Abstract
Advanced membrane materials are playing increasingly important roles in solving global energy intensive separation problems. Herein, we introduce a high-performance intrinsically microporous Tröger's base-derived ladder polymer (DFTTB) as an advanced membrane material for low-temperature gas separation applications. DFTTB was obtained by design of a 2,3-difluoro-functionalized triptycene (DFTrip) building block. The resulting ladder polymer exhibited high microporosity (
S
BET
= 918 m
2
g
−1
), good thermal and mechanical properties, and excellent gas separation performance at or above the latest 2015 permeability/selectivity trade-off curves for H
2
/N
2
, H
2
/CH
4
and O
2
/N
2
with H
2
and O
2
permeabilities of 5468 and 650 barrer coupled with H
2
/N
2
, H
2
/CH
4
and O
2
/N
2
selectivities of 50, 38 and 6.0, respectively. Furthermore, DFTTB displayed unprecedented performance at sub-ambient temperatures with an O
2
/N
2
selectivity of 10.1 and O
2
permeability of 137 barrer at −30 °C. This high selectivity coupled with up to ∼100-fold higher O
2
and H
2
permeability than commercial glassy polymer membrane materials, provides new opportunities for low temperature air separation and hydrogen recovery from petrochemical process streams.