DSpace at VNU: Photochemical decoration of silver nanoparticles on graphene oxide nanosheets and their optical characterization

1 Yecxanh Street, Hai Ba Trung District, Hanoi, Viet Nam g International Training Institute for Materials Science ITIMS, Hanoi University of Science and Technology HUST, 01 Dai Co Viet S

Photochemical decoration of silver nanoparticles on graphene oxide

nanosheets and their optical characterization

Nguyen Thi Lana, Do Thi Chia, Ngo Xuan Dinha, Nguyen Duy Hunga, Hoang Lana, Pham Anh Tuanb,

Thanh-Tung Duongh, Vu Ngoc Phana, Anh-Tuan Lea,⇑

a

Department of Nanoscience and Nanotechnology, Advanced Institute for Science and Technology (AIST), Hanoi University of Science and Technology (HUST), No 1 Dai Co Viet Street, Hai Ba Trung District, Hanoi, Viet Nam

b

Vietnam Metrology Institute, 08 Hoang Quoc Viet Road, Cau Giay District, Hanoi, Viet Nam

c

School of Materials Science and Engineering, Hanoi University of Science and Technology (HUST), 01 Dai Co Viet Street, Hai Ba Trung District, Hanoi, Viet Nam

d School of Engineering Physics, Hanoi University of Science and Technology (HUST), 01 Dai Co Viet Street, Hai Ba Trung District, Hanoi, Viet Nam

e

Department of Physics, Hanoi University of Science, 334 Nguyen Trai, Thanh Xuan, Hanoi, Viet Nam

f

Laboratory for Ultrastructure and Bionanotechnology (LUBN), National Institute of Hygiene and Epidemiology (NIHE), No 1 Yecxanh Street, Hai Ba Trung District, Hanoi, Viet Nam

g

International Training Institute for Materials Science (ITIMS), Hanoi University of Science and Technology (HUST), 01 Dai Co Viet Street, Hai Ba Trung District, Hanoi, Viet Nam

h

Department of Materials Engineering, Chungnam National University, Daeduk Science Town, 305-764 Daejeon, Republic of Korea

a r t i c l e i n f o

Article history:

Received 24 April 2014

Received in revised form 13 June 2014

Accepted 5 July 2014

Available online 11 July 2014

Keywords:

Ag-GO nanohybrid

Green synthesis

Optical properties

a b s t r a c t

Nanohybrid materials based on silver nanoparticles (Ag-NPs) and graphene oxide (GO) are attracting con-siderable research interest because of their potential many applications including surface-enhanced Raman scattering, catalysis, sensors, biomedicine and antimicrobials In this study, we established a sim-ple and effective method of preparing a finely dispersed Ag-GO aqueous solution using modified Hummer and photochemical technique The Ag-NPs formation on GO nanosheets was analyzed by X-ray diffrac-tion, transmission electron microscopy, Raman spectroscopy, and Fourier-transform infrared spectros-copy The average size of Ag-NPs on the GO nanosheets was approximately 6–7 nm with nearly uniform size distribution The Ag-GO nanohybrid also exhibits an adsorption band at 435 nm because

of the presence of Ag-NPs on the GO nanosheets Photoluminescence emission of the Ag-GO nanohybrid was found at 400 and 530 nm, which can be attributed to the interaction between the luminescence of exploited GO nanosheets and localized surface plasmon resonance from metallic Ag-NPs The observed excellent optical properties of the as-prepared Ag-GO nanohybrid showed a significant potential for opto-electronics applications

Ó 2014 Elsevier B.V All rights reserved

1 Introduction

Graphene, which consists of a one-atom-thick sheet of sp2

-bonded carbon atoms in a hexagonal two-dimensional lattice, is

attracting considerable research interests because of its

remark-able physicochemical properties Such properties include a high

specific surface area, mechanical strength, and thermal and

electri-cal conductivities, as well as extraordinary electronic properties

and electron transport capabilities[1] These excellent properties

make graphene a promising nanomaterial for various technological

applications, ranging from biosensor, energy to optoelectronic

devices[1]

