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Microporous polymers for hydrogen storage applications

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Published

Standard

Microporous polymers for hydrogen storage applications. / Wood, Colin D.; Tan, Bien; Stöckel, Ev et al.
234th ACS National Meeting, Abstracts of Scientific Papers. ACS, 2007. (ACS National Meeting Book of Abstracts).

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Wood, CD, Tan, B, Stöckel, E, Kirk, R, Rosseinsky, MJ, Bradshaw, D, Khimyak, Y, Niu, H, Trewin, A, Jiang, J, Su, F & Cooper, AI 2007, Microporous polymers for hydrogen storage applications. in 234th ACS National Meeting, Abstracts of Scientific Papers. ACS National Meeting Book of Abstracts, ACS, 234th ACS National Meeting, Boston, MA, United States, 19/08/07.

APA

Wood, C. D., Tan, B., Stöckel, E., Kirk, R., Rosseinsky, M. J., Bradshaw, D., Khimyak, Y., Niu, H., Trewin, A., Jiang, J., Su, F., & Cooper, A. I. (2007). Microporous polymers for hydrogen storage applications. In 234th ACS National Meeting, Abstracts of Scientific Papers (ACS National Meeting Book of Abstracts). ACS.

Vancouver

Wood CD, Tan B, Stöckel E, Kirk R, Rosseinsky MJ, Bradshaw D et al. Microporous polymers for hydrogen storage applications. In 234th ACS National Meeting, Abstracts of Scientific Papers. ACS. 2007. (ACS National Meeting Book of Abstracts).

Author

Wood, Colin D. ; Tan, Bien ; Stöckel, Ev et al. / Microporous polymers for hydrogen storage applications. 234th ACS National Meeting, Abstracts of Scientific Papers. ACS, 2007. (ACS National Meeting Book of Abstracts).

Bibtex

@inproceedings{3019bb621dfd4e5b97b6ba0857a79c39,
title = "Microporous polymers for hydrogen storage applications",
abstract = "We present here a route to produce microporous organic polymers based on the step growth polycondensation of dichloroxylene and other bischloromethyl monomers. We show that materials with very high surface areas (∼1900 m2/g BET; ∼3000 m2/g Langmuir) can be obtained by varying the structure of the monomer. The resulting materials can physisorb up to around 3.7 wt. % H2 at 77 K and 15 bar - the highest value yet reported for an organic polymer. We have used a combination of solid-state NMR, gas sorption measurements, and atomistic simulations in order to rationalize the surface area, pore size, and H2 sorption properties of these polymers. We believe that this flexible methodology represents an important advance for the future design of purely organic sorbents with enhanced gas storage capacities.",
author = "Wood, {Colin D.} and Bien Tan and Ev St{\"o}ckel and Ralph Kirk and Rosseinsky, {Matthew J.} and Darren Bradshaw and Yaroslav Khimyak and Hongjun Niu and Abbie Trewin and Jianxing Jiang and Fabing Su and Cooper, {Andrew I.}",
year = "2007",
month = dec,
day = "31",
language = "English",
isbn = "0841269556",
series = "ACS National Meeting Book of Abstracts",
publisher = "ACS",
booktitle = "234th ACS National Meeting, Abstracts of Scientific Papers",
note = "234th ACS National Meeting ; Conference date: 19-08-2007 Through 23-08-2007",

}

RIS

TY - GEN

T1 - Microporous polymers for hydrogen storage applications

AU - Wood, Colin D.

AU - Tan, Bien

AU - Stöckel, Ev

AU - Kirk, Ralph

AU - Rosseinsky, Matthew J.

AU - Bradshaw, Darren

AU - Khimyak, Yaroslav

AU - Niu, Hongjun

AU - Trewin, Abbie

AU - Jiang, Jianxing

AU - Su, Fabing

AU - Cooper, Andrew I.

PY - 2007/12/31

Y1 - 2007/12/31

N2 - We present here a route to produce microporous organic polymers based on the step growth polycondensation of dichloroxylene and other bischloromethyl monomers. We show that materials with very high surface areas (∼1900 m2/g BET; ∼3000 m2/g Langmuir) can be obtained by varying the structure of the monomer. The resulting materials can physisorb up to around 3.7 wt. % H2 at 77 K and 15 bar - the highest value yet reported for an organic polymer. We have used a combination of solid-state NMR, gas sorption measurements, and atomistic simulations in order to rationalize the surface area, pore size, and H2 sorption properties of these polymers. We believe that this flexible methodology represents an important advance for the future design of purely organic sorbents with enhanced gas storage capacities.

AB - We present here a route to produce microporous organic polymers based on the step growth polycondensation of dichloroxylene and other bischloromethyl monomers. We show that materials with very high surface areas (∼1900 m2/g BET; ∼3000 m2/g Langmuir) can be obtained by varying the structure of the monomer. The resulting materials can physisorb up to around 3.7 wt. % H2 at 77 K and 15 bar - the highest value yet reported for an organic polymer. We have used a combination of solid-state NMR, gas sorption measurements, and atomistic simulations in order to rationalize the surface area, pore size, and H2 sorption properties of these polymers. We believe that this flexible methodology represents an important advance for the future design of purely organic sorbents with enhanced gas storage capacities.

M3 - Conference contribution/Paper

AN - SCOPUS:37349081381

SN - 0841269556

SN - 9780841269552

T3 - ACS National Meeting Book of Abstracts

BT - 234th ACS National Meeting, Abstracts of Scientific Papers

PB - ACS

T2 - 234th ACS National Meeting

Y2 - 19 August 2007 through 23 August 2007

ER -