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purity of 94.6 wt % (Fig. 3D, lower right inset,
and fig. S24).
We compared our catalytic reaction results
with those previously reported (Fig. 4 and
table S7) in terms of CO 2 conversion and STY
of methanol. With only CZA catalysts, the TR
showed only moderate CO 2 conversion (23.0%)
and methanol STY (339 mg gcat–^1 hour–^1 ). After
the incorporation of the WCM, both CO 2 con-
version and methanol STY were greatly boosted
(61.4% and 809 mg gcat–^1 hour–^1 , respectively).
Our results obtained in the MR represent the
highest values reported to date under similar
reaction conditions and are even higher than
those obtained at much higher temperatures
and pressures. It may be possible to use WCMs
for other reactions that are kinetically or ther-
modynamically restricted by water—such as
CO 2 hydrogenation to dimethyl ether ( 21 )and
Fischer-Tropsch synthesis ( 22 )—by loading cor-
responding catalysts onto the outer surface of
the WCM.

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ACKNOWLEDGMENTS

Funding:Supported by Advanced Research Projects Agency–

Energy (ARPA-E), U.S. Department of Energy, award DE-

AR0000806; Rensselaer Polytechnic Institute (RPI) startup funds;

and National Natural Science Foundation of China grant NSFC-

21625604 (J.W.).Author contributions:M.Y. and H.L. conceived

the project; H.L. prepared and evaluated the membranes and

membrane reactors; S.R. and X.L. supplied and characterized the

catalysts; Q.D. conducted the BET test; S.Z. and S.L. drew and

discussed some figures; F.Z. performed the XRD; C.Q. and J.W.

performed the DFT calculation; M.Y. directed all aspects of the

project; and M.Y. and H.L. wrote the manuscript.Competing

interests:A U.S. provisional patent (application number 62/

795,082), with M.Y. and H.L. as co-inventors, has been filed by RPI.

Data and materials availability:All data are available in the main

text or the supplementary materials.

SUPPLEMENTARY MATERIALS

science.sciencemag.org/content/367/6478/667/suppl/DC1

Materials and Methods

Figs. S1 to S24

Tables S1 to S7

Movie S1

References ( 60 – 75 )

2 October 2019; accepted 10 December 2019

10.1126/science.aaz6053

Liet al.,Science 367 , 667–671 (2020) 7 February 2020 5of5

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