Fabrication of Core-shell Structure Nanocomposites of Gold

Nanoparticles@METAC

Sujuan Liu

,Zhaoyu Wu

Department of Chemistry and Industry,Mudanjiang Normal University, Aiminjie,Mudanjiang , China

Keywords: Core-shell structure, nanocomposites, gold nanoparticles.

Abstract: Novel core-shell structure nanocomposites are fabricated by grafting polymers of poly([2-

(Methacryloyloxy)ethyl]trimethylammonium chloride) onto gold nanoparticles through surface-initiated,

atom-transfer radical polymerization (ATRP) in 2-propanol/water mixed solvents. The surface of citrate-

stabilized gold nanoparticles was first modified by a disulfide initiator for ATRP. The Au@polymer

nanocomposites display a well-defined core/shell nanostructure that were characterized by TEM, FTIR,XPS

and UV-visible spectroscopy. Such core-shell nanocomposites can be considered as water-dispersible

nanotanks for hydrophobic drugs in the development of multifunctional biodelivery systems

1 INTRODUCTION

Metal nanoparticles that are imbedded in polymer

composites have been of intense recent interest [1]

with regard to their fabrication and potential

application in areas such as electronics, optics,

magnetics, catalysts, and sensors [2-7]. As a well-

known noble metal, gold is widely investigated due

to its specific impact in the fields of biotechnology

and bioscience [8-14]. A large number of polymer

molecules have been selected to decorate the surface

of gold nanoparticles in physical or chemical

manners for different purposes [15-20].

In this paper, we report the fabrication of

METAC modified gold nanoparticles as

nanocomposite materials by SI-ATRP on a gold

surface. The typical experimental procedure is

illustrated in Scheme 1. First, the disulfide initiator

was immobilized on the surface of gold

nanoparticles (Au@initiator). Subsequently, ATRP o

［ 2-(Methacryloyloxy)ethyl ］ trimethylammonium

chloride (METAC) occurred on gold nanoparticles

catalyzed by N,N,N′,N′,N′′-

pentamethyldiethylenetriamine (PMDETA) and

CuBr. Such environmentally responsive

nanocomposites provide a smart supporter or carrier

to transition metal ions and nanoparticles to

construct novel bimetallic nanocomposites,

especially in catalyst applications.

2 MATERIALS AND METHODS

2.1 Materials

The disulfide initiator ［ S-(CH

)

-OCOC(CH

)

］

, ［ 2-(Methacryloyloxy)ethyl ］

trimethylammoniumchloride(METAC),N,N,N’,N’,N

’’-pentamethyl-diethylenetriamine (PMDETA) were

purchased from Sigma Aldrich. CuBr, HAuCl

sodium citrate, and other chemicals were obtained

from. METAC was purified to remove the inhibitor.

The gold nanoparticles with an average diameter of

20 nm were prepared from HAuCl

and sodium

citrate by conventional citrate-reduction methods

[21].

2.2 Instrumentation

FTIR and UV-vis spectra, respectively, were

recorded on a Excalibur HE 3100 instrument

(Varian) and a U-4100 UV-vis spectrometer

(HITACHI). TEM images were obtained by a

Tecnai G

F30 transition electron microscope (FEI).

X-ray photoelectron spectroscopy (XPS) was

performed on an K-Alpha electron spectrometer

(Thermofisher Scienticfic Company) using 300 W

Al Kα radiation at about 1×10

-8

mbar,and the

binding energies were referenced to the C1s line at

284.8eV from adventitious carbon.

2.3 Preparation of SI-ATRP Initiator

The initiator immobilized on gold nanoparticles

(Au@initiator) was prepared from fresh gold

nanoparticles through ligand exchange between

disulfide initiator and citrates. Generally, a certain

volume of fresh gold nanoparticles in water was

slowly added to same volume of a N,N-

dimethylformamide (DMF) solution that dissolved

3.0 mM initiator with stirring for 24 h. The

Au@initiator was collected and washed with DMF

and Millipore purified deionized water by

centrifugation. Finally, Au@initiator was dispersed

in DMF and stored at 20 °C under an argon

atmosphere.

2.4 SI-ATRP Process of METAC

Polymerization of METAC on a gold surface was

performed in a mixed solvent at ambient conditions

according to the literature [22-25]. In detail, a round-

bottom flask was added with CuBr (28.6 mg) and

degassed by three freeze pump thaw cycles under N

atmosphere. A degassed mixture of Au@initiator (2

mg) dissolved in DMF (2 mL), PMDETA

(0.208mL), 2-propanol (0.5 mL), and a certain

amount of free initiator (0.5-20 mg) was injected

into the flask through a syringe, followed by

degassed METAC (1.05-2.10 g) with drastic stirring.

