A long-chain protic ionic liquid inside silica nanopores: Enhanced proton mobility due to efficient self-assembly and decoupled proton transport
Journal article, 2018

We report enhanced protonic and ionic dynamics in an imidazole/protic ionic liquid mixture confined within the nanopores of silica particles. The ionic liquid is 1-octylimidazolium bis(trifluoromethanesulfonyl)imide ([HC8Im][TFSI]), while the silica particles are microsized and characterized by internal well connected nanopores. We demonstrate that the addition of imidazole is crucial to promote a proton motion decoupled from molecular diffusion, which occurs due to the establishment of new N-H⋯N hydrogen bonds and fast proton exchange events in the ionic domains, as evidenced by both infrared and1H NMR spectroscopy. An additional reason for the decoupled motion of protons is the nanosegregated structure adopted by the liquid imidazole/[HC8Im][TFSI] mixture, with segregated polar and non-polar nano-domains, as clearly shown by WAXS data. This arrangement, promoted by the length of the octyl group and thus by significant chain-chain interactions, reduces the mobility of molecules (Dmol) more than that of protons (DH), which is manifested by DH/Dmolratios greater than three. Once included into the nanopores of hydrophobic silica microparticles, the nanostructure of the liquid mixture is preserved with slightly larger ionic domains, but effects on the non-polar ones are unclear. This results in a further enhancement of proton motion with localised paths of conduction. These findings demonstrate significant progress in the design of proton conducting materials via tailor-made molecular structures as well as by smart exploitation of confinement effects. Compared to other imidazole-based proton conducting materials that are crystalline up to 90 °C or above, the gel materials that we propose are useful for applications at room temperature, and can thus find applications in e.g. intermediate temperature proton exchange fuel cells.

Author

Mounesha Garaga Nagendrachar

Dalhousie University

Vassilios Dracopoulos

Institute of Chemical Engineering and High Temperature Chemical Processes

Ulrike Werner-Zwanziger

Dalhousie University

Josef W. Zwanziger

Dalhousie University

M. Maréchal

Grenoble Alpes University

Michael Persson

Akzo Nobel - Pulp and Performance Chemicals

Lars Nordstierna

Chalmers, Chemistry and Chemical Engineering, Applied Chemistry

Anna Martinelli

Chalmers, Chemistry and Chemical Engineering, Applied Chemistry

Nanoscale

2040-3364 (ISSN) 2040-3372 (eISSN)

Vol. 10 26 12337-12348

Subject Categories

Physical Chemistry

Ceramics

Materials Chemistry

DOI

10.1039/c8nr02031k

More information

Latest update

9/13/2018