Na+-gated water-conducting nanochannels for boosting CO2 conversion to liquid fuels

Huazheng Li; Chenglong Qiu; Shoujie Ren; Qiaobei Dong; Shenxiang Zhang; Fanglei Zhou; Xinhua Liang; Jianguo Wang; Shiguang Li; Miao Yu

doi:10.1126/science.aaz6053

Na⁺-gated water-conducting nanochannels for boosting CO₂ conversion to liquid fuels

Huazheng Li
, Chenglong Qiu
, Shoujie Ren
, Qiaobei Dong
, Shenxiang Zhang
, Fanglei Zhou
, Xinhua Liang
, Jianguo Wang
, Shiguang Li
, Miao Yu

Department of Energy, Environmental & Chemical Engineering

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

219 Scopus citations

Abstract

Robust, gas-impeding water-conduction nanochannels that can sieve water from small gas molecules such as hydrogen (H₂), particularly at high temperature and pressure, are desirable for boosting many important reactions severely restricted by water (the major by-product) both thermodynamically and kinetically. Identifying and constructing such nanochannels into large-area separation membranes without introducing extra defects is challenging. We found that sodium ion (Na⁺)–gated water-conduction nanochannels could be created by assembling NaA zeolite crystals into a continuous, defect-free separation membrane through a rationally designed method. Highly efficient in situ water removal through water-conduction nanochannels led to a substantial increase in carbon dioxide (CO₂) conversion and methanol yield in CO₂ hydrogenation for methanol production.

Original language	English
Pages (from-to)	667-671
Number of pages	5
Journal	Science
Volume	367
Issue number	6478
DOIs	https://doi.org/10.1126/science.aaz6053
State	Published - Feb 7 2020

Access to Document

10.1126/science.aaz6053

Cite this

@article{6e4a327dd51a4490bbbc7d77a2f1761f,

title = "Na+-gated water-conducting nanochannels for boosting CO2 conversion to liquid fuels",

abstract = "Robust, gas-impeding water-conduction nanochannels that can sieve water from small gas molecules such as hydrogen (H2), particularly at high temperature and pressure, are desirable for boosting many important reactions severely restricted by water (the major by-product) both thermodynamically and kinetically. Identifying and constructing such nanochannels into large-area separation membranes without introducing extra defects is challenging. We found that sodium ion (Na+)–gated water-conduction nanochannels could be created by assembling NaA zeolite crystals into a continuous, defect-free separation membrane through a rationally designed method. Highly efficient in situ water removal through water-conduction nanochannels led to a substantial increase in carbon dioxide (CO2) conversion and methanol yield in CO2 hydrogenation for methanol production.",

author = "Huazheng Li and Chenglong Qiu and Shoujie Ren and Qiaobei Dong and Shenxiang Zhang and Fanglei Zhou and Xinhua Liang and Jianguo Wang and Shiguang Li and Miao Yu",

note = "Publisher Copyright: Copyright {\textcopyright} 2020 The Authors.",

year = "2020",

month = feb,

day = "7",

doi = "10.1126/science.aaz6053",

language = "English",

volume = "367",

pages = "667--671",

journal = "Science",

issn = "0036-8075",

number = "6478",

}

TY - JOUR

T1 - Na+-gated water-conducting nanochannels for boosting CO2 conversion to liquid fuels

AU - Li, Huazheng

AU - Qiu, Chenglong

AU - Ren, Shoujie

AU - Dong, Qiaobei

AU - Zhang, Shenxiang

AU - Zhou, Fanglei

AU - Liang, Xinhua

AU - Wang, Jianguo

AU - Li, Shiguang

AU - Yu, Miao

PY - 2020/2/7

Y1 - 2020/2/7

N2 - Robust, gas-impeding water-conduction nanochannels that can sieve water from small gas molecules such as hydrogen (H2), particularly at high temperature and pressure, are desirable for boosting many important reactions severely restricted by water (the major by-product) both thermodynamically and kinetically. Identifying and constructing such nanochannels into large-area separation membranes without introducing extra defects is challenging. We found that sodium ion (Na+)–gated water-conduction nanochannels could be created by assembling NaA zeolite crystals into a continuous, defect-free separation membrane through a rationally designed method. Highly efficient in situ water removal through water-conduction nanochannels led to a substantial increase in carbon dioxide (CO2) conversion and methanol yield in CO2 hydrogenation for methanol production.

AB - Robust, gas-impeding water-conduction nanochannels that can sieve water from small gas molecules such as hydrogen (H2), particularly at high temperature and pressure, are desirable for boosting many important reactions severely restricted by water (the major by-product) both thermodynamically and kinetically. Identifying and constructing such nanochannels into large-area separation membranes without introducing extra defects is challenging. We found that sodium ion (Na+)–gated water-conduction nanochannels could be created by assembling NaA zeolite crystals into a continuous, defect-free separation membrane through a rationally designed method. Highly efficient in situ water removal through water-conduction nanochannels led to a substantial increase in carbon dioxide (CO2) conversion and methanol yield in CO2 hydrogenation for methanol production.

UR - https://www.scopus.com/pages/publications/85079081816

U2 - 10.1126/science.aaz6053

DO - 10.1126/science.aaz6053

M3 - Article

C2 - 32029624

AN - SCOPUS:85079081816

SN - 0036-8075

VL - 367

SP - 667

EP - 671

JO - Science

JF - Science

IS - 6478

ER -

Na⁺-gated water-conducting nanochannels for boosting CO₂ conversion to liquid fuels

Abstract

Access to Document

Other files and links

Fingerprint

Cite this