Materials with high proton conductivity above 200 °C based on a nanoporous metal-organic framework and non-aqueous ionic media

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Materials with high proton conductivity above 200 °C based on a nanoporous metal-organic framework and non-aqueous ionic media. / Ponomareva, Valentina G.; Aliev, Sokhrab B.; Shutova, Elena S. et al.

In: RSC Advances, Vol. 7, No. 1, 01.01.2017, p. 403-407.

Research output: Contribution to journal › Article › peer-review

Author

Ponomareva, Valentina G. ; Aliev, Sokhrab B. ; Shutova, Elena S. et al. / Materials with high proton conductivity above 200 °C based on a nanoporous metal-organic framework and non-aqueous ionic media. In: RSC Advances. 2017 ; Vol. 7, No. 1. pp. 403-407.

BibTeX

@article{8869d7df0cdd4f278ac652c94113f3ee,

title = "Materials with high proton conductivity above 200 °C based on a nanoporous metal-organic framework and non-aqueous ionic media",

abstract = "Fuel cell devices working above 200 °C provide a number of advantages such as low poisoning of the catalyst, high energy output and efficient heat recovery. However, new materials for proton exchange membranes (PEM) must be developed to operate at such conditions. Here we demonstrate that by mixing nanoporous coordination polymer MIL-101 and (benz)imidazolium triflate salts at high pressure with subsequent annealing a hybrid material with superior proton conducting properties approaching 0.1 S cm−1 at temperatures above 200 °C and in a dry atmosphere could be obtained. The ionic components completely fill the nanopores of the MIL-101 coordination polymer as well as the intercrystallite space, forming a continuous anhydrous proton conducting media. The MIL-101 microcrystalline framework improves the mechanical properties of the material and provides a number of other advantages, such as an increase of the ion conductivity at lower temperatures and a facilitation of the proton transfer by lowering of the activation energy. The present study contains spectroscopic, texture and calorimetric analyses of the reported compounds as well as the investigation of nanoscopic composite effects which affect the phase transition parameters of the ionic components.",

keywords = "POLYMER ELECTROLYTE MEMBRANES, TEMPERATURE FUEL-CELLS, COORDINATION POLYMERS, ACID MEMBRANES, COMPOSITES",

author = "Ponomareva, {Valentina G.} and Aliev, {Sokhrab B.} and Shutova, {Elena S.} and Pishchur, {Denis P.} and Dybtsev, {Danil N.} and Fedin, {Vladimir P.}",

year = "2017",

month = jan,

day = "1",

doi = "10.1039/c6ra25552c",

language = "English",

volume = "7",

pages = "403--407",

journal = "RSC Advances",

issn = "2046-2069",

publisher = "ROYAL SOC CHEMISTRY",

number = "1",

}

RIS

TY - JOUR

T1 - Materials with high proton conductivity above 200 °C based on a nanoporous metal-organic framework and non-aqueous ionic media

AU - Ponomareva, Valentina G.

AU - Aliev, Sokhrab B.

AU - Shutova, Elena S.

AU - Pishchur, Denis P.

AU - Dybtsev, Danil N.

AU - Fedin, Vladimir P.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Fuel cell devices working above 200 °C provide a number of advantages such as low poisoning of the catalyst, high energy output and efficient heat recovery. However, new materials for proton exchange membranes (PEM) must be developed to operate at such conditions. Here we demonstrate that by mixing nanoporous coordination polymer MIL-101 and (benz)imidazolium triflate salts at high pressure with subsequent annealing a hybrid material with superior proton conducting properties approaching 0.1 S cm−1 at temperatures above 200 °C and in a dry atmosphere could be obtained. The ionic components completely fill the nanopores of the MIL-101 coordination polymer as well as the intercrystallite space, forming a continuous anhydrous proton conducting media. The MIL-101 microcrystalline framework improves the mechanical properties of the material and provides a number of other advantages, such as an increase of the ion conductivity at lower temperatures and a facilitation of the proton transfer by lowering of the activation energy. The present study contains spectroscopic, texture and calorimetric analyses of the reported compounds as well as the investigation of nanoscopic composite effects which affect the phase transition parameters of the ionic components.

AB - Fuel cell devices working above 200 °C provide a number of advantages such as low poisoning of the catalyst, high energy output and efficient heat recovery. However, new materials for proton exchange membranes (PEM) must be developed to operate at such conditions. Here we demonstrate that by mixing nanoporous coordination polymer MIL-101 and (benz)imidazolium triflate salts at high pressure with subsequent annealing a hybrid material with superior proton conducting properties approaching 0.1 S cm−1 at temperatures above 200 °C and in a dry atmosphere could be obtained. The ionic components completely fill the nanopores of the MIL-101 coordination polymer as well as the intercrystallite space, forming a continuous anhydrous proton conducting media. The MIL-101 microcrystalline framework improves the mechanical properties of the material and provides a number of other advantages, such as an increase of the ion conductivity at lower temperatures and a facilitation of the proton transfer by lowering of the activation energy. The present study contains spectroscopic, texture and calorimetric analyses of the reported compounds as well as the investigation of nanoscopic composite effects which affect the phase transition parameters of the ionic components.

KW - POLYMER ELECTROLYTE MEMBRANES

KW - TEMPERATURE FUEL-CELLS

KW - COORDINATION POLYMERS

KW - ACID MEMBRANES

KW - COMPOSITES

UR - http://www.scopus.com/inward/record.url?scp=85008700615&partnerID=8YFLogxK

U2 - 10.1039/c6ra25552c

DO - 10.1039/c6ra25552c

M3 - Article

AN - SCOPUS:85008700615

VL - 7

SP - 403

EP - 407

JO - RSC Advances

JF - RSC Advances

SN - 2046-2069

IS - 1

ER -

ID: 10316706