Congress on

&

14

th

International Conference and Exhibition on

August 28-30, 2017 Brussels, Belgium

Analytical and Bioanalytical Techniques

Pharmaceutical Formulations

Novel silica and silica-titania membranes for high temperature gas separations

Neha Bighane

Georgia Institute of Technology, USA

C

oncern over depleting supplies of fossil fuels (coal, oil and natural gas) and increasing global warming has driven

tremendous interest worldwide in the development of alternate clean fuels. Hydrogen gas is a suitable candidate for a clean,

abundant and efficient source of energy. Hydrogen is primarily produced from the steam reforming of natural gas coupled with

the water gas shift reaction. Selective removal of H

2

from syngas mixture in the presence of steam at 200-350oC can increase

the efficiency of the water gas shift reaction. It has been estimated that an overall energy saving of 43% in the water gas shift

reaction can be achieved with the presence of a H

2

/CO

2

membrane unit. A gas separation membrane is a robust material that

enables selective permeation of one gas from a mixture based on partial pressure driving force. Novel silica and silica-titania

membranes were developed from the controlled oxidative thermolysis of crosslinked polydimethylsiloxane precursors. The

PDMS precursor film is prepared by humidity induced condensation cure reaction of PDMS resin with an alkoxy crosslinker.

The rubbery PDMS films are heated to 377oC in an oxygen atmosphere in a tubular furnace and this results in the formation

of silica membrane films. The developed silica membranes are microporous amorphous silica, have 1.4% water adsorption

and can withstand up to 377oC in an oxidizing environment. They exhibit high hydrogen permeability and moderate H

+

/

CO

2

selectivity. Silica-titania membranes have been fabricated from controlled oxidative thermolysis of Ti-crosslinked PDMS

by heating to 407oC. The developed silica-titania membranes are microporous amorphous silica-titania, have 0.85% water

adsorption and can withstand up to 407oC in an oxidizing environment. At 80oC at 30 psia, silica membranes have selectivity of

H

2

/CO

2

= 2 and H

2

/N

2

=20. At 35oC at 55 psia, silica-titania membranes have molecular sieving selectivity of H

2

/CO

2

=2.33, H

2

/

N

2

=H

2

/CH

4

=64 and O

2

/N

2

=4.97. Material characterization studies on silica and silica-titania membranes include TGA, FTIR,

XPS, SEM, EDS, TEM, BET and adsorption measurements.

Biography

Neha Bighane done Master of Science in Chemical Engineering, from Georgia Institute of Technology, Atlanta, USA, in Spring 2012. She was 8 years graduate

research assistant, 2007-2015, ChBE, Georgia Tech, USA. She was junior research fellow, for PhD degree, in Indian Institute of Chemical Technology (Hyderabad,

India) in collaboration with Royal Melbourne Institute of Technology (Melbourne, Australia). She published 2 Paper in Journal of Membrane Science, she attended

5 in national and international conferences She was Selected as a Global Scholar by PreScouters Inc., in February 2015 and awarded certificate of merit in social

science by CBSE, India in 2001.

nbighane3@gmail.com

Neha Bighane, Insights in Analytical Electrochemistry, 3:2

DOI: 10.21767/2470-9867-C1-002