A specific class of graphene research deals with graphene oxide (GO), GO sheets are chemically synthesized graphene sheets that are modified with oxygen-containing functional groups Oxygen-ated groups in GO can strongly affect the electronic, mechanical, and electrochemical properties of GO, thereby resulting in differ-ences between GO and pristine graphene In comparison with the pristine graphene, the existence of these oxygen functional groups can also provide advantages such as hydrophilicity and controlla-ble electronic properties for using GO in various technological applications[2–4]

Silver nanoparticles (Ag-NPs) are attractive objects for the sci-entific community in materials science because Ag-NPs posses many advantages such as good conductivity, catalytic and wide-spectrum antimicrobial activity against various micro-organisms and localized surface plasmon resonance (LSPR) effect[5,6]

http://dx.doi.org/10.1016/j.jallcom.2014.07.042

0925-8388/Ó 2014 Elsevier B.V All rights reserved.

⇑ Corresponding author.

E-mail address: tuan.leanh1@hust.edu.vn (A.-T Le).

Contents lists available atScienceDirect

Journal of Alloys and Compounds

j o u r n a l h o m e p a g e : w w w e l s e v i e r c o m / l o c a t e / j a l c o m

To explore the combined advantageous properties of Ag-NPs

and GO sheets, Ag-GO nanohybrids have been intensively studied

[7,8] The Ag-NPs have an important role in many applications such

as surface-enhanced Raman scattering, catalyst, and sensors, as

well as biomedical and antimicrobial applications Insertion of

Ag-NPs into the GO nanosheet is important for further exploration

of Ag-NPs properties and applications For example, Wei et al.[9]

reported that introduction of Ag-NPs into GO sheets indicate that

the antibacterial performance of Ag-GO nanohybrids were

enhanced compared with Ag-NPs and GO materials alone The

Ag-GO nanohybrids also show non-toxic effect on rat skin [9]

Other reports[10–12]showed excellent antimicrobial activity for

Ag-GO nanohybrids

To date, several solution-based routes have been developed to

synthesize the Ag-NPs on the GO nanosheets such as microwave

irradiation, hydrogen reduction in supercritical CO2,

surface-modification method using thiol groups, and citrate-modified

chemical reduction, [7–12] However, some challenges and

problems remain in preparing highly dispersed metallic Ag

nanoparticles of regular size on GO nanosheets and in controlling

stable dispersions of Ag-GO suspension in aqueous solution

because of Ag-GO agglomeration To overcome this problem, we

introduce a simple and effective method for preparation of

Ag-GO nanohybrids via a two-step process, in which aqueous

dispersions of GO nanosheets are produced using a modified

Hummer technique and the Ag-NPs are then decorated on GO

nanosheets by a photochemical technique

In this study, we demonstrate an easy synthesis method for

effective decoration of the Ag-NPs on the GO nanosheet using

mod-ified Hummer and photochemical techniques UV irradiation was

used to improve the uniform dispersions of Ag-NPs on the GO

nanosheets during the reduction process by glucose with oleic acid

as a capping agent The analyzed results suggest that presence of

Ag-NPs on the surface of GO nanosheets and the interaction

between Ag-NPs and functional groups on the edge of the GO

nanosheets were ascribed to the electron transfer from metallic

Ag to the GO nanosheets Two emission peaks in

photolumines-cence of Ag-GO nanohybrids were also observed at 400 and

530 nm, which are attributed to the interaction between

lumines-cence of exploited GO nanosheets and localized surface plasmon

resonance from metallic Ag-NPs Photoluminescence intensity of

Ag-GO nanohybrid increased at peak 400 nm with increasing

concentration of Ag-NPs because of surface plasmon-enhanced

luminescence

2 Experimental procedures

2.1 Chemicals

Analytical-grade silver nitrate (AgNO 3, 99.9%), sodium hydroxide (NaOH),

ammonium hydroxide (NH 3 , 25%), potassium permanganate (KMnO 4 , 99.9%),

hydrogen peroxide (H 2 O 2 , 30%), sulfuric acid (H 2 SO 4 , 98%), hydrochloric acid (HCl,

37%), nitric acid (HNO 3 , 63%), oleic acid, and glucose that were used in this study

were purchased from Shanghai Chemical Reagent Co Ltd Graphite (nature coal

powder) was fabricated from coal in Vietnam.

