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Journal of Materials Science

Erschienen in:

02.06.2021 | Composites & nanocomposites

High-strength reduced graphene oxide paper prepared by a simple and efficient method

verfasst von: Wen Li, Chengjie Weng, Wenzhong Yang, Liming Shen, Ningzhong Bao

Erschienen in: Journal of Materials Science | Ausgabe 25/2021

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Abstract

Excellent mechanical and electrical properties of graphene-based paper-like materials are essential for applications in flexible conductors, energy-storage devices, etc. The graphene oxide (GO) supernatant separated by centrifugation and ultrasonication has been used to prepare graphene oxide paper and reduced graphene oxide paper (rGOP) with high strength and conductivity. However, this method has cumbersome steps and low supernatant concentration, which greatly increases time and energy consumption, and is not suitable for rapid batch preparation of high-strength and high-thickness rGOP. Herein, a high-speed mechanical shearing method has been used to efficiently exfoliate graphite oxide suspension into high-concentration GO slurry with large lateral size, and rGOP has been further prepared by blade coating and HI acid chemical reduction. Compared with the product prepared by ultrasonic exfoliation method, the average area of GO sheets obtained via the mechanical shear exfoliation method can reach around 16.31 μm². As a result, the mechanical properties and conductivity of the prepared rGOP have been increased by 30% and 23.5%, respectively, with the tensile strength and electrical conductivity of 478.2 MPa and 208.4 S/cm being obtained. The developed method is of great significance for the large-scale production and emerging applications of lightweight and high-performance rGOP.

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Vorheriger Artikel Architected poly(lactic acid)/poly(ε-caprolactone)/halloysite nanotube composite scaffolds enabled by 3D printing for biomedical applications

Nächster Artikel Use of a Ni-TiO2 nanocomposite film to enhance agricultural cutting knife surfaces by electrodeposition technology

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Xin GQ, Yao TK, Sun HT, Scott SM, Shao DL, Wang GK, Lian J (2015) Highly thermally conductive and mechanically strong graphene fibers. Science 349:1083–1087CrossRef

Zhu YW, Murali S, Cai WW, Li XS, Suk JW, Potts JR, Ruoff RS (2010) Graphene and graphene oxide: synthesis, properties, and applications. Adv Mater 22:3906–3924CrossRef

Dikin DA, Stankovich S, Zimney EJ, Piner RD, Dommett GHB, Evmenenko G, Nguyen ST, Ruoff RS (2007) Preparation and characterization of graphene oxide paper. Nature 448:457–460CrossRef

Chen HQ, Müller MB, Gilmore KJ, Wallace GG, Li D (2008) Mechanically strong, electrically conductive, and biocompatible graphene paper. Adv Mater 20:3557–3561CrossRef

Nair RR, Wu HA, Jayaram PN, Grigorieva IV, Geim AK (2012) Unimpeded permeation of water through helium-leak-tight graphene-based membranes. Science 335:442–444CrossRef

Cheng QF, Jiang L, Tang ZY (2014) Bioinspired layered materials with superior mechanical performance. Acc Chem Res 47:1256–1266CrossRef

Madurani KA, Suprapto S, Machrita NI, Bahar SL, Illiya W, Kurniawan F (2020) Progress in graphene synthesis and its application: history, challenge and the future outlook for research and industry. ECS J Solid State Sci Technol 9:093013CrossRef

Wu MM, Chen J, Wen YY, Chen HW, Li YR, Li Ch, Shi GQ (2018) Chemical approach to ultrastiff, strong, and environmentally stable graphene films. ACS Appl Mater Interfaces 10:5812–5818CrossRef

Cao CH, Daly M, Chen B, Howe JY, Singh CV, Filleter T, Sun Y (2015) Strengthening in graphene oxide nanosheets: bridging the gap between interplanar and intraplanar fracture. Nano Lett 15:6528–6534CrossRef

10.

Gao Y, Liu LQ, Zu SZ, Peng K, Zhou D, Han BH, Zhang Zh (2011) The effect of interlayer adhesion on the mechanical behaviors of macroscopic graphene oxide papers. ACS Nano 5:2134–2141CrossRef

11.

