Novel Silica Nanostructured Platforms with Engineered Surface Functionality and Spherical Morphology for Low-Cost High-Efficiency Carbon Capture Email Page
email
Print This Page
print
Performer:  Delaware State University Location:  Dover, Delaware
Project Duration:  07/01/2014 – 09/30/2017 Award Number:  FE0023541
Technology Area:  University Training and Research Total Award Value:  $234,358
Key Technology:  High Performance Materials DOE Share:  $234,358
Performer Share:  $0

<strong>Top:</strong> TEM images of NSN-1 (a) and NSN-3(b) showing<br/>the nanosheet-structure of two novel materials.<br/><strong>Bottom:</strong> SEM images of materials NSN-1 and NSN-3
Top: TEM images of NSN-1 (a) and NSN-3(b) showing
the nanosheet-structure of two novel materials.
Bottom: SEM images of materials NSN-1 and NSN-3

Project Description

Developments in nano-engineered materials have resulted in the discovery of a number of new materials which may have beneficial applications for CO2 capture. This project aims to develop and evaluate silica-based nanostructure platforms containing amine-based solid sorbents for post-combustion carbon dioxide (CO2) capture. The fabrication process will allow for significantly enhanced porosity and surface area, which will allow for increased CO2 adsorption capacity. In addition, the use of inexpensive raw materials and low-cost synthetic processes will position these platforms as a competitive solid sorbent for replacement of solution-based amine scrubbing technologies used in post-combustion CO2 capture.

Project Benefits

Development of inexpensive CO2 adsorbents could solve issues associated with the operation of alkaline fuel cells. As well, the materials developed will remove CO2 from air in existing fossil-burning plants and could lead to the development of efficient CO2 capture technologies.

Presentations, Papers, and Publications

Contact Information

Federal Project Manager Barbara Carney: barbara.carney@netl.doe.gov
Technology Manager Briggs White: briggs.white@netl.doe.gov
Principal Investigator Cheng-Yu Lai: Cylai@desu.edu