2.2 Synthesis of graphene oxide (GO) by modified Hummer method

First, GO nanosheets were synthesized from coal powder by modified Hummer

method as described previously [13] Briefly, 1 g of coal powders were mixed with

HNO 3 and KMnO 4 at a volume ratio of 1:2:1.5, respectively, and then the mixture

were converted to exploited graphite (EG) under microwave 800 W for 1 min In

this reaction, the mixture of 2 g of EG, 8 g of KMnO 4 , and 1 g of NaNO 3 was added

slowly to 160 mL of 98% H 2 SO 4 at 5 °C in ice-water bath and then stirred for 30 min.

Ice-water bath was removed, and then temperature was increased slowly to 45 °C

and continuously stirred for 2 h Deionized water was added slowly to the mixture

which was stirred until purple fumes were inhibited By increasing reaction

tem-perature to 95 °C and stirring the mixture for 1 h, the resulting product of the GO

nanosheets was obtained with yellow–brown color The GO nanosheets were then

metal ions that remained in the GO solution The final GO products were purified

by filtering, washing several times by ultrasonic vibration, centrifugation with deionized water, and removal of ultrafine carbon powder that was not oxidized 2.3 Synthesis of Ag-GO nanohybrid by modified photochemical method

The Ag-NPs were then deposited on the GO nanosheets by modified Tollens pro-cess as reported elsewhere [14] Fig 1 shows the schematic of a two-step process to synthesize the Ag-GO nanohybrid In a typical experiment, 1.7 g (10 mmol) of AgNO3 was dissolved in 100 mL of deionized water The AgNO3 solution was then precipitated with 0.62 g (15.5 mmol) of sodium hydroxide (Aldrich, >99%) The obtained precipitate, which is composed of Ag 2 O, was filtered and dissolved in

100 mL of aqueous ammonia (0.4% w/w, 23 mmol) until a transparent solution of silver ammonium complex [Ag(NH 3 ) 2 ] +

(aq) formed Up to 2.5 g (8.9 mmol) of oleic acid was then added dropwise into the complex, and the resulting solution was gently stirred for 2 h at room temperature until the complete homogeneity of the reaction mixture was achieved As to the synthesis of Ag-GO nanohybrid, resulting complex mixture was mixed with GO suspension (3 mg/mL) while stirring for

30 min and followed by the addition of 2 g (11.1 mmol) of glucose The reduction process of the silver complex solution (in quartz glass) was initiated with UV irra-diation A UV lamp (k = 365 nm, 35 W) was used as a light source to stimulate the reduction process After 12 h of UV irradiation, the Ag-NPs were deposited on the

GO nanosheets to form the Ag-GO nanohybrid.

2.4 Characterization techniques Transmission electron microscopy (TEM, JEOL-JEM 1010) was conducted to determine the morphology and distribution of the Ag-NPs on the GO nanosheets The samples for TEM characterization were prepared by placing a drop of colloidal solution on a formvar-coated copper grid that was dried at room temperature The composition of the Ag-GO nanohybrid was characterized by energy-dispersive X-ray (5410 LV JEOL) The crystalline structure of the prepared Ag-NPs and Ag-GO nanohybrid was analyzed by X-ray diffraction (XRD, Bruker D5005) using Cu Ka

radiation (k = 0.154 nm) at a step of 0.02° (2h) at room temperature The back-ground was subtracted using linear interpolation method.

The chemical functional groups of GO and Ag-GO were characterized using FTIR measurements, samples were collected with one layer coating in potassium bro-mide and compressed into pellets, and spectra in the range of 400–4000 cm 1

were recorded with Nicolet 6700 FT-IR instrument Raman measurement was conducted using 633 nm of HeANe laser excitation.

The UV–vis absorbance spectra were recorded using a HP 8453 spectrophotom-eter, and the absorption spectrum of all suspension samples in 10 mm path length quartz cuvettes was 300–900 nm The photoluminescence spectra of GO, Ag, and Ag-GO were measured using Nanolog, Horiba The photoluminescence spectra were obtained with 300 nm excitation.

