This paper presents fabrication and characterization of an ethanol sensor whose working electrode (W.E.) is made consists of electrodeposited PdCu on laser induced graphene (LIG) layer and drop-casted alcohol oxidase (AOx) enzyme. AOx reacts with ethanol to generate hydrogen peroxide and the electrodeposited PdCu works as an electrocatalyst of hydrogen peroxide in order to increase amperometric output current. The optimum conditions for the ratio between Pd and Cu, the drop-casted AOx amount, the pH value of PBS have been obtained by varying the fabrication conditions and comparing the output results. Field emission scanning electron microscope (FE-SEM) and Raman spectroscopy were used to confirm LIG electrode formation. Also, Energy-dispersive X-ray spectroscopy (EDS) was performed to verify the ratio of the electrodeposited Pd and Cu. Cyclic voltammetry (CV) analysis of the W.E. showed that the peak reduction current occurs at –0.045 V. and this voltage was chosen as an applied voltage in amperometric measurement. Electrochemical impedance spectroscopy (EIS) shows that the charge transfer resistance of the PdCu deposited LIG W.E. is lower than the bare LIG W.E., which also shows the output current accordingly. Chronoamperometric response of the fabricated sensor was measured at various ethanol concentrations in range of 0-12 mM, and the linear sensitivity was 17.99 ㎂mM<SUP>-1</SUP>cm<SUP>-2</SUP>. which is similar or better than those of the recently reported other ethanol sensors.

• Abstract
• 1. 서론
• 2. 본론
• 3. 결론
• References

1 M. Shanmugam, "Two-dimensional layered semiconductor/graphene heterostructures for solar photovoltaic applications" 6 (6): 12682-12689, 2014

2 N. G. Patel, "Screen-printed biosensors using different alcohol oxidases" 75 (75): 101-110, 2001

3 A. C. Ferrari, "Raman spectrum of graphene and graphene layers" 97 (97): 1-4, 2006

4 Tian, Gang, "Quantification of ethanol in plasma by electrochemical detection with an unmodified screen printed carbon electrode" 6 (6): 1-6, 2016

5 박대한, "PdCu를 전기 도금한 레이저 유도 그래핀 전극 기반의 과산화수소 측정 센서 개발" 대한전기학회 67 (67): 1626-1632, 2018

6 C. Xu, "Nanoporous PdCu alloy with enhanced electrocatalytic performance" 13 (13): 766-769, 2011

7 J. Lin, "Laser-induced porous graphene films from commercial polymers" 5 : 5-12, 2014

8 R. Ye, "Laser-Induced Graphene: From Discovery to Translation" 31 (31): 1-15, 2019

9 R. Ye, "Laser-Induced Graphene Formation on Wood" 29 (29): 1-7, 2017

10 R. Ye, "Laser-Induced Graphene" 51 (51): 1609-1620, 2018

11 J. O. Blose, "Injury-related medical care utilization in a problem drinking population" 81 (81): 1571-1575, 1991

12 Y. Tan, "Immobilization of enzymes at high load/activity by aqueous electrodeposition of enzyme-tethered chitosan for highly sensitive amperometric biosensing" 25 (25): 2644-2650, 2010

13 M. Saafi, "Hybrid graphene/geopolymeric cement as a superionic conductor for structural health monitoring applications" 25 : 2016

14 O. Barbosa, "Glutaraldehyde in bio-catalysts design: A useful crosslinker and a versatile tool in enzyme immobilization" 4 (4): 1583-1600, 2014

15 C. J. Harvey, "Formulation and stability of a novel artificial human sweat under conditions of storage and use" 24 (24): 1790-1796, 2010

16 X. Xie, "Flow-injection determination of ethanol by fiberoptic chemiluminescence measurement" 266 (266): 325-329, 1992

17 A. M. Azevedo, "Ethanol biosensors based on alcohol oxidase" 21 (21): 235-247, 2005

18 S. Kurbanoglu, "Ethanol biosensor based on immobilization of alcohol Oxidase in a conducting polymer matrix via Crosslinking with Glutaraldehyde" 60 (60): 453-460, 2015

19 U. M. Mizgunova, "Enzymic method for the determination of ethanol and methanol with spectrophotometric detection of the rate of the process" 121 (121): 431-433, 1996

20 M. W. Hsieh, "Electrodeposition of PdCu alloy and its application in methanol electro-oxidation" 270 : 252-259, 2013

21 M. A. Kumar, "Elecrochemical Determination of Ethanol by a Palladium Modified Graphene Nanocomposite Glassy Carbon Electrode" 50 (50): 350-363, 2017

22 E. C. Rama, "Comparative study of different alcohol sensors based on Screen-Printed Carbon Electrodes" 728 : 69-76, 2012

23 C. Verduyn, "Colorimetric alcohol assays with alcohol oxidase" 2 (2): 15-25, 1984

24 R. W. Dreyfus, "CN temperatures above laser ablated polyimide" 55 (55): 335-339, 1992

25 B. Kowalewska, "Bioelectrocatalytic Activity of Immobilized Alcohol Oxidase on 4-(pyrrole-1-yl) Benzoic Acid Modified Carbon Nanotubes" 28 (28): 2050-2057, 2016

26 A. Uzunoglu, "Bimetallic PdCu/SPCE non-enzymatic hydrogen peroxide sensors" 220 : 968-976, 2015

27 S. A. Miscoria, "Analytical performance of a glucose biosensor prepared by immobilization of glucose oxidase and different metals into a carbon paste electrode" 14 (14): 981-987, 2002

28 M. Tipmanee, "Amperometric Biosensors Using Different Alcohol Oxidases" 891 : 90-95, 2019

29 V. Hooda, "Alcohol quantification: recent insights into amperometric enzyme biosensors" 46 (46): 398-410, 2018

30 M. Akin, "Alcohol biosensing by polyamidoamine (PAMAM)/cysteamine/alcohol oxidase-modified gold electrode" 26 (26): 896-906, 2010

31 A. Liu, "A three-dimensional hierarchical nanoporous PdCu alloy for enhanced electrocatalysis and biosensing" 703 (703): 172-178, 2011

32 S. Soylemez, "A promising enzyme anchoring probe for selective ethanol sensing in beverages" 133 : 1228-1235, 2019

33 S. Cinti, "A paper-based nanomodified electrochemical biosensor for ethanol detection in beers" 960 : 123-130, 2017

34 N. C. Kekec, "A novel conducting polymer based platform for ethanol sensing" 193 : 306-314, 2014

35 S. A. Bekmezci, "A new ethanol biosensor based on polyfluorene-g-poly(ethylene glycol) and multiwalled carbon nanotubes" 122 : 109300-, 2020

36 I. C. Trial, "A method employing gas chromatography for the determination of ethanoi in beer has been collaborn-Butanol (0.5% V/V), internal standard . Pip and dilute to 2 litres with distilled water. The determination of ethanol in beer by gas liquid chromat" 99 : 381-384, 1993