Dataset for Hydrogen Storage Capacity of Freeze Cast Microporous Monolithic Composites
This dataset presents the nitrogen adsorption isotherms for a range of powders and monoliths formed from them used to calculate their BET surface area. Hydrogen isotherms are also produced to show the storage capacity for the same entities. A comparison of the mass of hydrogen stored using the monoliths compared with compression is also included. A comparison of the mass of hydrogen stored by compression at different conditions with activated carbon AX21 at different conditions is included. The effect of the volume of adsorbent on the mass of hydrogen stored is also included.
Cite this dataset as:
Butler, C.,
GKN Aerospace,
2024.
Dataset for Hydrogen Storage Capacity of Freeze Cast Microporous Monolithic Composites.
Bath: University of Bath Research Data Archive.
Available from: https://doi.org/10.15125/BATH-01419.
Export
Data
PIM-1 H2 77K 04_04_2022.XLS
application/vnd.ms-excel (109kB)
Creative Commons: Attribution 4.0
Adsorption isotherm data output from 3flex for PIM-1 powder
Nitrogen_Adsorption_Isotherm.opju
application/octet-stream (83kB)
Creative Commons: Attribution 4.0
Nitrogen adsorption isotherms for PIM-1 powder MSC-30, MSC-30SS powders and monoliths.
Hydrogen_adsorption_isotherm.opju
application/octet-stream (102kB)
Creative Commons: Attribution 4.0
Hydrogen adsorption isotherms for PIM-1 powder MSC-30, MSC-30SS powders and monoliths.
Mass_hydrogen-stored.opju
application/octet-stream (88kB)
Creative Commons: Attribution 4.0
Comparison of mass of hydrogen stored on monoliths vs compression for 1.4 l tank.
Effect of adsorbent_Volume.opju
application/octet-stream (67kB)
Creative Commons: Attribution 4.0
The effect of different masses of adsorbent on mass of hydrogen stored.
Contributors
Tim Mays
Supervisor
University of Bath
V. Sahadevan
Editor
GKN Aerospace
R. O'Malley
Editor
GKN Aerospace
Daniel Graham
Sponsor
GKN Aerospace
Chris Bowen
Supervisor
University of Bath
University of Bath
Sponsor
Documentation
Data collection method:
Most of this data was obtained experimentally from machines producing adsorption isotherms. Some of the data was collected from literature. Please see the associated papers for full methodological details.
Data processing and preparation activities:
Data is directly from literature and referenced.
Technical details and requirements:
Excel, matlab and Origin were used to create this data. Experimental data was collected from a 3flex machine from micromertics.
Funders
University of Bath
https://doi.org/10.13039/501100000835
GKN Aerospace
https://doi.org/10.13039/501100014815
GKN Prosperity Partnership
EP/X025403/1
Engineering and Physical Sciences Research Council
https://doi.org/10.13039/501100000266
UK-HyRES: EPSRC Hub for Research Challenges in Hydrogen and Alternative Liquid Fuels
EP/X038963/1
Engineering and Physical Sciences Research Council
https://doi.org/10.13039/501100000266
Frontier Research Guarantee - Processing of Smart Porous Electro-Ceramic Transducers (ProSPECT)
EP/X023265/1
Publication details
Publication date: 18 July 2024
by: University of Bath
Version: 1
DOI: https://doi.org/10.15125/BATH-01419
URL for this record: https://researchdata.bath.ac.uk/1419
Related papers and books
Butler, C., Mays, T. J., Sahadevan, V., O’Malley, R., Graham, D. P., and Bowen, C. R., 2024. Hydrogen storage capacity of freeze cast microporous monolithic composites. Materials Advances, 5(17), 6864-6872. Available from: https://doi.org/10.1039/d4ma00325j.
Butler, C., Narayan, B., Mays, T. J., Lowe, T., O’Malley, R., Sahadevan, V., and Bowen, C. R., 2025. Freeze Casting of Microporous Composite Beads Based on a Polymer of Intrinsic Microporosity for Gas Storage Applications. ACS Omega, 10(16), 15959-15966. Available from: https://doi.org/10.1021/acsomega.4c07247.
Contact information
Please contact the Research Data Service in the first instance for all matters concerning this item.
Contact person: Catherine Butler
Faculty of Engineering & Design
Chemical Engineering
Mechanical Engineering
