Ultrafast Nanofiltration through Large-Area Single-Layered Graphene Membranes

Yanzhe Qin; Yongyou Hu; Stephan Koehler; Liheng Cai; Junjie Wen; Xiaojun Tan; Weiwei L. Xu; Qian Sheng; Xu Hou; Jianming Xue; Miao Yu; David Weitz

doi:10.1021/acsami.7b00504

Ultrafast Nanofiltration through Large-Area Single-Layered Graphene Membranes

Yanzhe Qin
, Yongyou Hu
, Stephan Koehler
, Liheng Cai
, Junjie Wen
, Xiaojun Tan
, Weiwei L. Xu
, Qian Sheng
, Xu Hou
, Jianming Xue
, Miao Yu
, David Weitz

Department of Chemical and Biological Engineering

South China University of Technology
Harvard University
University of South Carolina
Peking University
Xiamen University

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

65 Scopus citations

Abstract

Perforated single-layered graphene has demonstrated selectivity and flux that is orders of magnitude greater than state-of-the-art polymer membranes. However, only individual graphene sheets with sizes up to tens of micrometers have been successfully fabricated for pressurized permeation studies. Scaling-up and reinforcement of these atomic membranes with minimum cracks and pinholes remains a major hurdle for practical applications. We develop a large-area in situ, phase-inversion casting technique to create 63 cm² high-quality single-layered perforated graphene membranes for ultrafast nanofiltration that can operate at pressures up to 50 bar. This result demonstrates the feasibility of our technique for creating robust large-area, high quality, single-layered graphene and its potential use as a pressurized nanofiltration membrane.

Original language	English
Pages (from-to)	9239-9244
Number of pages	6
Journal	ACS Applied Materials and Interfaces
Volume	9
Issue number	11
DOIs	https://doi.org/10.1021/acsami.7b00504
State	Published - Mar 22 2017

Keywords

graphene nanofiltration
graphene transfer
high-quality graphene
large area graphene
molecular sieving
nanoporous graphene
phase inversion

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10.1021/acsami.7b00504

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title = "Ultrafast Nanofiltration through Large-Area Single-Layered Graphene Membranes",

abstract = "Perforated single-layered graphene has demonstrated selectivity and flux that is orders of magnitude greater than state-of-the-art polymer membranes. However, only individual graphene sheets with sizes up to tens of micrometers have been successfully fabricated for pressurized permeation studies. Scaling-up and reinforcement of these atomic membranes with minimum cracks and pinholes remains a major hurdle for practical applications. We develop a large-area in situ, phase-inversion casting technique to create 63 cm2 high-quality single-layered perforated graphene membranes for ultrafast nanofiltration that can operate at pressures up to 50 bar. This result demonstrates the feasibility of our technique for creating robust large-area, high quality, single-layered graphene and its potential use as a pressurized nanofiltration membrane.",

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AU - Qin, Yanzhe

AU - Hu, Yongyou

AU - Koehler, Stephan

AU - Cai, Liheng

AU - Wen, Junjie

AU - Tan, Xiaojun

AU - Xu, Weiwei L.

AU - Sheng, Qian

AU - Hou, Xu

AU - Xue, Jianming

AU - Yu, Miao

AU - Weitz, David

PY - 2017/3/22

Y1 - 2017/3/22

N2 - Perforated single-layered graphene has demonstrated selectivity and flux that is orders of magnitude greater than state-of-the-art polymer membranes. However, only individual graphene sheets with sizes up to tens of micrometers have been successfully fabricated for pressurized permeation studies. Scaling-up and reinforcement of these atomic membranes with minimum cracks and pinholes remains a major hurdle for practical applications. We develop a large-area in situ, phase-inversion casting technique to create 63 cm2 high-quality single-layered perforated graphene membranes for ultrafast nanofiltration that can operate at pressures up to 50 bar. This result demonstrates the feasibility of our technique for creating robust large-area, high quality, single-layered graphene and its potential use as a pressurized nanofiltration membrane.

AB - Perforated single-layered graphene has demonstrated selectivity and flux that is orders of magnitude greater than state-of-the-art polymer membranes. However, only individual graphene sheets with sizes up to tens of micrometers have been successfully fabricated for pressurized permeation studies. Scaling-up and reinforcement of these atomic membranes with minimum cracks and pinholes remains a major hurdle for practical applications. We develop a large-area in situ, phase-inversion casting technique to create 63 cm2 high-quality single-layered perforated graphene membranes for ultrafast nanofiltration that can operate at pressures up to 50 bar. This result demonstrates the feasibility of our technique for creating robust large-area, high quality, single-layered graphene and its potential use as a pressurized nanofiltration membrane.

KW - graphene nanofiltration

KW - graphene transfer

KW - high-quality graphene

KW - large area graphene

KW - molecular sieving

KW - nanoporous graphene

KW - phase inversion

UR - https://www.scopus.com/pages/publications/85015940484

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DO - 10.1021/acsami.7b00504

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JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 11

ER -

Ultrafast Nanofiltration through Large-Area Single-Layered Graphene Membranes

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Keywords

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