Abstract
A rapid and high-performance sensor for lard adulterant in edible oil was developed using the tapered plastic optical fiber (POF) coated with graphene and multi-walled carbon nanotubes. The coating material was deposited onto a tapered POF with a taper waist diameter and a taper length of 0.45 mm and 1 cm, respectively. The addition of the coating material was used to increase the sensitivity and selectivity coefficient of the tapered POF toward the lard substance. The sensing mechanism is based on a simultaneous interaction of lard substance and an evanescent wave of tapered POF with the coating layers. The results showed that graphene coating on the tapered POF increased the selectivity coefficient of the tapered POF towards lard substance from 33.54 to 324.19, and it gave a sensitivity of 0.427 dBm/%. In comparison, multi-walled carbon nanotubes coating increased the selectivity coefficient to 71.65 and increased its sensitivity to 1.189dBm/%. Thus, the proposed configuration of the tapered POF with the coating material offered a simple configuration for a rapid, high sensitivity and selectivity detection of lard adulterant in edible oils.
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R. Johnson, Food Fraud and Economically Motivated Adulteration of Food and Food Ingredients. Congressional Research Service, US: CRS, 2014: 1–40.
N. A. Fadzillah, Y. B. Che Man, M. A. Jamaludin, S. A. Rahman, and H. A. Al Kahtani, “Halal food issues from islamic and modern science perspective,” in 2011 2nd International Conference on Humanities, Historical and Social Sciences, Cairo, 2011, pp. 159–163.
M. T. Gillies, Shortenings, margarines, and food oils, Noyes Data Corporation, 1974.
M. J. Haas, “Animal fats,” in Bailey’s industrial oil and fat products, 6th edition, F. Shahidi, Ed. New Jersey: John Wiley & Sons Inc., 2005: 2005–2006.
FDA, “Economically Motivated Adulteration”, FDA Enforcement Reports, 2011 (available online: https://www.fda.gov/food/compliance-enforcement-food/economically-motivated-adulteration-food-fraud).
P. Ulca, H. Balta, I. Cagin, and H. Z. Senyuva, “Meat species identification and Halal authentication using PCR analysis of raw and cooked traditional Turkish foods,” Meat Science, 2013, 94(3): 280–284.
N. H. Jenkins, “Virgin territory - exploring the world of olive oil,” New York: Houghton Mifflin Harcourt, 2015.
N. Blechman, “Extra virgin suicide - the adulteration of Italian olive oil (2014) (available online: http://www.nytimes.com/interactive/2014/01/24/opnion/food-chains-extra-virgin-suicide.html).
Q. Wang, A. Afshin, M. Y. Yakoob, G. M. Singh, C. D. Rehm, S. Khatibzadeh, et al., “Impact of nonoptimal intakes of saturated, polyunsaturated, and trans fat on global burdens of coronary heart disease,” Journal of the American Heart Association, 2016, 5(1): e002891.
R. E. Cooper, C. Tye, J. Kuntsi, E. Vassos, and P. Asherson, “The effect of omega-3 polyunsaturated fatty acid supplementation on emotional dysregulation, oppositional behaviour and conduct problems in ADHD: a systematic review and meta-analysis,” Journal of Affective Disorders, 2016, 190: 474–482.
K. Bonne and W. Verbeke, “Muslim consumer trust in halal meat status and control in Belgium,” Meat Science, 2008, 79(1): 113–123.
I. Puspita, D. P. M. Banurea, N. Irawati, A. M. Hatta, Sekartedjo, and F. Kurniawan, “Taper parameters effect on tapered POF for lard adulteration in olive oil detection,” Optoelectronics and Advanced Materials-Rapid Communications, 2020, 14(5–6): 250–255.
Z. A. Syahariza, Y. C. Man, J. Selamat, and J. Bakar, “Detection of lard adulteration in cake formulation by Fourier transform infrared (FTIR) spectroscopy,” Food Chemistry, 2005, 92(2): 365–371.
M. Latief, A. Khorsidtalab, I. Saputra, R. Akmeliawati, A. Nurashikin, I. Jaswir, et al., “Rapid lard identification with portable electronic nose,” in IOP Conference Series: Materials Science and Engineering, Hainan, 2017, pp. 012043.
M. A. Sairin, S. A. Aziz, N. A. A. Latiff, A. Ismail, and F. Z. Rokhani, “Lard detection in edible oil using dielectric spectroscopy,” in Sensors for everyday life, S. C. Mukhopadhyay, O. A. Postolache, K. P. Jayasundera, and A. K. Swain, Eds. Germany: Springer International Publishing, 2017: 245–271.
O. Taylan, N. Cebi, M. T. Yilmaz, O. Sagdic, and A. A. Bakhsh, “Detection of lard in butter using Raman spectroscopy combined with chemometrics,” Food Chemistry, 2020, 332: 127344.
K. Peters, “Polymer optical fiber sensors - a review,” Smart Materials and Structures, 2010, 20(1): 013002.
Y. Tian, W. Wang, N. Wu, X. Zou, and X. Wang, “Tapered optical fiber sensor for label-free detection of biomolecules,” Sensors, 2011, 11(4): 3780–3790.
K. P. W. Dissanayake, W. Wu, H. Nguyen, T. Sun, and K. T. Grattan, “Graphene-oxide-coated long-period grating-based fiber optic sensor for relative humidity and external refractive index,” Journal of Lightwave Technology, 2017, 36(4): 1145–1151.
A. Aziz, H. Lim, S. Girei, M. Yaacob, M. Mahdi, N. Huang, et al., “Silver/graphene nanocomposite-modified optical fiber sensor platform for ethanol detection in water medium,” Sensor and Actuator B: Chemical, 2015, 206: 119–125.
