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Industrial Chemistry | ISSN: 2469-9764 | Volume 4

17

th

International Conference on

May 21-22, 2018 | New York, USA

Industrial Chemistry and Water Treatment

Gold nanoparticles assembled on multilayer graphene sheets for surface enhanced Raman

spectroscopy of glucose and related organic pollutants

Laila Al-garni, Biao Leng

and

Zafar Iqbal

New Jersey Institute of Technology, USA

T

he small normal Raman cross-section of glucose is considered a major issue for their detection by surface enhanced

Raman spectroscopy (SERS) for medical applications, such as blood glucose level monitoring of diabetic patients and

evaluation of patients with other medical conditions since glucose is a marker for many human diseases. Similarly, organic

contaminants such as toluene suspended in drinking water require detection and removal. In this work, we report the use

of commercial multilayer graphene sheets as substrates on which gold nanoparticles are chemically assembled by citrate

reduction. The results show that these substrates are capable of providing SERS enhancement factors up to 1010 with a

detection limit to 10-8 M in aqueous solutions of glucose. The SERS performance on graphene substrates are many orders of

magnitude higher compared with results on gold coated chemically etched Klarite® silicon substrates. The glucose spectra over

a wide range of concentrations in the 400-1500cm-1 fingerprint region were recorded with a Thermo Scientific DXR Raman

microspectrometer using 785nm laser wavelength, 10mW laser power and a 50x microscope objective. The intensity of the

1340cm-1 line of glucose in particular varied linearly with glucose concentration and can be used as a calibration for samples

of unknown concentrations. Chemometric methods were used to provide improved spectra at very low concentrations. The

role of fractional charge transfer effects from the graphene substrate to glucose that could provide secondary enhancement of

the spectra will also be evaluated. Similar preliminary results on toluene suspended in water related to water contamination

will also be presented.

Biography

Laila Al-garni has received her Master’s degree in Chemistry from Saudi Arabia at King Abdul Aziz University in 2009. She has started her job in 2008 as Teaching

Assistant, then promoted as Lecturer in 2009. She is pursuing her PhD in Physical Chemistry from New Jersey Institute of Technology under the direction of Prof.

Zafar Iqbal, where she used Raman spectroscopy for detection of glucose at very low concentration (pharmaceutical and biofuel sensing application).

lsa5@njit.edu

Laila Al-garni et al., Ind Chem 2018, Volume 4

DOI: 10.4172/2469-9764-C1-009