Oriented Arrangement: The Origin of Versatility for Porous Graphene Materials
Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials wit...
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| Published in: | Small (Weinheim an der Bergstrasse, Germany) Vol. 13; no. 34 |
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| Abstract | Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte‐assisted self‐assembly and shear‐force‐induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa−1 for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of ≈18.7 L m−2 h−1 bar−1 and a dynamic removal rate of 510 mg m−2 h−1.
Macroscopic graphene foam with oriented arrangement of graphene sheets and pore structure is prepared by the electrolyte‐assisted and shear‐arranged method. Such a unique architecture endows this novel graphene material with anisotropic mechanical, electrical and thermal properties and superior elasticity, which make it suitable for versatile applications, such as a high‐sensitivity pressure sensor and organic pollutant removal membrane with high flux. |
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| AbstractList | Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte-assisted self-assembly and shear-force-induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa-1 for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of [asymp]18.7 L m-2 h-1 bar-1 and a dynamic removal rate of 510 mg m-2 h-1. Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte-assisted self-assembly and shear-force-induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of ≈18.7 L m h bar and a dynamic removal rate of 510 mg m h . Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte‐assisted self‐assembly and shear‐force‐induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa −1 for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of ≈18.7 L m −2 h −1 bar −1 and a dynamic removal rate of 510 mg m −2 h −1 . Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte‐assisted self‐assembly and shear‐force‐induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa−1 for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of ≈18.7 L m−2 h−1 bar−1 and a dynamic removal rate of 510 mg m−2 h−1. Macroscopic graphene foam with oriented arrangement of graphene sheets and pore structure is prepared by the electrolyte‐assisted and shear‐arranged method. Such a unique architecture endows this novel graphene material with anisotropic mechanical, electrical and thermal properties and superior elasticity, which make it suitable for versatile applications, such as a high‐sensitivity pressure sensor and organic pollutant removal membrane with high flux. Macroscopic porous graphene materials composed of graphene sheets have demonstrated their advantageous aspects in diverse application areas. It is essential to maximize their excellent performances by rationally controlling the sheet arrangement and pore structure. Bulk porous graphene materials with oriented pore structure and arrangement of graphene sheets are prepared by marrying electrolyte-assisted self-assembly and shear-force-induced alignment of graphene oxide sheets, and the super elasticity and anisotropic mechanical, electrical, and thermal properties induced by this unique structure are systematically investigated. Its application in pressure sensing exhibits ultrahigh sensitivity of 313.23 kPa-1 for detecting ultralow pressure variation below 0.5 kPa, and it shows high retention rate for continuously intercepting dye molecules with a high flux of ≈18.7 L m-2 h-1 bar-1 and a dynamic removal rate of 510 mg m-2 h-1 . |
| Author | Liu, Zhaoping Zhou, Xufeng Huang, Heran Deng, Wei Fang, Qile Ma, Jingbo |
| Author_xml | – sequence: 1 givenname: Wei surname: Deng fullname: Deng, Wei organization: University of Chinese Academy of Sciences (UCAS) – sequence: 2 givenname: Qile surname: Fang fullname: Fang, Qile organization: Chinese Academy of Sciences (CAS) – sequence: 3 givenname: Heran surname: Huang fullname: Huang, Heran organization: Chinese Academy of Sciences (CAS) – sequence: 4 givenname: Xufeng surname: Zhou fullname: Zhou, Xufeng email: zhouxf@nimte.ac.cn organization: Chinese Academy of Sciences (CAS) – sequence: 5 givenname: Jingbo surname: Ma fullname: Ma, Jingbo organization: Ningbo University – sequence: 6 givenname: Zhaoping surname: Liu fullname: Liu, Zhaoping email: liuzp@nimte.ac.cn organization: Chinese Academy of Sciences (CAS) |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/28692763$$D View this record in MEDLINE/PubMed |
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| Keywords | pollutant removal porous structure oriented arrangement graphene pressure sensors |
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| Title | Oriented Arrangement: The Origin of Versatility for Porous Graphene Materials |
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