M. Singh, S. K. Raghuwanshi, and O. Prakash, “Ultra-sensitive fiber optic gas sensor using graphene oxide coated long period gratings,” IEEE Photonics Technology Letter, 2019, 31(17): 1473–1476.
S. P. Dash, S. K. Patnaik, and S. K. Tripathy, “Investigation of a low cost tapered plastic fiber optic biosensor based on manipulation of colloidal gold nanoparticles,” Optics Communications, 2019, 437: 388–391.
Y. Zhao, X. G. Li, X. Zhou, and Y. N. Zhang, “Review on the graphene based optical fiber chemical and biological sensors,” Sensors and Actuatprs B: Chemical, 2016, 231: 324–340.
A. Jain, A. Homayoun, C. W. Bannister, and K. Yum, “Single-walled carbon nanotubes as near-infrared optical biosensors for life sciences and biomedicine,” Biotechnology Journal, 2015, 10(3): 447–459.
K. A. Madurani, S. Suprapto, N. I. Machrita, S. L. Bahar, W. Illiya, and F. Kurniawan, “Progress in graphene synthesis and its application: history, challenge and the future outlook for research and industry,” ECS Journal of Solid State Science, 2020, 9(9): 093013.
H. Qiu, S. Xu, S. Jiang, Z. Li, P. Chen, S. Gao, et al., “A novel graphene-based tapered optical fiber sensor for glucose detection,” Applied Surface Science, 2015, 329: 390–395.
A. L. Khalaf, P. T. Arasu, H. N. Lim, S. Paiman, N. A. Yusof, M. A. Mahdi, et al., “Modified plastic optical fiber with CNT and graphene oxide nanostructured coatings for ethanol liquid sensing,” Optics Express, 2017, 25(5): 5509–5520.
T. Allsop, R. Arif, R. Neal, K. Kalli, V. Kundrát, A. Rozhin, et al., “Photonic gas sensors exploiting directly the optical properties of hybrid carbon nanotube localized surface plasmon structures,” Light: Science & Applications, 2016, 5(2): e16036.
C. N. H. Lah, N. Jamaludin, F. Z. Rokhani, S. A. Rashid, and A. S. M. Noor, “Lard detection using a tapered optical fiber sensor integrated with gold-graphene quantum dots,” Sensing and Bio-Sensing Research, 2019, 26: 100306.
C. X. Teng, N. Jing, and J. Zheng, “The influence of temperature to a refractive index sensor based on a macro-bending tapered plastic optical fiber,” Optical Fiber Technology, 2016, 31: 32–35.
M. Yasin, N. Irawati, S. W. Harun, F. Ahmad, and M. Khasanah, “Sodium nitrate (NaNO3) sensor based on graphene coated microfiber,” Measurement, 2019, 146: 208–214.
M. Yasin, N. Irawati, S. W. Harun, and F. Ahmad, “NaNO3 sensing based on microfiber coated with multi-walled carbon nanotubes,” Optik, 2019, 185: 936–942.
M. Batumalay, S. W. Harun, N. Irawati, H. Ahmad, and H. Arof, “A study of relative humidity fiber-optic sensors,” IEEE Sensor Journals, 2014, 15(3): 1945–1950.
M. Zhao, X. Wang, J. Cheng, L. Zhang, J. Jia, and X. Li, “Synthesis and ethanol sensing properties of Al-doped ZnO nanofibers,” Current Applied Physics, 2013, 13(2): 403–407.
D. J. Feng, G. X. Liu, X. L. Liu, M. S. Jiang, and Q. M. Sui, “Refractive index sensor based on plastic optical fiber with tapered structure,” Applied Optics, 2014, 53(10): 2007–2011.
O. Leenaerts, B. Partoens, and F. M. Peeters, “Adsorption of H2O, NH3, CO, NO2, and NO on graphene: a first-principles study,” Physic Review B, 2008, 77(12): 125416.
H. Zhang, A. Kulkarni, H. Kim, D. Woo, Y. J. Kim, B. H. Hong, et al., “Detection of acetone vapor using graphene on polymer optical fiber,” Journal of Nanoscience and Nanotechnology, 2011, 11(7): 5939–5943.
J. W. Weber, V. E. Calado, and M. C. M. van de Sanden, “Optical constants of graphene measured by spectroscopic ellipsometry,” Applied Physics Letter, 2010, 97(9): 091904.
Q. Ye, J. Wang, and Z. Liu, “Polarization-dependent optical absorption of graphene under total internal reflection,” Applied Physic Letter, 2013, 102(2): 021912.
H. Tai, Y. Jiang, G. Xie, J. Yu, and X. Chen, “Fabrication and gas sensitivity of polyaniline-titanium dioxide nanocomposite thin film,” Sensors and Actuators B: Chemical, 2007, 125(2): 644–650.
F. Kurniawan, N. S. Al Kiswiyah, K. A. Madurani, and M. Tominaga, “Electrochemical sensor based on single-walled carbon nanotubes-modified gold electrode for uric acid detection,” Journal of Electrochemical Society, 2018, 165(11): B515.
Acknowledgment
The research has been funded by the Indonesian Government, KEMENRISTEKDIKTI (Ministry of Research, Technology, and Higher Education of the Republic of Indonesia) for supporting this work under project scheme University’s Fundamental Research Program (Grant No. 918/PKS/ITS/2021).
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Puspita, I., Irawati, N., Madurani, K.A. et al. Graphene- and Multi-Walled Carbon Nanotubes-Coated Tapered Plastic Optical Fiber for Detection of Lard Adulteration in Olive Oil. Photonic Sens 12, 220411 (2022). https://doi.org/10.1007/s13320-022-0652-y
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DOI: https://doi.org/10.1007/s13320-022-0652-y