Cheng QF, Wu MX, Li MZh, Jiang L, Tang ZhY (2013) Ultratough artificial nacre based on conjugated cross-linked graphene oxide. Angew Chem Int Ed 52:3750–3755CrossRef

12.

Hu K, Tsukruk VV (2015) Tuning the electronic properties of robust bio-bond graphene papers by spontaneous electrochemical reduction: from insulators to flexible semi-metals. Chem Mater 27:6717–6729CrossRef

13.

Cui W, Li MZh, Liu JY, Wang B, Zhang C, Jiang L, Cheng QF (2014) A strong integrated strength and toughness artificial nacre based on dopamine cross-linked graphene oxide. ACS Nano 8:9511–9517CrossRef

14.

Zhang M, Wang YL, Huang L, Xu ZP, Li C, Shi GQ (2015) Multifunctional pristine chemically modified graphene films as strong as stainless steel. Adv Mater 27:6708–6713CrossRef

15.

Zhong J, Sun W, Wei QW, Qian XT, Cheng HM, Ren WC (2018) Efficient and scalable synthesis of highly aligned and compact two-dimensional nanosheet films with record performances. Nat Commun 9:3484CrossRef

16.

Lin XY, Shen X, Zheng QB, Yousefi N, Ye L, Mai YM, Kim JK (2012) Fabrication of highly-aligned, conductive, and strong graphene papers using ultralarge graphene oxide sheets. ACS Nano 6:10708–10719CrossRef

17.

Brisebois PP, Siaj M (2020) Harvesting graphene oxide-years 1859 to 2019: a review of its structure, synthesis, properties and exfoliation. J Mater Chem C 8:1517–1547CrossRef

18.

Li C, Lin J, Shen LM, Bao NZh (2020) Quantitative analysis and kinetic modeling of ultrasound-assisted exfoliation and breakage process of graphite oxide. Chem Eng Sci 213:115414CrossRef

19.

Shao GL, Lu Y, Wu FF, Yang ChL, Zeng FL, Wu QL (2012) Graphene oxide: the mechanisms of oxidation and exfoliation. J Mater Sci 47:4400–4409. https://doi.org/10.1007/s10853-012-6294-5CrossRef

20.

Ogino I, Yokoyama Y, Iwamura S, Mukai SR (2014) Exfoliation of graphite oxide in water without sonication: bridging length scales from nanosheets to macroscopic materials. Chem Mater 26:3334–3339CrossRef

21.

Kim HN, Suslick KS (2017) Sonofragmentation of ionic crystals. Chem A Eur J 23:2778–2782CrossRef

22.

Xia ZhY, Pezzini S, Treossi E, Giambastiani G, Corticelli F, Morandi V, Zanelli A, Bellani V, Palermo V (2013) The exfoliation of graphene in liquids by electrochemical, chemical, and sonication-assisted techniques: a nanoscale study. Adv Funct Mater 23:4684–4693CrossRef

23.

Pan S, Aksay IA (2011) Factors controlling the size of graphene oxide sheets produced via the graphite oxide route. ACS Nano 5:4073–4083CrossRef

24.

Liscio A, Kouroupis-Agalou K, Betriu XD, Kovtun A, Treossi E, Pugno NM, Luca GD, Giorgini L, Palermo V (2017) Evolution of the size and shape of 2D nanosheets during ultrasonic fragmentation. 2D Mater 4:025017CrossRef

25.

Park WK, Yoon Y, Song YH, Choi SY, Kim S, Do Y, Lee J, Park H, Yoon DH, Yang WS (2017) High-efficiency exfoliation of large-area mono-layer graphene oxide with controlled dimension. Sci Rep 7:16414CrossRef

26.

Jeong SY, Kim SH, Han JT, Jeong HJ, Yang S, Lee GW (2011) High-performance transparent conductive films using rheologically derived reduced graphene oxide. ACS Nano 5:870–878CrossRef

27.

