Direct synthesis of carbide-derived carbon monoliths with hierarchical pore design by hard-templating

Nickel, Winfried, Oschatz, Martin, von der Lehr, Martin, Leistner, Matthias, Hao, Guang-Ping, Adelhelm, Philipp, Müller, Philipp, Smarsly, Bernd M., Kaskel, Stefan

01 September 2014

Carbide-derived carbon Monoliths (CDC-Ms) containing a multimodal arrangement with high volumes of micro- meso- and macropores are prepared by direct nanocasting of silica monoliths with polycarbosilane precursors. CDC-Ms show well-defined pore structures along with specific surface areas of more than 2600 m2 g−1 and overall pore volumes as high as 3.14 cm3 g−1. They exhibit advanced gas filtration properties compared to purely microporous materials due to enhanced storage capacities and kinetics as demonstrated by thermal response measurements based on InfraSORP technology.

Synthese

Carbid-abgeleiteter Kohlenstoff

synthesis

carbide-derived carbons

CDC

InfraSORP technology

ddc:540

ddc:530

rvk:VA 1120

rvk:UA 1000

Direct synthesis of carbide-derived carbon monoliths with hierarchical pore design by hard-templating

Nickel, Winfried, Oschatz, Martin, von der Lehr, Martin, Leistner, Matthias, Hao, Guang-Ping, Adelhelm, Philipp, Müller, Philipp, Smarsly, Bernd M., Kaskel, Stefan

01 September 2014

Carbide-derived carbon Monoliths (CDC-Ms) containing a multimodal arrangement with high volumes of micro- meso- and macropores are prepared by direct nanocasting of silica monoliths with polycarbosilane precursors. CDC-Ms show well-defined pore structures along with specific surface areas of more than 2600 m2 g−1 and overall pore volumes as high as 3.14 cm3 g−1. They exhibit advanced gas filtration properties compared to purely microporous materials due to enhanced storage capacities and kinetics as demonstrated by thermal response measurements based on InfraSORP technology.

info:eu-repo/classification/ddc/540

ddc:540

info:eu-repo/classification/ddc/530

ddc:530