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Versatile Adsorption Processes for the Capture of Carbon Dioxide from Industrial Sources - FlexICCS
Campbell, Eleanor
(Principal Investigator)
School of Chemistry
Overview
Fingerprint
Research output
(2)
Project Details
Status
Finished
Effective start/end date
1/09/16
→
30/04/21
Funding
EPSRC:
£278,127.00
View all
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Fingerprint
Explore the research topics touched on by this project. These labels are generated based on the underlying awards/grants. Together they form a unique fingerprint.
Carbon capture
Engineering & Materials Science
100%
Steam reforming
Engineering & Materials Science
98%
Adsorbents
Engineering & Materials Science
56%
Steam Reforming
Chemical Compounds
45%
steam
Physics & Astronomy
43%
Adsorption
Engineering & Materials Science
39%
methane
Physics & Astronomy
37%
Vacuum
Engineering & Materials Science
35%
Research output
Research output per year
2019
2019
2020
2020
2
Article
Research output per year
Research output per year
Monolithic Adsorbent-Based Rapid-Cycle Vacuum Pressure Swing Adsorption Process for Carbon Capture from Small-Scale Steam Methane Reforming
Sharma, I.
,
Friedrich, D.
,
Golden, T.
&
Brandani, S.
,
4 Mar 2020
, (E-pub ahead of print)
In:
Industrial & Engineering Chemistry Research.
Research output
:
Contribution to journal
›
Article
›
peer-review
Open Access
File
Carbon capture
100%
Steam reforming
98%
Adsorbents
97%
Steam Reforming
91%
Adsorption
79%
Exploring the opportunities for carbon capture in modular, small-scale steam methane reforming: an energetic perspective
Sharma, I.
,
Friedrich, D.
,
Golden, T.
&
Brandani, S.
,
4 May 2019
, (E-pub ahead of print)
In:
International journal of hydrogen energy.
Research output
:
Contribution to journal
›
Article
›
peer-review
Open Access
File
Carbon capture
100%
Steam reforming
98%
steam
87%
methane
74%
carbon
54%