Chen J, Li Y, Huang LR, Huang L, Jia N, Li Ch, Shi GQ (2015) Size fractionation of graphene oxide sheets via filtration through track-etched membranes. Adv Mater 27:3654–3660CrossRef

28.

Zhao JP, Pei SF, Ren WC, Gao LB, Cheng HM (2010) Efficient preparation of large-area graphene oxide sheets for transparent conductive films. ACS Nano 4:5245–5252CrossRef

29.

Qi XD, Zhou TN, Deng Sh, Zong GY, Yao XL, Fu Q (2014) Size-specified graphene oxide sheets: ultrasonication assisted preparation and characterization. J Mater Sci 49:1785–1793. https://doi.org/10.1007/s10853-013-7866-CrossRef

30.

Casabianca LB, Shaibat MA, Cai WW, Park S, Piner R, Ruoff RS, Ishii Y (2010) NMR-based structural modeling of graphite oxide using multidimensional 13C solid-state NMR and ab initio chemical shift calculations. J Am Chem Soc 132:5672–5676CrossRef

31.

Fathy M, Gomaa A, Taher FA, EI-Fass MM, Kashyout AEHB (2016) Optimizing the preparation parameters of GO and rGO for large-scale production. J Mater Sci 51:5664–5675. https://doi.org/10.1007/s10853-016-9869-8CrossRef

32.

Lerf A, He H, Forster M, Klinowski J (1998) Structure of graphite oxide revisited. J Phys Chem B 102:4477–4482CrossRef

33.

Akbari A, Sheath P, Martin ST, Shinde DB, Shaibani M, Banerjee PC, Tkacz R, Bhattacharyya D, Majumder M (2016) Large-area graphene-based nanofiltration membranes by shear alignment of discotic nematic liquid crystals of graphene oxide. Nat Commun 7:10891CrossRef

34.

Yang Q, Su Y, Chi C, Cherian CT, Huang K, Kravets VG, Wang FC, Zhang JC, Pratt A, Grigorenko AN, Guinea F, Geim AK, Nair RR (2017) Ultrathin graphene-based membrane with precise molecular sieving and ultrafast solvent permeation. Nat Mater 16:1198–1202CrossRef

35.

Abraham J, Vasu KS, Williams CD, Gopinadhan K, Yang Su, Cherian CT, Dix J, Prestat E, Haigh SJ, Grigorieva IV, Carbone P, Geim AK, Nair RR (2017) Tunable sieving of ions using graphene oxide membranes. Nat Nanotechnol 12:546–550CrossRef

36.

Kumar P, Maiti UN, Lee KE, Kim SO (2014) Rheological properties of graphene oxide liquid crystal. Carbon 80:453–461CrossRef

37.

Narayan R, Kim JE, Kim JY, Lee KE, Kim SO (2016) Graphene oxide liquid crystals: discovery, evolution and applications. Adv Mater 28:3045–3068CrossRef

38.

Espinosa HD, Juster AL, Latourte FJ, Loh OY, Gregoire D, Zavattieri PD (2011) Tablet-level origin of toughening in abalone shells and translation to synthetic composite materials. Nat Commun 2:173CrossRef

39.

Pei SF, Zhao JP, Du JH, Ren WC, Cheng HM (2010) Direct reduction of graphene oxide films into highly conductive and flexible graphene films by hydrohalic acids. Carbon 48:4466–4474CrossRef

40.

Moon IK, Lee J, Ruoff RS, Lee H (2010) Reduced graphene oxide by chemical graphitization. Nat Commun 1:73CrossRef

41.

Yang G, Yi HK, Yao YG, Li ChW, Li Zh (2020) Thermally conductive graphene films for heat dissipation. ACS Appl Nano Mater 3:2149–2155CrossRef

Titel: High-strength reduced graphene oxide paper prepared by a simple and efficient method
verfasst von: Wen Li
Chengjie Weng
Wenzhong Yang
Liming Shen
Ningzhong Bao
Publikationsdatum: 02.06.2021
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 25/2021
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-021-06151-2

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Abstract

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