The reaction was performed for 24 h and terminated

by opening the system to air. The Au@METAC

nanocomposites were purified by more than three

cycles of centrifugation, 2-propanol/DMF washing.

3 RESULTS AND DISCUSSION

3.1 Preparation and Component Analysis

Gold nanoparticles with diameters of 20 nm were

synthesized by using the conventional citrate-

reduction method and can be easily dispersed in

warter without aggregation, as shown in Figure 1.

The immobilization of disulfide initiator on the gold

surface was achieved through ligand exchange

between disulfide and citrate. The ATRP reaction of

METAC from a free initiator or a macromolecular

initiator was suggested to be carried out in a protic

alcohol solvent [26-27].

Herein, the solvent is mixed

protic 2-propanol with DMF according to the

solubility of the Au@initiator and METAC chains.

A large amount of PMDETA was used to maintain

the activity of the catalytic system, and an appreciate

amount of free initiator was added into the reaction

mixture to control the polymerization [28]. Figure

3A shows the FT-IR spectra of Au@initiator and as-

prepared Au@METAC nanocomposites. The profile

of the Au@initiator (curve b) is similar to that of the

pure disulfide initiator, whose characteristic

absorbance at 2922, 2850 (CH

stretching), and 1729

-1

(ester carbonyl stretching) of Au@initiator

(curve b) denotes the presence of the ATRP initiator

on gold nanoparticles. For obtained Au@METAC

(curve a), the characteristic peaks at 2968, 1730, and

1457 cm

-1

represent the CH

and CH

stretching

vibrations, ester carbonyl stretching, -CH

- N

(CH

)

bending vibrations according to the references

[22,23]. 960cm

-1

(CH

)

),1166,1278cm

-1

(C-O). It

shows that the polymerization of METAC is

performed successfully. So, the FT-IR results reveal

that the Au@METAC nanocomposites are easily

protonated by hydrochloride.

Moreover, the Au@METAC nanocomposite

samples and pure METAC (sigma, as a comparison)

were analyzed by X-ray

photoelectronspectroscopy(XPS).The element

components of Au@METAC nanocomposites are

approximately contributed to C (41.2%), N (2.5%),

O (11.6%), Au (43.4%), and Cl (1.3%). Figure 3B

shows the binding-energy decrease of Au 4f within a

range of 8.1 eV and 8 eV (95.4 to 87.3 eV for Au

4f5/2 and 91.6 to 83.6 eV for Au 4f7/2) after (a) and

before (b) gold nanoparticle disulfide initiator

modification by METAC. This proves the formation

of Au-C bonds on the gold surface.

All of these

component analyses demonstrate that the designed

Au@METAC nanocomposites were successfully

obtained from a consecutive ATRP reaction.

3.2 Morphology and Structural

Characterizations

Figure 2 show the transmission electron microscopy

(TEM)images of Au@METAC nanocomposites

under different magnifications. The well-dispersed

nanostructures consist of a gold “core” with an

average diameter of 20 nm and a polymer “shell”

about 10 nm thick, which could be clearly observed

after staining by phosphotungstic acid.

4 CONCLUSION

In summery, we have demonstrated that SI-ATRP of

METAC can be performed on the surface of initiator

modified gold nanoparticles to fabricate

Au@polymer nanocomposites. The as-prepared

Au@METAC nanocomposites have a distinct core

shell nanostructure with gold cores and polymer

shells. The polymer “shell” has a network scaffold.

The biocompatible and amphiphilic core-shell

nanostructures can be considered as water-

dispersible nanotanks for hydrophobic drugs, which

may have great potential in the multifunctional

biodelivery of hydrophobic drugs. The fabrication

strategy for core-shell nanostructures can be

generalized to prepare novel structured materials in

nanotechnology and biotechnology.

METAC

CuBr/PMDETA

2-propanol/H

Au@initiator Au@METAC

Citrate-stabilized

gold nanopartiacles

DMF/H

Disulfide initiator

METAC

CuBr/PMDETA

2-propanol/H

METAC

CuBr/PMDETA

2-propanol/H

Au@initiator Au@METAC

Citrate-stabilized

gold nanopartiacles

Citrate-stabilized

gold nanopartiacles

AuAu

AuAuAu

DMF/H

Disulfide initiator

DMF/H

Disulfide initiator

Scheme1. Au@METAC fabrication

Figure 1.TEM image of GNP dispersed in THF. Scale

bar:100 nm.

Figure 2. TEM images of Au@METAC nanocomposites

dispersed in water.

(A) (B)

Figure 3. (A) FT-IR spectra of Au@initiator (a) and

Au@METAC nanocomposites washed by 2-

propanol,(B)Au 4f spectra from XPS analysis of

Au@initiator (a) and Au@METAC nanocomposites (b).

ACKNOWLEDGEMENTS

This research is supported by the research projects

(No. 201710233007,G2017e2447andQN201604）.

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