3 Results and discussion 3.1 Formation of GO nanosheet and Ag-GO nanohybrid

nanohybrids at different magnifications The Ag-NPs are finely dis-persed (Fig 2a), the average size of the Ag-NPs was 5 nm (see inset of Fig 2a) No aggregation of silver particles was also observed, indicating the important role of UV irradiation for con-trolling stably uniform dispersions in Ag-NP synthesis process Fig 2b–d clearly show the presence of a large number of Ag-NPs that are anchored to the GO surfaces The adhered nanoparticles have quasi-spherical morphologies and are dispersed uniformly

on the GO nanosheets In these TEM images, most nanoparticle diameters are 7 nm (see inset ofFig 2a) The wrinkles of the

GO nanosheets (Fig 2c) are also observed, revealing that the GO nanosheets are thin Based on TEM analysis, no aggregation of Ag-NPs is found on the surface of GO nanosheets The small sizes and fine dispersions of Ag-NPs on GO nanosheets enable potential for various technological applications

The formation of the Ag-NPs on GO nanosheets is further con-firmed by XRD analysis Fig 3 shows the XRD patterns for GO nanosheets and GO-Ag nanohybrid samples The GO nanosheets exhibited a broad peak at 10.9° corresponding to the (0 0 2) inter-layer spacing of 0.81 nm, which indicates that the ordinal struc-tures of graphite have been exploited and that oxygen-containing functional groups have been inserted into the interspaces After

decorating the Ag-NPs, three distinct diffraction peaks appear at

2h = 38.2°, 44.4°, and 64.5°, which correspond to the (1 1 1),

(2 0 0), and (2 2 0) crystalline planes of metallic Ag (JCPDS No

04-0783) These observations confirm that the metallic Ag-NPs are

effectively anchored to the surface of GO nanosheets TEM and

XRD analyses revealed that the GO, Ag-NPs, and Ag-decorated GO

nanosheets were formed These obtained results suggest that the

Ag-NPs are successfully decorated on the GO nanosheets using

two-step process In the present study, the mechanism for Ag-GO

formation can be understood as follows: after mixing silver

ammonia complex with GO nanosheets, the positively charged Ag[(NH3)2]+can be easily attached to the negatively charged oxy-gen functional groups on the GO When Ag-GO formation occurs

by adding glucose to the mixture, the aldehyde groups of glucose release electrons to reduce silver ammonia complex into silver nanoparticles The Ag-NPs can be deposited into the GO nano-sheets because of the electrostatic interaction between silver ammonia complex and GO nanosheets UV irradiation is performed during the reduction process to control uniform dispersions of Ag-NPs on the GO nanosheets

Fig 1 A schematic protocol for a two-step process to synthesize the Ag-GO nanohybrid.

Fig 2 TEM images of (a) Ag-NPs and (b–d) Ag-GO nanohybrids at different magnifications.

On the basis of TEM and XRD studies as well as earlier reports

[15,16], a possible mechanism of silver nanoparticle formation

and growth under the applied experimental conditions was

sug-gested The UV irradiation causes excitation of [Ag(NH3)2]+ions

fol-lowed by electron transfer from the glucose molecule to Ag+, thus

producing Ag0atoms which then form clusters and seeds:

½AgðNH3Þ2þþ RCHOH !hvAg0þ 2NH3þ Hþþ R _COH

nAg0! ðAgnÞ0;

where RCHOH represents glucose in cyclic form The use of UV

irra-diation leads to the substantially simultaneous formation of a large

amount of silver nuclei which then started to grow This situation

results in small dimensions and stably uniform dispersions of the

finally obtained silver NPs on the GO nanosheets The remaining

sil-ver ions are adsorbed on the surface of already formed

nanoparti-cles and attract oppositely charged oxygen functional groups on

the GO sheets through an electrostatic interaction to keep the

reduced silver nanoparticles staying on the GO[11]

