posted on 2024-11-30, 04:29authored byJason
J. Calvin, Christopher DelRe, Daniel P. Erdosy, Joy Cho, Hyukhun Hong, Jarad A. Mason
Polymers can be used to augment the properties of microporous
materials,
affording enhanced processability, stability, and compatibility. Manipulating
polymers to target specific properties, however, requires detailed
knowledge of how different polymers and microporous materials interact.
Here, we report a study of the thermodynamics of polyethylene glycol
(PEG) intrusion into a representative hydrophobic zeolite (silicalite-1)
and metal–organic framework [ZIF-67; Co(2-methylimidazolate)2] in water, both of which can be formed into colloidally stable
aqueous dispersionstermed “microporous water”with
dry, guest-accessible pore networks. Through a combination of O2 capacity measurements and isothermal titration calorimetry
(ITC), we establish relationships between PEG intrusion behavior,
polymer length, polymer end groups, and the structure of the microporous
framework. In particular, we find that PEG intrusion is exothermic
for silicalite-1 but endothermic for ZIF-67. Our results provide fundamental
insights into polymer intrusion in microporous materials that should
inform efforts to design composite solids and fluids with enhanced
functionality.