Formation Process of Graphene Nano Sheets

Herlince Sihotang

, Rikson Siburian

1,2*

, Crystina Simanjuntak

, Saur Lumban Raja

, Minto Supeno

Vivi Sukmawati

and Zul Alfian

Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Sumatera Utara,

Jl. Bioteknologi No. 1, Medan 20155, Indonesia

Nano Medicine Center, Universitas Sumatera Utara, Medan, Indonesia

Postgraduate Chemistry Study Program, Faculty of Mathematics and Natural Sciences, Universitas Sumatera Utara,

Jl. Bioteknologi No. 1 Kampus USU, Medan, Indonesia

vsukmawati81@gmail.com, zulalfian16@yahoo.com

Keywords: Graphene Nano Sheets, Magnesium, Epoxide, FTIR, Hummer Method.

Abstract: Formation process of Graphene Nano Sheets (GNS) was described in this paper. The aims of this paper are

to synthesize of GNS and to propose formation process of GNS base on magnesium (Mg) as a reductor

agent. This research is an experiment laboratory research. The modification of Hummer’s method was

chosen to generate GNS. Then, GNS was characterized with FTIR. The results data show that Mg may be

used to reduce epoxide functional groups.

1 INTRODUCTION

Graphene may be applied to many applications

(Geim, 2007; Xu, 2015; Novoselov, 2004; Terrones,

2010; Soldano, 2010). Unfortunately, it cannot be

produced naturally. It is possible to synthesize base

on graphite as a raw material (Choi, 2011; Bhuyan,

2016; Lee, 2016). Generally, GNS may be

synthesized by using CVD (Wang, 2009; Juang,

2010; Bárcenas, 2018; Jacobberger, 2015) and

chemical method (Siburian, 2012, 2013, 2014, 2017;

Ratih, 2018; Supeno, 2018; Sebayang, 2018). GNS

may be generated with facile method. Commonly,

chemical method in term of producing graphene uses

graphite as a raw material (Bhuyan, 2016; Eigler,

2013; Saleem, 2018; Dimiev, 2014). Chemically

method may be expected to large scale graphene

production (Kairi, 2018; Li, 2014; Zhong, 2015;

Parvez, 2015; Park, 2009), and exfoliated graphite

(Gao, 2017). The commercialization of graphene

and its derivatives product will be visible if it may

produce on low cost, best quality, large scale and

green material (Tatarova, 2017; Zhong, 2015).

Therefore, in this paper the formation of GNS base

on chemically method was studied, thereby large

scale production of GNS may be done in future.

2 MATERIALS AND METHODS

2.1 Synthesis of GNS

In this research, GNS was produced with Hummer’s

modified method (Siburian, 2012). Briefly, 1 gram

graphite was mixed with 75 mL H

96% and 1

gram NaNO

, stirred for 4 hours. Then, 5 gram

KMnO

gradually was added into solution, stirred 4

hours, T = 20

C at ice water bath condition. At the

end of 4 hours, the solution was move from ice

water bath and it was continue stirred for 48 hours at

room temperature to form dark brown solution.

Subsequently, 5 mL H

30% and 100 mL H

5% was put into solution, respectively, stirred 2

hours to form graphite oxide. After that, graphite

oxide solution was centrifuged at 6500 rotor per

minute (rpm) for 20 minutes to separate between

residue and supernatant. Then, residue was added 10

mL piranha solution and aquades, centrifuged at

6500 rpm for 20 minutes, respectively to form

graphite oxide solution.

100 mL graphite oxide solution was

ultrasonicated on 5060 Hz for 5 hours to form

graphene oxide. Finally, 10 mL graphene oxide

solution was added 0.01 mg magnesium (Mg)

powder, stirred for 72 hours, filtrated and heated at T

= 80 ºC for 24 hours to produce GNS. Graphite,

Sihotang, H., Siburian, R., Simanjuntak, C., Raja, S., Supeno, M., Sukmawati, V. and Alﬁan, Z.

Formation Process of Graphene Nano Sheets.

DOI: 10.5220/0008839400360038

In Proceedings of the 1st International Conference on Chemical Science and Technology Innovation (ICOCSTI 2019), pages 36-38

ISBN: 978-989-758-415-2

graphite oxide, graphene oxide and GNS were

characterized by using FTIR, respectively.

3 RESULTS AND DISCUSSION

First of all, graphite as a raw material was

characterized with FTIR (Figure 1).

Figure 1: FTIR spectrum of graphite.

Figure 1 show that there is a weak and broad peak at

1581 cm

-1

, indicating graphite consists of double

bond aromatic carbon. In contrast, FTIR spectra of

graphite oxide is totally different compare to

graphite (Figure 2).

Figure 2: FTIR spectrum of graphite oxide.

FTIR data indicates that graphite oxide has hydroxyl

functional group (-OH) (wave number (υ) = 3,410 cm

), CH

(2,924 cm

-1

), CH

(2,854 cm

-1

), C=O

(1,705

-1

), and C-O

(1,118 cm

-1

). Meanwhile, FTIR data of

graphite oxide may be seen in Figure 3.

Figure 3: FTIR spectrum of graphene oxide.

The formation of graphene oxide may be indicated

with υ = 3,410 cm

-1

(-OH), 1,620 cm

-1

(C=O), and

1,273 cm

-1

(C-O). Finally, graphene oxide was

reduced by using Mg to form GNS (Figure 4). In the

presence of Mg, the epoxide functional group may

be replaced by Mg.

Figure 4: FTIR spectrum of graphene.

4 CONCLUSIONS

The formation of graphene occurs when functional

group of graphene oxide was reduced by Mg. Mg

may only reduced epoxy functional group.

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ICOCSTI 2019 - International Conference on Chemical Science and Technology Innovation