3.2 Chemical groups in GO and Ag-GO nanohybrid

To elucidate the chemical attachment of Ag-NPs on the GO

nanosheets, FTIR and Raman analyses were conducted Fig 4

shows the FTIR spectra of (a) GO and (b) Ag-GO nanohybrids For

the case of GO (Fig 4), the presence of adsorption bands at

3493 cm1 corresponds to the AOH stretching vibration Other

peaks of oxygen functional groups were also detected including

CO2 groups at 2359 cm1, C@C bonding of aromatic rings of the

GO carbon skeleton structure at 1647 cm1, and OAH

deforma-tions of the CAOH groups at 1383 cm1 These oxygen functional

groups could be located on both basal planes and edges of the

GO nanosheets[2,3] However, a noticeable decrease in the inten-sity of the adsorption bands of the oxygenated functional groups was found in the FTIR spectrum of the Ag-GO nanohybrid This finding results mainly from both presence of the Ag-NPs on the surface of GO nanosheets and a slight reduction of GO by glucose during the synthesis process of Ag-GO The decrease of OAH stretch absorption intensity in the hybrids is attributed to interac-tions between silver ions and hydroxyl group of GO The variation

of the other peak in the case of Ag-GO demonstrates the interaction between silver ions and oxygen functional groups on both basal planes (hydroxyl group OH) and edges (carboxyl group CAOH) of the GO nanosheets through the formation of a coordination bond

or through simple electrostatic attraction The FTIR results demon-strate that the GO nanosheets have been successfully exfoliated, and strong interactions may exist between Ag-NPs and the remain-ing hydroxyl and carboxyl groups on the surface of the GO Fig 5shows the Raman spectra of (a) GO and (b) Ag-GO nano-hybrids For the case of GO (Fig 5), two characteristic prominent peaks were observed at 1360 cm1(D band) and at 1591 cm1(G band) Compared with GO, the Raman spectra of Ag-GO indicates that the D band and the G band are slightly shifted to 1338 and

1595 cm1, respectively The D band represents edges, other defects, and disordered carbon because of vibration of sp3-bonded carbon atoms and impurities, whereas the G band arises from the zone center E2g mode, assigning to the ordered sp2-bonded C atoms A significant frequency shift (about 22 cm1) toward a smaller wavenumber of the D-band is found in Ag-GO sample com-pared with the GO indicating a higher level of disorder of the graphene layers and increased numbers of defects because of the partial reduction of GO by glucose during the synthesis of the Ag-GO nanohybrid The spectra showed that the carbon framework

of GO is modified by reduction reaction process of Ag-NPs This finding is consistent with the FTIR result and that from previous works[7,10]

Besides, the ratio of intensity of the D band to that of the G band (ID/IG) also increased The ID/IGvalues are approximately 0.77 and 0.92 for GO and GO-Ag respectively The ratio value of ID/IG repre-sents the degree of disorder and the average size of the sp2 domains The observed increasing ID/IG-value suggested a decrease

in in-plane size of graphene upon the reduction process The partial reduction of GO could cause fragmentation along the reactive sites and might yield new graphitic domains, leading to smaller sizes and higher number of graphene than that of GO before the reduc-tion[7,11]

In the present study, the higher increased ID/IG-value of the Ag-GO nanohybrid than that of the GO is likely attributed to the surface-enhanced Raman scattering from the intense local electro-magnetic fields of Ag-NPs that accompanies plasmon resonance effect The FTIR and Raman results suggest that the attachment

Fig 3 XRD patterns for GO nanosheets and GO-Ag nanohybrid samples. Fig 5 Raman spectra of (a) GO and (b) Ag-GO nanohybrids.

of Ag-NPs on the GO nanosheets and the interaction between the

Ag and the functional groups of the GO nanosheets were ascribed

to the electron transfer from the metallic Ag to the GO nanosheets

3.3 Optical characterization of GO, Ag, and Ag-GO

To explore optical characterizations of the prepared Ag-GO

nanohybrid, we conducted UV–vis and photoluminescence (PL)

analyses

Fig 6shows (a) the UV–vis spectra of GO, Ag-NPs, and Ag-GO

nanohybrid and (b) the UV–vis spectra of Ag-GO nanohybrid at

dif-ferent Ag concentrations One peak (Fig 6a) at 305 nm comes from

n ?p*transitions of C@O bond in sp3hybrid regions, and another

prominent peak at 393 nm is ascribed to the CAOH bond,

whereas the presence of absorption peak at 726 nm is attributed

to band edge absorption feature[17] Obviously, the NP and

Ag-GO samples display strong absorption peaks at 428 and 435 nm,

respectively, because of the surface plasmon resonance (SPR) effect

of Ag-NPs The appearance of characteristic surface plasmon band

at 435 nm indicates the formation of Ag-NPs on GO nanosheets

The SPR phenomenon occurs when the incident light interacts with

valence electrons at the outer band of Ag-NPs, leading to oscillation

of electrons along with the frequency of the electromagnetic

source [18] However, the absorption band is shifted to longer

wavelength with increased concentration of Ag-NPs (Fig 6b) The

shifting of the absorption peak toward longer wavelength for

higher concentration of Ag-NPs indicates the formation of larger

Ag nanoparticles with different shapes and sizes[8,18] The surface

plasmon band shifts are strongly dependent on particle size, shape,

chemical surrounding, and adsorbed species on the surface and

dielectric medium, whereas the plasmon peak and full width at

half maximum depends on the extent of colloid aggregation

[18,19]

Ag-GO nanohybrid and (b) the PL emission spectra of Ag-GO

nanohybrid at different Ag concentrations The PL emission spectra

of GO aqueous suspension show two emission peaks at 412 and

530 nm Previous experiments verified that GO fluorescence is due to electron–hole recombination from conduction band bottom and nearby localized electronic states to wide-range valance band

In view of atomic structure, the GO emission is predominantly resulting from electron transitions among/between the non-oxidized carbon region (AC@CA) and the boundary of oxidized carbon atoms (CAO, C@O, or O@CAOH)[15,20]

The Ag-NP aqueous suspension also displays a maximum emis-sion peak at 400 nm The visible luminescence of Ag-NP colloid is ascribed to excitation of electrons from occupied D bands into states above the Fermi level Subsequent electron–phonon and hole–phonon scattering processes lead to energy loss and finally photoluminescent–radiative recombination of an electron from

an occupied sp band with the hole[18]

PL spectrum of Ag-GO showed two emission peaks at 400 and

530 nm, which were attributed to the interaction between lumi-nescence of atomically layered GO and localized surface plasmon resonance from metallic Ag-NPs Compared with the GO, the first peak position is shifted to 400 nm, and emission of peak at

400 nm is attributed to the plasmon resonance of Ag-NPs, whereas the second peak did not change at 530 nm With increasing con-centration of Ag-NPs, the PL intensity of Ag-GO was also increased

at peak 400 nm because of surface plasmon-enhanced lumines-cence [21,22] The effect of surface plasmon interaction of the Ag-NPs with the GO surface was also probed by UV–vis observa-tion The signal at about 332 nm in the PL spectra is the Raman sig-nal of water, whereas the sigsig-nals at 606 and 668 nm are attributed to the second mode of lamp and water, respectively

4 Conclusions

An easy and effective method of preparing Ag-GO aqueous solution was presented The fine dispersions of Ag-NPs on the GO

Fig 6 (a) The UV–vis spectra of GO, Ag-NPs, and Ag-GO nanohybrid and (b) the

Fig 7 (a) The PL emission spectra of GO, Ag-NPs, and Ag-GO nanohybrid and (b) the PL emission spectra of Ag-GO nanohybrid at different concentration of Ag.

nanosheets were altered by tuning the UV irradiation The results

also indicated that attraction of Ag-NPs on the GO nanosheets

and the interaction between the Ag-NPs and the functional groups

of the GO nanosheets were ascribed to the electron transfer from

the metallic Ag to the GO nanosheets The Ag-GO emission was

predominantly caused by the interaction between luminescence

of atomically layered GO and localized surface plasmon resonance

from the metallic Ag-NPs

Acknowledgements

This work was supported by Vietnam’s National Foundation for

Science and Technology Development (NAFOSTED) through a

fun-damental research project (Code: 103.44-2012.60) The authors

would like to thank P.T Huy at AIST for providing GO samples

and also thanks to N.D Cuong at AIST for proof reading and useful

discussions

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